curriculum vitae anupama bhat kaul educationhb2504.utep.edu/vitas/akaul.pdf · anupama b. kaul,...

33
Anupama B. Kaul, Mar. 2017 Page 1 of 33 CURRICULUM VITAE ANUPAMA BHAT KAUL El Paso, Texas Phone: (915) 747-6003 [email protected] EDUCATION Ph.D. in Materials Science and Engineering 2000 University of California at Berkeley, California Minors: Electrical Engineering and Physics M.S. in Materials Science and Engineering 1997 University of California at Berkeley, California M.S. courses sponsored by Hewlett Packard Company 1994–1995 Stanford University, Stanford, California B.S. with Honors, Double Major: Physics; Engineering Physics 1992 Oregon State University, Corvallis, Oregon Minor: Mathematics, Magna Cum Laude APPOINTMENTS SUMMARY 2014 – Present University of Texas at El Paso (UTEP), TX -- AT&T Distinguished Professor, Department of Electrical and Computer Engineering -- Associate Dean for Research & Graduate Studies, College of Engineering -- Director, Nanomaterials and Devices Laboratory (NDL) 2011- 2014 National Science Foundation (NSF), Arlington, VA -- Program Director (IPA from JPL-Caltech), ECCS Division, Engineering Directorate 2002 – 2014 Jet Propulsion Laboratory (NASA), California Inst. of Tech. (Caltech), Pasadena, CA -- Senior Member of Technical Staff, Task Manager 2000 – 2002 Motorola Labs-Corporate Headquarters, Schaumburg, IL -- Senior Research Engineer 1993 – 1995 Hewlett-Packard (HP) R&D Division, HP, Corvallis, OR -- R&D Engineer RECENT LEADERSHIP HIGHLIGHTS 2016 – Present External Advisory Board Member, Penn State University’s Two-dimensional (2D) Crystal Consortium (2DCC) – Materials Innovation Platform (MIP). The 2DCC-MIP is an NSF supported National User Facility for 2D materials research funded at the level of $18 Million (5 years; renewable for additional 5 years). 2012 – 2014 Created and led the 2-Dimensional Atomic-layer Research and Engineering (2-DARE) Program under the NSF’s Emerging Frontiers in Research and Innovation (EFRI)

Upload: others

Post on 22-Jul-2020

0 views

Category:

Documents


0 download

TRANSCRIPT

Page 1: CURRICULUM VITAE ANUPAMA BHAT KAUL EDUCATIONhb2504.utep.edu/vitas/akaul.pdf · Anupama B. Kaul, Mar. 2017 Page 5 of 33 NEEDS is designed to develop computation, simulation and educational

Anupama B. Kaul, Mar. 2017 Page 1 of 33

CURRICULUM VITAE

ANUPAMA BHAT KAUL

El Paso, Texas Phone: (915) 747-6003 [email protected]

EDUCATION

Ph.D. in Materials Science and Engineering 2000 University of California at Berkeley, California

Minors: Electrical Engineering and Physics

M.S. in Materials Science and Engineering 1997 University of California at Berkeley, California M.S. courses sponsored by Hewlett Packard Company 1994–1995 Stanford University, Stanford, California

B.S. with Honors, Double Major: Physics; Engineering Physics 1992 Oregon State University, Corvallis, Oregon Minor: Mathematics, Magna Cum Laude

APPOINTMENTS SUMMARY 2014 – Present University of Texas at El Paso (UTEP), TX -- AT&T Distinguished Professor, Department of Electrical and Computer Engineering -- Associate Dean for Research & Graduate Studies, College of Engineering -- Director, Nanomaterials and Devices Laboratory (NDL) 2011- 2014 National Science Foundation (NSF), Arlington, VA

-- Program Director (IPA from JPL-Caltech), ECCS Division, Engineering Directorate 2002 – 2014 Jet Propulsion Laboratory (NASA), California Inst. of Tech. (Caltech), Pasadena, CA

-- Senior Member of Technical Staff, Task Manager 2000 – 2002 Motorola Labs-Corporate Headquarters, Schaumburg, IL

-- Senior Research Engineer 1993 – 1995 Hewlett-Packard (HP) R&D Division, HP, Corvallis, OR

-- R&D Engineer

RECENT LEADERSHIP HIGHLIGHTS 2016 – Present External Advisory Board Member, Penn State University’s Two-dimensional (2D)

Crystal Consortium (2DCC) – Materials Innovation Platform (MIP). The 2DCC-MIP is an NSF supported National User Facility for 2D materials research funded at the level of $18 Million (5 years; renewable for additional 5 years).

2012 – 2014 Created and led the 2-Dimensional Atomic-layer Research and Engineering (2-DARE) Program under the NSF’s Emerging Frontiers in Research and Innovation (EFRI)

Page 2: CURRICULUM VITAE ANUPAMA BHAT KAUL EDUCATIONhb2504.utep.edu/vitas/akaul.pdf · Anupama B. Kaul, Mar. 2017 Page 5 of 33 NEEDS is designed to develop computation, simulation and educational

Anupama B. Kaul, Mar. 2017 Page 2 of 33

initiative. This program created new funding at ~ $50 Million level in partnership with the Department of Defense to support research on 2D layered materials and devices in the US.

2015 – 2016 Chair (and Principal Investigator on NSF Proposal) of US EU Workshop on 2D Layered Materials and Devices held in 2015 that involved the European Union (EU) Graphene Flagship Program (funded at level of ~ $10 Billion Euros over 10 years) and leading US researchers working on 2D layered materials and devices. A direct outcome of this workshop was the issuance of a Dear Colleague Letter (DCL) by the NSF in 2016 (https://www.nsf.gov/pubs/2016/nsf16102/nsf16102.jsp?org=ENG) to promote cross-Atlantic collaborations between US and EU researchers in this area of research.

2015 – 2016 Fellow, ELATE Class of 2016; Executive Leadership in Academic Technology and Engineering (ELATE) Program is a national year-long leadership development program for senior women faculty in Engineering, Science and Technology, administered by Drexel University.

2016 – Present Director, Center for Engineering and Nanoscience Research, a new Center under development and in its formative phases, to promote interdisciplinary research in Nanoscience and Nanotechnology at UTEP.

PROFESSIONAL EXPERIENCE

University of Texas, El Paso (UTEP) El Paso, TX Fall 2014 – present Associate Dean for Research and Graduate Studies, College of Engineering 2014 – present

College-centric Administrative Responsibilities & Initiatives o Initiated & Lead the Interdisciplinary Research Seed (IRS) Fund, a new initiative to promote and

enhance interdisciplinary and collaborative research activities between departments in the college.

o Spear-heading efforts to grow the research infrastructure within the college through the acquisition of new equipment for the college’s shared user facilities.

o Prioritizing resources to support current research-centric activities and to promote growth of the research enterprise in the college.

o Facilitating interactions of junior faculty with potential federal agencies for young investigator and other early career awards.

o Initiated & Lead the College-wide Distinguished Speaker Seminar Series where high-profile researchers are invited to visit UTEP to engage with faculty and students for enhancing interactions and potential collaborations.

o Initiated & Lead the College Thesis & Dissertation Awards Committee for recognizing research scholarship amongst graduating M.S. and Ph.D. students.

o Initiated & Lead the College Fellowships Committee for attracting high-caliber Ph.D. students to the College.

o Manage and coordinate the peer-review of pre-proposals and white-papers from the college, in collaboration with Office or Research and Sponsored Projects (ORSP) that are responsive to limited submission calls from federal agencies.

o Support faculty and graduate students on a need-basis for providing them with resources to attend leading conferences and other important events to enhance their research productivity and scholarship.

o Marketing college’s graduate programs through internal and external workshops and events.

Page 3: CURRICULUM VITAE ANUPAMA BHAT KAUL EDUCATIONhb2504.utep.edu/vitas/akaul.pdf · Anupama B. Kaul, Mar. 2017 Page 5 of 33 NEEDS is designed to develop computation, simulation and educational

Anupama B. Kaul, Mar. 2017 Page 3 of 33

o Chaired the Search Committee for the Lab Manager Position to oversee the College’s Nanofabrication and Material Characterization Facilities, Spring-Summer 2015.

o Developing initiatives and support mechanisms for postdoctoral scholars in the College to enhance their research productivity and promoting career development.

University-wide Administrative Committees & Responsibilities o Appointed by the University President to serve on the New InterDisciplinary Research Building

(IDRB) committee; 12/2015 – present. o Focus Group Leader for the Nanoscience and Advanced Materials Focus Group for the New

Interdisciplinary Research Building. As Focus Group Leader, brought together faculty from colleges within the campus to put forth a vision for Nanoscience and Advanced Materials research at UTEP; provided Building Committee and Architects with design guidelines for the various lab spaces centric to this focus group (e.g. imaging suite, wet-labs, dry labs) proposed for the new building.

o Director, Center for Engineering and Nanoscience Research, a new Center under development and in its formative phases at UTEP to promote interdisciplinary research in Nanoscience and Nanotechnology.

o Member, Technology Commercialization Advisory Board, 6/2016 – present. Committee composed of faculty and administrative leaders across campus, and is coordinated by the UTEP Tech Transfer Office.

o Member, Campus-wide Council on Research & Sponsored Projects through the Office of VP-Research.

o Member, Campus-wide Committee for Research Centers through Office of VP-Research. o Faculty Interdisciplinary Program Leader for College of Engineering, Interdisciplinary Research

Symposium 2015, Organized by Office of Research and Sponsored Programs (ORSP).

AT&T Distinguished Professor of Electrical and Computer Engineering 2014 – present Research Focus Area: The overarching theme of my research is to characterize the intriguing properties of nanoscale materials and harness these properties for device related applications. The research encompasses materials synthesis, materials property characterization, bottom-up assembly and top-down nanofabrication and device characterization. Website for Research Group, the Nanomaterials and Devices Lab (NDL): http://utep.edu/kaulgroup

Director, Nanomaterials and Devices Laboratory (NDL) o Founded NDL at UTEP in 2015, which became established and productive in 2016. o Developed three sub-labs within the NDL umbrella which includes the: 1) Electronic and Opto-

electronic Materials and Device Characterization Lab; 2) Materials Synthesis and Characterization Lab; 3) Composites and Bio-materials Processing Lab.

o Research on the synthesis and characterization of low-dimensionality nanomaterials (e.g. nanocarbons, van der Waals solids) and their use in device platforms for nanoelectronics, sensors, opto-electronics, energy harvesting devices, flexible electronics and bio-related applications.

o Developed a state-of-the-art opto-electronics laboratory for material property and device characterization that is equipped with a cryogenic, vacuum-based probe stage interfaced to ultra-low-noise electronics and tunable narrow-band/broad-band optical sources from the visible to the infra-red regime.

Page 4: CURRICULUM VITAE ANUPAMA BHAT KAUL EDUCATIONhb2504.utep.edu/vitas/akaul.pdf · Anupama B. Kaul, Mar. 2017 Page 5 of 33 NEEDS is designed to develop computation, simulation and educational

Anupama B. Kaul, Mar. 2017 Page 4 of 33

o Developed an end-to-end material synthesis laboratory using both top-down and bottom-up synthesis. Solution-based approaches enable the additive manufacturing of nanomaterials through ink-jet printing, and other techniques; vapor-based synthesis enables the realization of high crystalline-quality nanomaterials using chemical vapor deposition for high-performance devices.

o Developed a laboratory for forming hybrid organic and inorganic composites using 3D-printing, and integrating bio-materials for bio-sensing device applications.

o Active collaborations include researchers from leading institutes in the US: Los Alamos National Labs, Drexel University, Purdue, Rice, University of Central Florida, as well as international collaborations.

o Recipient of the University of Texas System’s Science and Technology Acquisition and Retention (STARs) Award for equipment acquisition for the establishment of NDL ($500,000).

o Currently advising one Research Scientist, two Postdoctoral Scholars, eight graduate students; undergraduates and high-school students are also actively involved in research at NDL.

National Science Foundation Arlington, VA 2011 – 2014

Program Director

Electronics, Photonics and Magnetic Devices Program, ECCS Division, ENG Directorate 2011 – 2014

Created New Initiative with Total Funding ~ $30 Million o Championed the creation of a new $30 Million ($15 Million/year for 2 years), multi-disciplinary

initiative on 2D atomic-layered materials & devices beyond graphene at NSF. Initiative includes collaboration with the Department of Defense (DoD).

o Top-rated topic from more than 160 concept submissions nationwide; topic selection made using rigorous external (US-wide) and internal (NSF-wide) review.

Managed Core Technology Portfolio (~ $8 Million) & Targeted Initiatives (> $10 Million) o Developed, coordinated and managed programs in the following core technology areas: carbon-

based electronics; micro & nanoelectronics; energy-efficient green electronics; flexible & printed electronics; organic light emitting devices for solid-state lighting & displays; molecular & organic electronics. Includes NSF’s CAREER program.

Targeted Initiatives: o Scalable Nanomanufacturing (SNM), Cognizant Program Director (ECCS Division): Awarded ~

$2.7 Million in research funding. SNM is in response to the National Nanotechnology Initiative (NNI) Signature Initiative on Sustainable Nanomanufacturing that seeks novel processes and techniques for continuous and scalable nanomanufacturing, including self-assembly processes, among other techniques.

o Major Research Instrumentation Program (MRI), 2012 ECCS Division Representative: Awarded ~ $2.5 Million in research funding. MRI solicitation seeks to increase access to shared scientific and engineering instruments for research, training and education.

o Failure-resistant Systems, Cognizant Program Director (ECCS Division): Assisted in review & award process. NSF/SRC initiative seeks to explore compelling research to develop reliable failure resistant systems, particularly in the design of robust electronic devices, circuits and systems.

o Engineering Research Centers (ERC), Co-Program Director (Co-PD): Two funded centers at ~ $36 Million. Site visit team member and Co-PD for two Nanosystems ERCs (NERC) Programs initiated in 2012.

o Network for Computational Nanotechnology (NCN), Nano-Engineered Electronic Device Simulation node (NEEDS) Node, Co-Program Director: Co-PD with total funding at ~ $4 Million.

Page 5: CURRICULUM VITAE ANUPAMA BHAT KAUL EDUCATIONhb2504.utep.edu/vitas/akaul.pdf · Anupama B. Kaul, Mar. 2017 Page 5 of 33 NEEDS is designed to develop computation, simulation and educational

Anupama B. Kaul, Mar. 2017 Page 5 of 33

NEEDS is designed to develop computation, simulation and educational services and includes the current nanoHUB tools.

Other Activities & Workshops o Emerging Frontiers in Research and Innovation (EFRI), Working Group, ECCS Division

Representative: EFRI seeks to select frontier topics that are transformative and address a national need or grand challenge area.

o Initiated Workshop on “2D Materials and Devices Beyond Graphene” (joint with Air Force Office of Scientific Research (AFOSR), MPS/Division of Materials Research (DMR)).

o Initiated Workshop on “Next Generation Organic Photovoltaics” (joint with Office of Naval Research (ONR)).

Program Director Emerging Frontiers in Research and Innovation (EFRI) Office, ENG Directorate 2013 – 2014

o Leading the coordination, execution and management of 2-Dimensional Atomic-layer Research and Engineering (2-DARE) EFRI program ($30 Million total funding over 2 years). Webcast of program at: http://www.tvworldwide.com/events/nsf/130905/default.cfm?logout=1

o Thrust Lead for electronics, photonics and magnetic properties and device applications, in addition to nanomanufacturing components for 2-DARE initiative.

o Invited speaker at Engineering Advisory Committee (ENG ADCOM) Spring meeting to present goals and vision for EFRI 2-DARE, April 2014.

Jet Propulsion Laboratory (JPL), Caltech, NASA, Pasadena, CA 2002 – 2014

Task Manager & Principal Investigator 2005 – 2014

Project Management: Directed activities of researchers and provided feedback on their performance evaluations; initiated and led meetings; budgeting, forecasting, and scheduling. Provided technical progress reviews to senior JPL management, including the Office of the Chief Scientist and Chief Technologist.

Nanomaterials for Optical Absorber and Energy Harnessing Applications o Under the JPL Research & Technology (R&TD) Development Award, led the synthesis and

characterization of carbon nanostructures that are demonstrated to have optical absorption characteristics 100 X superior compared to the reference over a broad spectral range from UV-to-IR.

o Demonstrated the optical properties of such nano-absorbers could be engineered by controlling the bottom-up synthesis conditions, and modeled data according to theory in collaboration with faculty at the University of California, San Diego.

o Demonstrated the exceptional thermo-mechanical resilience of the nanostructured optical absorbers which were extremely rugged compared to conventional metal-black absorbers.

o Initiating the use of colloidal quantum dot nanocrystals (e.g. CdS), as well as organic semiconductors for energy harnessing applications.

Nanomaterials and Architectures for Extreme Environment Electronics o Under the JPL Research & Technology (R&TD) Development Award, led the development of

nano-electro-mechanical (NEM) switches for extreme environment electronics applications; strategic technology development for NASA’s future potential missions to extreme planetary environments (e.g. Venus or Europa).

o Led effort to develop growth and nanofabrication techniques to form isolated and aligned carbon nanofibers (CNFs) for 3D NEM switch architectures. Extending effort for creating CNF-based

Page 6: CURRICULUM VITAE ANUPAMA BHAT KAUL EDUCATIONhb2504.utep.edu/vitas/akaul.pdf · Anupama B. Kaul, Mar. 2017 Page 5 of 33 NEEDS is designed to develop computation, simulation and educational

Anupama B. Kaul, Mar. 2017 Page 6 of 33

mechanical resonators for mass-sensing and biomedical applications in collaboration with Case Western Reserve University.

o Led the effort to develop nanomanipulation techniques for probing the electrical and mechanical properties of individual vertically oriented CNFs in collaboration with Caltech Faculty at the Kavli Nanoscience Institute.

Materials for Sensors and High-frequency Applications o Led the development of novel carbon nanotube (CNT) based pressure sensors for vacuum micro-

electronics with potential applications in NASA and DoD high frequency vacuum electronics, field emitters and micro-gyroscopes.

o Explored the use of GaN-based high-electron-mobility-transistors (HEMT) devices for harsh-environment chemical sensing applications by appropriately controlling the choice of the gate-electrode metal which can react to various chemical threats.

o Implemented vacuum encapsulation techniques with nanogetters for packaging CNT-based field emitters as miniature emission sources at THz frequencies for space instruments.

o Developed processes with JPL team to form deep sub-micron quantum computing devices for high density circuits that led to demonstrating the first 16-qubit quantum processor.

Switching Devices Derived From Single-walled Carbon Nanotubes (SWCNTs) o Under the National Reconnaissance Office (NRO) Director’s Innovation Initiative (DII) Award, led

the exploration of SWCNT switches for nanoelectronics applications. o Led the effort for integrating new inorganic materials with SWCNTs, where the catalyst was pre-

defined for the on-chip synthesis of the SWCNTs. o Demonstrated low voltage, high frequency switching devices.

NASA Program Office Management 2010 – 2011

Member of Technical Review Board for selecting innovative and strategic concepts for technology development in support of future NASA Planetary Science Missions.

Engaged in Science and Compliance Reviews (SCRs) for providing technical and programmatic feedback to JPL Principal Investigators for proposals submitted to NASA Research Opportunities in Earth and Space Sciences (ROSES) calls in various Planetary Science Programs.

Member Technical Staff 2002 – 2005

Developed micromachining techniques to form high bandwidth coherent detectors based on heterodyne mixers for sub-millimeter-wave frequencies on ultra-thin membranes of Si with suspended metal beam leads on SOI substrates. Electrical characterization of devices targeted for atmospheric chemistry applications in the 200-300 GHz band for the Scanning Microwave Limb Sounder, potential NASA Earth Science Mission.

Conceived, implemented and demonstrated the use of a low energy nitrogen ion-beam to form ultra-thin AlN layers for tunnel barrier applications in quantum-scale devices.

Motorola Labs, Advanced Technology Center, Schaumburg, IL 2000 – 2002 Senior Research Engineer

Designed and characterized RF MEMS switches formed using organic materials on flexible substrates, for their application in wireless communication systems for a DARPA-sponsored RF MEMS program.

Performed modeling and dielectric characterization of organic substrate materials to identify low loss materials at microwave frequencies.

Managed research collaboration with electrical engineering faculty and graduate students at the University of Missouri-Rolla for this DARPA RF MEMS Consortium led by Motorola Labs.

Page 7: CURRICULUM VITAE ANUPAMA BHAT KAUL EDUCATIONhb2504.utep.edu/vitas/akaul.pdf · Anupama B. Kaul, Mar. 2017 Page 5 of 33 NEEDS is designed to develop computation, simulation and educational

Anupama B. Kaul, Mar. 2017 Page 7 of 33

Hewlett-Packard Company, R&D Division, Corvallis, OR 1993 – 1995 R&D Engineer

Investigated performance of next generation surface micromachined ink-jet print-head designs. Implemented accelerated testing methods using Arrhenius modeling and statistical techniques for candidate materials selection. Results aided Marketing Division to set product life goals.

Designed test equipment to perform long life material characterization to identify stress-induced degradation mechanisms that impacted product lifetimes. Liaison between R&D sites of HP-San Diego and HP-Corvallis in consolidating test strategies for enabling long product lifetimes.

Raychem Corporation, R&D Division, Menlo Park, CA

Summer Intern Summer 1992

Designed, fabricated and tested circuit protection devices, known as polyswitches (resettable fuses) made from carbon-polymer composites. Studied effects of material parameters on device operation.

Applied a novel technique to demonstrate a Josephson junction (led to invention disclosure).

TEACHING EXPERIENCE

Courses Developed and Taught

University of Texas, El Paso, TX

“Micro-electro-mechanical-systems (MEMS) and BioMEMS: Fall 2016 Manufacturing, Device Operation and Applications”

Developed a new theory course (upper division undergraduate and cross listed for graduate students) to provide an introduction to MEMS and how conventional MEMS has been adapted to enabling advances in biomedical devices. Course offered as Special Topics: EE 4395; EE 5390; BME 5390.

Topics discussed include: Si as a mechanical material; basic manufacturing processes for MEMS; bulk and surface micromachining; soft-lithography processes; thermal, electrostatic, piezoelectric and magnetic transduction for sensing and actuation; BioMEMS and cantilever-based biosensors; nanopores for DNA sequencing; basic concepts in microfluidics and microfluidic components and systems; Lab-on-

Chip (LOC) and Micro-Total-Analysis-Systems (TAS).

Research Driven Course (RDC) supported by the National Institute of Health (NIH) Fall 2016 BUilding Infrastructure Leading to Diversity (BUILD) Program at UTEP RDC Course: “Biomedical Assays Using Batch-fabricated MEMS-based Microfluidic Devices”

Developed a new lab course targeted toward MEMS-based fabrication techniques where students obtain hands-on-training for designing and creating MEMS-based structures, particularly as they relate to microfluidic devices and their use in biomedical applications for disease detection. RDC reinforces concepts learned in MEMS-based theory course offered concurrently, where students make LOC devices to validate DNA-amplification and polymerase chain reaction (PCR) in a microfluidic platform for disease detection.

RDC facilitated through the NIH-BUILD program that provided funding for this competitively-selected proposal for lab course development at ~ $35K. RDC developed in collaboration with faculty from Chemistry. Course offered as EE 4171/EE 5191.

Advanced Functional Materials: Properties, Synthesis and Device Applications Spring 2015, 2016 Developed a new graduate-level course (cross listed for seniors) on the electronic, optical and

magnetic properties of materials. Topics covered include: classical mechanics and evolution toward

Page 8: CURRICULUM VITAE ANUPAMA BHAT KAUL EDUCATIONhb2504.utep.edu/vitas/akaul.pdf · Anupama B. Kaul, Mar. 2017 Page 5 of 33 NEEDS is designed to develop computation, simulation and educational

Anupama B. Kaul, Mar. 2017 Page 8 of 33

quantum mechanical concepts, crystal structure, bonding and how the band-structure formalism explains the properties of materials in the solid-state. Semiconducting device physics of junctions and transistors. Moore’s law scaling and the need for energy-efficient electronics which has paved the way for beyond-Si materials.

The module on synthesis begins with thin film physics, invoking concepts from thermodynamics and kinetics for nucleation and growth. These concepts are leveraged for the illustration of synthesis mechanisms in organic and inorganic materials and nanostructures. Examples of techniques discussed include physical vapor deposition, chemical vapor deposition, solution-based approaches, among others. Course offered as Special Topics that is cross listed in the Electrical Engineering Department, and the Metallurgical and Materials Engineering program (MASE) Program: EE 5390, MME 5390; EE 4395.

Instructor Rating: 2015 – 4.3/5.0; 2016 – 4.83/5.0 Course Rating: 2015 – 4.5/5.0; 2016 – 4.83/5.0

Guest Lecturer

University of Texas, El Paso, TX Electrical and Computer Engineering Department Spring 2016

Guest lecturer for the Junior Professional Orientation (JPO) Seminar (EE 3195) to discuss “The Benefits of a Graduate Education”

Biomedical Engineering Program Spring 2015

Guest lecturer to first year Biomedical Engineering Graduate Students entitled “Interdisciplinary Research Trends in STEM”

Other Indian Institute of Technology-New Delhi, India Summer 2015

Department of Electrical and Computer Engineering Developed and delivered a module on “Nanotechnology, Nanocarbons & New Frontiers in

Advanced Materials Research,” to seniors and graduate students.

University of Maryland, College Park, MD Fall 2013 Department of Electrical and Computer Engineering

Developed a module on “Carbon-based materials and devices” and “Novel materials for the beyond-CMOS era” for upper-division courses: a) Fundamentals of Solid State Electronics; b) Introduction to Device Physics.

Teaching Assistant

University of California at Berkeley, Berkeley, CA Fall 1998 Head Teaching Assistant, Department of Electrical Engineering Supervised lab work of seniors and graduate students for Si integrated circuit design and processing, including MEMS devices (EE 143).

Oregon State University, Corvallis, OR Teaching Assistant, Department of Physics Fall 1992

Instructed and supervised students in introductory mechanics and waves (PH 201).

Page 9: CURRICULUM VITAE ANUPAMA BHAT KAUL EDUCATIONhb2504.utep.edu/vitas/akaul.pdf · Anupama B. Kaul, Mar. 2017 Page 5 of 33 NEEDS is designed to develop computation, simulation and educational

Anupama B. Kaul, Mar. 2017 Page 9 of 33

Instructor

Math Instructor, Math and Science Learning Center, Department of Mathematics Summer 1991 Assisted students on a one-on-one basis in calculus and differential equations.

OTHER MENTORING ACTIVITIES

VIP Speaker at the UTEP Women In eNgineering (WIN) Forum, UTEP Campus, 2016-2017 Academic Year. This forum is targeted to provide young female engineers with perspectives that can be beneficial to them as they embark on their professional careers.

Mentoring early career faculty at UTEP for providing them with support mechanisms to engage with funding agencies and in preparing their early career proposals to federal agencies.

Supervised summer students under NASA undergraduate summer research programs at JPL and worked with graduate students at Caltech on research programs.

Mentor for new engineering graduates to JPL; Certificate of Achievement by Mary E. Derro & General Eugene L. Tattini (JPL Deputy Director).

Served on faculty tenure committees and graduate students’ fellowships committees.

Invited to national meetings to serve as a role model and speak about approaches for encouraging young female students to pursue careers in Science, Technology, Engineering and Math (STEM) disciplines. Organizations that sought out my feedback on this topic included: IEEE, SWE, and CRA.

Participated in 'Shadow an Engineer' program on an on-going basis, part of a mentoring program for high school girls at Berkeley, CA, and JPL-Caltech.

Guest Speaker, “Adventures in Space and Science: From the large to the ultra-small”, Pasadena Christian School (elementary school), Pasadena, CA 2009.

Mentor, Washington Elementary School, Berkeley, CA (during graduate school).

FUNDING HISTORY

Total funding obtained as PI and/or Co-PI = $3.9 Million from agencies such as the AFOSR, ARO, NSF, NRO, NASA, STARNet, etc.

HONORS & AWARDS

Fellow ELATE Class of 2016; Executive Leadership in Academic Technology and Engineering (ELATE) Program is a national year-long leadership development program for senior women faculty in Engineering, Science and Technology, administered by Drexel University.

UTEP AWARE Program Graduate, June 2016; a year-long program offered to selected faculty, administrators, and staff at UTEP to provide sessions for them to learn about campus programs, research directives, and history.

National Academy of Engineering (NAE), 2014 Indo-American Frontiers of Engineering (FOE) Symposium, invited participant, 2014.

National Science Foundation, Director’s Award for Program Management Excellence, 2013; Citation: “For leadership & collaborative excellence in developing the topic on 2D atomic-layered materials & devices beyond graphene as a stand-alone EFRI topic.” Only 2 awardees selected for Program Management Excellence from entire Engineering Directorate at NSF in 2013.

Page 10: CURRICULUM VITAE ANUPAMA BHAT KAUL EDUCATIONhb2504.utep.edu/vitas/akaul.pdf · Anupama B. Kaul, Mar. 2017 Page 5 of 33 NEEDS is designed to develop computation, simulation and educational

Anupama B. Kaul, Mar. 2017 Page 10 of 33

Invitation received for attending Grand Challenges Global Summit organized by US National Academy of Engineering (NAE), UK Royal Academy of Engineering (RAE), and Chinese Academy of Engineering (CAE), 2013.

NASA Service Award 2012.

National Academy of Engineering (NAE), 2012 US Frontiers of Engineering (FOE) Symposium as an invited participant, 2012.

Who’s Who in Science and Engineering (Marquis), 11th Edition (2011), and subsequent Editions; sampling across more than 100 countries.

NASA Patent Award, 2008, 2009, 2010 (3 Awards), 2011, 2012, 2013.

Who’s Who in America (Marquis), 63rd Edition (2008), and subsequent Editions.

Biltmore Who’s Who among Executives and Professionals, 2012-present

Senior Member of the IEEE, 2008 – present.

NASA Team Accomplishment Award, 2007.

Class 1 NASA Tech. Brief Award, 12 awards, 2004 – 2014.

4 Invention Awards at Motorola Labs, 2001 – 2002.

Best poster award, Workshop on Superconductor Electronics, Rosendale, NY, 1999.

Finalist, IBM Research Fellowship, University of California at Berkeley, 1999.

Paul Copson Memorial Scholarship, Oregon State University, 1991 – 1992.

Belknap Engineering Scholarship, Oregon State University, 1990 – 1992.

Hewlett-Packard Academic Award, Society of Women Engineers, 1989. Alpha Lambda Delta, Phi Eta Sigma, Sigma Pi Sigma, Phi Kappa Phi.

EDITORIAL / ADVISORY BOARDS

External Advisory Board Member, Penn State University’s 2D Crystal Consortium (2DCC), A National User Facility funded by the NSF Division of Materials Research (DMR), Materials Innovation Platform (MIP) at ~ $18 Million for 5 years, renewable for an additional 5 years; 5/2016 – present.

Scientific Committee Member, International Conference on Nanomaterials, Nanodevices, Fabrication and Characterization (CNNFC’16), Prague, Czech Republic, April, 2016, 2017.

Elected Member of the Awards Committee, National Science Foundation, Summer 2014.

Regional Vice President (America), Thin Films Society (TFS), 2014-2016.

International Advisory Panel, Materials Research Express, Institute of Physics (IOP) Publishers, 2013-present.

Semiconductor Research Corporation (SRC) Global Forum 2014, Steering Committee Member for Forum on Nanoelectronic Manufacturing: From Materials to Systems, 2013-2014.

IEEE NANO 2013, Awards Committee Member, 2013.

Associate Editor, IEEE Sensors Journal, 2012-present.

MRS 2012 Fall Meeting, Awards Committee Member (Best poster award), 2012.

MRS Bulletin Summary Coordinator for Fall 2012 Symposium WW: Roll-to-Roll Processing of Electronics and Advanced Functionalities.

IEEE Electron Devices Society Ph.D./M.S. Fellowships Committee, 2012-2014.

Engineering Research Centers (on nanosystems, 2 independent centers), Site Visiting Committee, Co-Program Director, National Science Foundation, 2012-2014.

American Editor, Nanoscience and Nanotechnology Letters, 2010 – present.

Associate Editor, Reviews in Advanced Sciences and Engineering, 2011 – present.

MicroTech Advisory Board Member, Nano Science and Technology Institute (NSTI), 2010 – present.

Editorial Board Member, Journal of Nanoengineering and Nanomanufacturing, 2011-present.

Page 11: CURRICULUM VITAE ANUPAMA BHAT KAUL EDUCATIONhb2504.utep.edu/vitas/akaul.pdf · Anupama B. Kaul, Mar. 2017 Page 5 of 33 NEEDS is designed to develop computation, simulation and educational

Anupama B. Kaul, Mar. 2017 Page 11 of 33

Editorial Board Member, Open Process Chemistry Journal, 2008 – present.

CONFERENCES & WORKSHOPS ORGANIZED

Conference Organizing Committees

Organizing Committee Member (abstract reviewer), International Conference on Nanomaterials,

Nanodevices, Fabrication and Characterization (CNNFC’16, ‘17), Prague, Czech Republic, April 2016,

2017.

CIMTEC 2016 – International Conferences on Modern Materials and Technologies, International

Advisory Board Member, Symposium F – “Graphene and Other Emerging 2D-layered Nanomaterials:

Synthesis, Properties and Potential Applications,” Perugia, Italy, June 2016; Session Chair: Session F-6 –

Application of Graphene and Other 2D Layered Materials and Composites, Perugia, Italy, June 2016.

ISDRS (International Semiconductor Device Research Symposium) 2013, Program Committee Member,

Bethesda, MD, Dec. 2013 – present.

IEEE 2015 Summer Topicals Meeting Series, Topic Chair, “Functional Two-dimensional Materials

(FTDM)”, Nassau, Bahamas, July 2015.

ICON (International Conference on One-dimensional Nanomaterials) 2015, General Conference Co-

chair, Bethesda, MD, August 2015.

2014 TechConnect World Technology Committee (NSTI); Symposium Chair, “Organic, Flexible and

Printed Electronics,” Washington D.C., June 2014.

2013 IEEE NANO, Technical Program Committee, Beijing, China, August 2013.

2013 IEEE NANO Track Chair, “Nanoelectronics: Graphene, Carbon Nanotubes and Nanowires” Beijing,

China, August 2013.

2013 IEEE NANO Session Chair: Nanoelectronics: Nanotubes and Nanowires, Beijing, China, August

2013.

2013 TechConnect World Technology Committee (NSTI); Symposium Chair, “Organic and Flexible

Electronics,” Washington D.C., May 2013.

Nanotech Conference & Expo’13, Session Chair: Flexible and Organic Electronics I, Washington D.C.

May 2013.

Nanotech Conference & Expo’13, Session Chair: Flexible and Organic Electronics II, Washington D.C.

May 2013.

2013 MRS Spring Meeting, Symposium Co-organizer, “Beyond Graphene - 2D Atomic Layers from

Layered Materials,” San Francisco, CA, April 2013.

MRS 2013 Spring Meeting, Session Chair: Transport in 2D-Layered Materials, San Francisco, CA, April

2013.

MRS 2013 Spring Meeting, Session Chair: Characterization of 2D-Layered Materials, San Francisco, CA,

April 2013.

MRS 2013 Spring Meeting, Session Chair (Poster): Characterization and Optical Properties of 2D-

Layered Materials, San Francisco, CA, April 2013.

2012 IEEE NANO, Technical Program Committee, Birmingham, England, August 2012.

2012 IEEE NANO Track Chair, “Nanoelectronics: Graphene, Carbon Nanotubes and Nanowires,”

Birmingham, England, August 2012.

Page 12: CURRICULUM VITAE ANUPAMA BHAT KAUL EDUCATIONhb2504.utep.edu/vitas/akaul.pdf · Anupama B. Kaul, Mar. 2017 Page 5 of 33 NEEDS is designed to develop computation, simulation and educational

Anupama B. Kaul, Mar. 2017 Page 12 of 33

2012 IEEE NANO Session Chair: Graphene Growth and Fabrication, Birmingham, England, August 2012.

2012 IEEE NANO Session Chair: Graphene Device Applications, Birmingham, England, August 2012.

MRS 2012 Fall Meeting, Symposium Co-organizer, “Roll-to-Roll Processing of Electronics & Advanced

Functionalities”, Boston, MA, Nov 2012.

MRS 2012 Fall Meeting, Session Chair: Transfer Printing and Nanomanufacturing II, Boston, MA, Nov.

2012.

MRS 2012 Fall Meeting, Session Chair (Poster): Roll-to-Roll Processing of Electronics & Advanced

Functionalities, Boston, MA, Nov. 2012. Poster Award committee co-chair.

MRS 2012 Fall Meeting, Session Chair: Materials Aspects of Roll-to-Roll Production I, Boston, MA, Nov.

2012.

2012 IEEE Electron Devices and Solid State Circuits Society (EDS) Colloquium on Energy Harvesting

Devices, Chair, Panel Discussion, University of Maryland, Sep. 2012.

2012 TechConnect World Technology Committee; Symposia Chair, “Nanostructured Materials and

Devices,” Santa Clara, CA, June 2012.

2012 TechConnect World Program Review Committee, Santa Clara, CA, June 2012.

Nanotech Conference & Expo’12, Session Chair: Flexible Electronics I, CA, June 2012.

Nanotech Conference & Expo’12, Session Chair: Flexible Electronics II, CA, June 2012.

Microtech Conference & Expo’12, Session Chair: Green Electronics I, CA, June 2012.

Microtech Conference & Expo’12, Session Chair: Green Electronics II, CA, June 2012.

2011 TechConnect World 2011 Program Review Committee (Nanotech 2011, NanoBio 2011 and

MicroTech 2011), Boston, MA, June 2011.

SPIE 2010 Conference Program Committee SPIE’s Micro-Nanotechnology Sensors, Systems and

Applications; Defense, Securities and Sensing Conference, Orlando, FL, Mar. 2010.

SPIE’s 2010 Micro-Nanotechnology Sensors, Systems and Applications, Session Chair: Nanoelectronics

and High Frequency MEMS and NEMS, Orlando, FL, Mar. 2010.

SPIE 2009 Conference Program Committee SPIE’s Micro (MEMS) and Nanotechnologies for Space,

Defense and Securities Conference, Orlando, FL, April 2009.

SPIE’s 2009 Micro-Nanotechnology Sensors, Systems and Applications, Session Chair: Complex MEMS

and Nanosystems; SPIE’s Micro (MEMS) and Nanotechnologies for Space, Defense and Securities

Conference, Orlando, FL, April 2009.

IEEE Applied Superconductivity Conference 2006, Session Chair: Low Temperature Fabrication, Applied

Supercond. Conf., Seattle, WA, Aug. 2006.

IEEE Applied Superconductivity Conference 2006, Session Chair: Novel Fabrication, Applied Supercond.

Conf., Seattle, WA, Aug. 2006.

Workshops Organized

Chair, Engineering Research Forum, showcasing interdisciplinary collaborations within Engineering, and

Sessions for engagement of new tenure-track faculty and postdoctoral scholars within College, UTEP

Campus, Dec. 2016.

US Co-Chair, EU-US Workshop on 2D Materials, Heterostructures and Devices, National Graphene

Institute, University of Manchester, Manchester, United Kingdom, October 2016; Primary organizer is

Page 13: CURRICULUM VITAE ANUPAMA BHAT KAUL EDUCATIONhb2504.utep.edu/vitas/akaul.pdf · Anupama B. Kaul, Mar. 2017 Page 5 of 33 NEEDS is designed to develop computation, simulation and educational

Anupama B. Kaul, Mar. 2017 Page 13 of 33

the EU Graphene Flagship Program funded at the level of ~ $1 Billion Euros over 10 years;

http://graphene-flagship.eu/eu-us-workshop-2016.

Chair & PI, NSF US-EU Workshop on 2D Layered Materials and Devices, Arlington, VA, April 2015

(http://engineering.utep.edu/useu2dworkshop/index.htm). Workshop subsequently led to the

issuance of a Dear Colleague Letter by the NSF in July 2016.

https://www.nsf.gov/pubs/2016/nsf16102/nsf16102.jsp?org=ENG)

NSF/AFOSR Workshop on 2D Materials and Devices Beyond Graphene, Arlington, VA, May 2012

(http://nsf2dworkshop.rice.edu/).

NSF/ONR Workshop on Key Scientific and Technological Issues for the Development of Next Generation

Organic Solar Cells, Arlington, VA, Sep. 2012 (http://web.utk.edu/~opvwshop/).

PROFESSIONAL ACTIVITIES

Reviewer for Journals and Books

Nature Publishing Group (NPG): Nature Nanotechnology

American Chemical Society’s (ACS): Nano Journal, Nano Lett.

American Institute of Physics (AIP): Applied Physics Letters

Elsevier’s: Applied Materials Today

Institute of Physics (IOP): 2D Materials Journal

IEEE: IEEE Transactions on Applied Superconductivity, IEEE Transactions on Nanotechnol., IEEE Sensors Journal

American Vacuum Society (AVS): Journal of Vacuum Science and Technology – B

Elsevier Science’s: Thin Solid Films Journal

Micro and Nano Letters Journal

Technical reviewer (general): IEEE, ACS, MRS, AVS

Technical Reviewer, Book Proposal: Metallic Oxynitride Thin Films by Reactive Sputtering: Processes, Properties and Applications, Mar. 2009.

Technical Reviewer: papers in Nanoscale Materials and Devices Session, MRS, 2006, 2008, 2009.

Technical Reviewer: papers in Micro and Nano Devices Session within MEMS Division, ASME International Mechanical Engineering Congress and Exposition (IMECE), 2006, 2007, 2008.

Reviewer for Proposals

Reviewer, Air Force Office of Scientific Research (AFOSR), for Young Investigator Program (YIP) from DoD for proposal in nanomaterials, 2016.

Reviewer for the National Science Foundation (NSF) Panel on Nanotechnology for proposals ranging from $4 Million - $10 Million, 2015.

Reviewer, Air Force Office of Scientific Research (AFOSR), for DURIP and regular submission proposal on nanomaterials for THz applications, 2014, 2015.

Review Board Member, Department of Defense (DoD), for entire review process ranging from initial white papers to full proposals and award selection in the area of novel nanomaterials for device applications, 2013.

Technical Reviewer, NASA SBIR Phase I proposal for using metallic nanoparticles to enhance surface plasmon resonance for bolometer/detector applications, 2009.

Technical Reviewer, NASA SBIR Phase I proposal for using mechanical detector arrays for long-wavelength infrared imaging applications, 2009.

Review Panel Member for the National Science Foundation (NSF), 2008.

Page 14: CURRICULUM VITAE ANUPAMA BHAT KAUL EDUCATIONhb2504.utep.edu/vitas/akaul.pdf · Anupama B. Kaul, Mar. 2017 Page 5 of 33 NEEDS is designed to develop computation, simulation and educational

Anupama B. Kaul, Mar. 2017 Page 14 of 33

Technical Reviewer, NASA SBIR Phase I proposal for using carbon nanotubes as infrared imaging detectors, 2007.

Review Board Member for proposals submitted to the Bio-Nano-Quantum Technology Initiative under the JPL Research and Technology Development Program, 2005.

Other Activities

Field Expert, for contributing to the European (EU) funded ObservatoryNANO project report for assessing the development stage and impact of technologies for universal memory (magnetic RAM, CNT RAM, etc.), 2010.

Consultant, Reuters Insight, Community of Experts, 2008 – present.

Societies

Senior Member: Institute of Electrical and Electronics Engineers (IEEE).

Member: Materials Research Society (MRS), American Chemical Society (ACS), Society of Women Engineers (SWE), Society of Physics Students (SPS).

PATENTS

1. A. B. Kaul “Methods for gas sensing with single-walled carbon nanotubes,” US Patent 8,529,124 B2,

California Institute of Technology, granted Sep. 2013.

2. H. M. Manohara, and A. B. Kaul, “Carbon nanotube vacuum gauges with wide-dynamic range and

processes thereof,” US Patent 8,387,465 B2, California Institute of Technology, granted Mar. 2013.

3. A. B. Kaul, L. W. Epp, and L. Bagge, “Applications and methods of operating a three-dimensional nano-

electro-mechanical resonator and related devices,” US Patent 8,435,798 B2, California Institute of

Technology, granted May 2013.

4. A. B. Kaul and J. B. Coles, “Thermally-resilient, broadband optical absorber from UV-to-IR derived from

carbon nanostructures and method of making the same,” US Patent 8,947,800 B2, California Institute of

Technology, granted Feb. 2015.

5. A. B. Kaul, E. W. Wong, R. Baron, and L. Epp, “Carbon nanotube switches for memory, RF

communication and sensing applications and methods of making the same,” US Patent 7,446,044,

California Institute of Technology, granted Nov. 2008.

6. A. B. Kaul and A. R. Khan, “Nano-electro-mechanical switches using three-dimensional sidewall-

conductive carbon nanofibers and method for making the same,” US Patent application, California

Institute of Technology case number CIT 5438 (NPO 47157), July 2010.

7. A. B. Kaul, K. Megerian, P. von Allmen, and R. L. Baron, “Nanotubes and related manufacturing

processes,” US Patent application, California Institute of Technology case number CIT 5309 (NPO

46552), Jan. 2010.

8. A. B. Kaul, K. G. Megerian, A. T. Jennings, and J. R. Greer, “Monolithically integrated, mechanically

resilient, carbon-based probes for Scanning Probe Microscopy,” Provisional Patent application,

California Institute of Technology case number CIT 5439P (NPO 47185), Sep. 2009.

9. M. J. Bronikowski, A. B. Kaul, R. L. Baron, H. M. Manohara and T. Krabach, “High performance structural

materials based on carbon nanotubes,” Provisional Patent application, California Institute of Technology

case number CIT 4771P, filed Oct. 2006.

10. T. Van Duzer, X. Meng, N. Newman, L. Yu and A. B. Kaul, “Internally shunted Josephson junction device,”

US Patent 6,734,454 B2, University of California-Berkeley, granted May 2004.

Page 15: CURRICULUM VITAE ANUPAMA BHAT KAUL EDUCATIONhb2504.utep.edu/vitas/akaul.pdf · Anupama B. Kaul, Mar. 2017 Page 5 of 33 NEEDS is designed to develop computation, simulation and educational

Anupama B. Kaul, Mar. 2017 Page 15 of 33

INVENTION DISCLOSURES

1. A. B. Kaul and T. Klosowiak, “An approach to determine force-dependent microscopic properties of

materials in micro-electro-mechanical (MEM) devices,” Invention Disclosure, Advance Technology

Center, Motorola Labs, Sep. 2001.

2. A. B. Kaul, J. Liu, K. Lian, and M. Eliacin, “A current, voltage or temperature MEMS sensor fabricated on

an organic PWB substrate,” Invention Disclosure, Advance Technology Center, Motorola Labs, Apr.

2001.

3. A. B. Kaul, L. Lach, R. Lempkowski, and M. Eliacin, “High Q, low cost switchable resonators enabled by a

PWB MEMS process” Invention Disclosure, Advance Technology Center, Motorola Labs, Feb. 2001.

4. L. Grajales and A. B. Kaul, “Over-voltage, under-voltage sensor and normally closed and/or dual-state-

dual-output MEMS switches,” Invention Disclosure, Advance Technology Center, Motorola Labs, Jan.

2001.

5. A. Bhat and R. Adamic, “A method of selectively etching Al embedded in a polymer laminate thick film”

Invention Disclosure, R&D Center Ink-Jet Division, Hewlett Packard Company, Mar. 1994.

6. M. Heaney and A. Bhat, “Josephson junctions made using a Nb-polymer composite” Invention

Disclosure, R&D Center, Raychem Corporation, Dec. 1992.

NEWS RELEASES

UTEP led workshop carves out international collaborative research opportunities: http://engineering.utep.edu/research093016.htm; Sep. 2016.

UTEP leads NSF US EU Workshop on 2D Layered Materials and Devices. Please see workshop final report, approved for public release, at link: http://engineering.utep.edu/useu2dworkshop/index.htm; April, 2015.

Kaul serves as PI and US Chair of NSF Sponsored Workshop, See announcement: http://engineering.utep.edu/announcement072915.htm; April 2015.

Kaul selected to participate in year long fellowship under ELATE program, a National Leadership Program. See announcement: http://engineering.utep.edu/announcement070615.htm; April, 2015.

SPIE Newsroom: A. B. Kaul, “Two-dimensional atomic layered materials and their applications,” (Nanotechnology), http://spie.org/x103763.xml, 2013.

Featured on NSF Weekly-Wire: “On the flip-side”, an NSF-wide publication that features selected staff-members, Fall 2013.

National Academy of Engineering (NAE): “Creative young engineers selected to participate in NAE’s 2012 U.S. Frontiers of Engineering Symposium,” http://www.nae.edu/Activities/MediaRoom/20095/54489/60785.aspx, June 2012.

Nanotechweb Newsroom: A. B. Kaul, K. Megerian, A. T. Jennings and J. R. Greer, “Tiny whiskers of carbon probed for the 3D electronics role,” http://nanotechweb.org/cws/article/lab/43649, Sep. 2010.

Nanotechweb Newsroom: A. B. Kaul, K. Megerian, P. von Allmen, and R. L. Baron, “Wafer-scale processes single out CNTs,” http://nanotechweb.org/cws/article/tech/38669, April 2009.

SPIE Newsroom: A. B. Kaul, Larry Epp and E. W. Wong, “Carbon nanotube mechanical relays for electronic applications,” SPIE Newsroom (Nanotechnology), http://spie.org/x1004.xml, June 2008.

Nanotechweb Newsroom: A. B. Kaul “Carbon nanotubes wired to sense pressure,” http://nanotechweb.org/cws/article/tech/39554, June 2009.

Page 16: CURRICULUM VITAE ANUPAMA BHAT KAUL EDUCATIONhb2504.utep.edu/vitas/akaul.pdf · Anupama B. Kaul, Mar. 2017 Page 5 of 33 NEEDS is designed to develop computation, simulation and educational

Anupama B. Kaul, Mar. 2017 Page 16 of 33

Frost and Sullivan Tech Alerts: A. B. Kaul “Single nanotubes in 3D nanoscale architectures,” http://www.frost.com/prod/servlet/ti-services-alerts.pag

Press release of DWave’s 16-qbit quantum processor, Museum of Computing History, Mountain View, CA, Feb. 2007; part of JPL team that developed processes to form circuits to help launch the 16-qubit processor demonstration.

PEER-REVIEWEED PUBLICATIONS 1. A. S. Bandyopadhyay, G. A. Saenz, and A. B. Kaul, “Three-terminal, ambipolar WSe2 photo-transistors,”

manuscript in preparation, to be submitted, Jan. 2017. 2. A. S. Bandyopadhyay, C. Biswas, and A. B. Kaul, “Temperature-dependent Raman and

photoluminescence measurements of WSe2 and extraction of phonon dynamics and lifetime,” manuscript submitted, (in review) 2017.

3. A. S. Bandyopadhyay, N. Adhikari, S. Chugh, and A. B. Kaul, “Synthesis and characterization of two-dimensional WSe2 grown using chemical vapor deposition,” manuscript in preparation, to be submitted 2017.

4. G. L. Saenz, C. De Anda, and A. B. Kaul, “Optimization of monolayer CVD-grown 2D MoS2 using surface

enhancers,” manuscript in preparation, to be submitted 2017.

5. G. L. Saenz, D. Fadil, and A. B. Kaul, “Stability analysis of the electronic transport properties of black

phosphorous at cryogenic temperatures,” manuscript in preparation, to be submitted 2017.

6. A. Delgado, J. A. Catalan, H. Yamaguchi, C. N. Villarrubia, A. D. Mohite, and A. B. Kaul, “ Opto-electro-

mechanical percolative composites from 2D layered materials: properties and applications in strain

sensing,” manuscript submitted (in review), 2017.

7. G. L. Saenz, G. Karapetrov, J. Curtis, and A. B. Kaul, “ Ultra-high photoresponsivity for suspended, few-

layer MoS2 photodetector with low Schottky barrier contacts,” manuscript submitted, (in review), 2016.

8. R. Hossain, I. Deaguero, T. Boland, and A. B. Kaul, “Large-format, biocompatible, ink-jet printed 2D-heterojunction photodetector on flexible substrates,” manuscript submitted, 2D Materials and Applications (Nature Partner Journal) (in review), 2017.

9. M. Michel, C. Biswas, R. Hossain, C. Tiwary, P. M. Ajayan, and A. B. Kaul, “A thermally-invariant, high-power graphite resistor for flexible electronics formed using additive manufacturing,” manuscript submitted, 2D Materials Journal (in review), Dec. 2016.

10. D. Fadil, R. F. Hossain, G. A. Saenz, and A. B. Kaul, “On the chemically-assisted excitonic enhancement in

environmentally-friendly solution dispersions of two-dimensional MoS2 and WS2,” manuscript

submitted, Journal of Materials Chemistry C (in review), Dec. 2016.

11. M. Michel, C. Biswas, and A. B. Kaul, “High-performance ink-jet printed graphene resistors formed with environmentally-friendly, surfactant-free inks for extreme thermal environments,” Applied Materials Today 6, 16 (2017).

12. M. Michel, J. A. Desai, C. Biswas, A. Delgado, and A. B. Kaul, “Engineering chemically exfoliated

dispersions of 2D graphene and molybdenum disulphide for ink-jet printing,” Nanotechnology 27, 485602

(2016).

13. A. B. Kaul, “Two-dimensional layered materials: structure, properties and prospects for device

applications,” invited feature paper Journal of Materials Research, Focus Issue 29, 348-361 (2014).

14. A. B. Kaul, J. B. Coles, K. G. Megerian, M. Eastwood, R. O Green, and P. R. Bandaru, Small 9, 1058 (2013).

Page 17: CURRICULUM VITAE ANUPAMA BHAT KAUL EDUCATIONhb2504.utep.edu/vitas/akaul.pdf · Anupama B. Kaul, Mar. 2017 Page 5 of 33 NEEDS is designed to develop computation, simulation and educational

Anupama B. Kaul, Mar. 2017 Page 17 of 33

15. A. B. Kaul, J. B. Coles, K. G. Megerian, M. Eastwood, R. O Green, T. Pagano, P. R. Bandaru and M. Dokmeci

Sensors and Transducers Journal 13, 109 (2011).

16. A. B. Kaul, K. G. Megerian, L. Bagge, L. Epp, H. G. LeDuc, J. B. Coles, M. Eastwood, R. O. Green and M.

Foote, Nanosci. and Nanotechnol. Lett. 2, 170 (2010).

17. A. B. Kaul, A. R. Khan, K. G. Megerian, L. Epp, L. Bagge, A. T. Jennings, D. Jang, and J. R. Greer, Nanosci.

and Nanotechnol. Lett. 2, 163 (2010).

18. A. B. Kaul, K. G. Megerian, A. Jennings, and J. R. Greer, Nanotechnology 21, 315501 (2010).

19. L. Bagge, L. Epp, A. Khan, and A. B. Kaul, J. Nanosci. and Nanotechnol. 10, 6388 (2010).

20. S. Kang, D. Banerjee, A. B. Kaul, K. G. Megerian, Scanning 32, 42 (2010).

21. A. B. Kaul, P. von Allmen, K. Megerian, and R. L. Baron, Nanosci. and Nanotechnol. Lett. 1, 145 (2009).

22. R. Harris, F. Brito, A. J. Berkely, J. Johansson, M. W. Johnson, T. M. Lanting, P. Bunyk, E. Ladizinsky, B.

Bumble, A. Fung, A. Kaul, A. Kleinsasser, and S. Han, New Journal of Physics 11, 123022 (2009).

23. A. B. Kaul, A. Khan, L. Bagge, K. G. Megerian, H. G. LeDuc, and L. Epp, Appl. Phys. Lett. 95, 093103, (2009).

Also selected for the Virtual Journal of Nanoscale Science & Technology, Sep. 14 (2009).

24. A. B. Kaul, Nanotechnology 20, 155501 (2009).

25. B. Bumble, A. Fung, A. B. Kaul, A. W. Kleinsasser, and G. Kerber, IEEE Trans. Appl. Supercond. 19, 226

(2009).

26. A. B. Kaul and H. M. Manohara, IEEE Trans. on Nanotechnol. 8, 252 (2009).

27. T. Lanting, A. J. Berkely, B. Bumble, P. Bunyk, A. Fung, J. Johansson, A. Kaul, A. Kleinsasser, E. Ladizinsky,

F. Maibaum, R. Harris, M. W. Johnson, E. Tolkacheva, and M. H. S. Amin, Phys. Rev. B 79, 060509 (2009).

28. A. B. Kaul, K. Megerian, P. von Allmen, R. L. Baron, Nanotechnology 20, 075303 (2009).

29. R. Harris, M. W. Johnson, S. Han, A. J. Berkley, J. Johannsson, P. Bunyk, S. Govorkov, M. C. Thom, S.

Uchaikin, B. Bumble, A. Fung, A. B. Kaul, A. Kleinsasser, C. J. S. Truncik, M. H. S. Amin, and D. V. Averin,

Phys. Rev. Lett. 101,117003 (2008).

30. A. B. Kaul, A. W. Kleinsasser, B. Bumble, H. G. LeDuc and K. A. Lee, IEEE Trans. Appl. Supercond. 17, 198

(2007).

31. A. B. Kaul, E. W. Wong, L. Epp, and B. D. Hunt, Nano Lett. 6, 942 (2006).

32. A. B. Kaul, A. W. Kleinsasser, B. Bumble, H. G. LeDuc and K. A. Lee, J. Mater. Res. 40, 3047 (2005).

33. A. B. Kaul, B. Bumble, K. Lee, H. LeDuc, F. Rice, and J. Zmuidzinas, J. Vac. Sci. Tech. B. 22, 2417 (2004).

Also selected for Virtual Journal of Nanoscale Science & Technology 10 (2004).

34. A. B. Kaul, T. Sands, and T. Van Duzer, J. Mater. Res. 16, 1223 (2001).

35. A. B. Kaul and T. Van Duzer, IEEE Trans. Appl. Superconduct. 11, 88 (2001).

36. A. B. Kaul, L. Yu, N. Newman, J. Rowell, S. Whiteley, and T. Van Duzer, Appl. Phys. Lett. 78, 99 (2001).

37. A. Bhat, X. Meng, A. Wong, and T. Van Duzer, Supercond. Sci. and Tech. 12, 1030 (1999).

38. X. Meng, A. Bhat, and T. Van Duzer, IEEE Trans. Appl. Superconduct. 9, 3208 (1999).

39. A. Bhat, X. Meng, S. Whiteley, M. Jeffery, and T. Van Duzer, IEEE Trans. Appl. Superconduct. 9, 3232

(1999).

BOOK CHAPTERS

1. A. B. Kaul and J. T. Robinson, Review Chapter (invited), Graphene and Graphene Nano Ribbons:

Properties, Synthesis, and Electronic Applications, Graphene Science Handbook, vol. 3 (Electrical and

Page 18: CURRICULUM VITAE ANUPAMA BHAT KAUL EDUCATIONhb2504.utep.edu/vitas/akaul.pdf · Anupama B. Kaul, Mar. 2017 Page 5 of 33 NEEDS is designed to develop computation, simulation and educational

Anupama B. Kaul, Mar. 2017 Page 18 of 33

Optical Properties), Editors: M. Aliofkhazari, N. Ali, W. I. Milne, C. S. Ozkan, S. Mitura, J. L. Gervasoni, CRC

Press – Taylor & Francis Group, 2016. ISBN 9781466591318, CAT#K20507.

2. A. B. Kaul, J. Lee, and P. Feng, Review Chapter (invited), Carbon nanomaterials: Applications as high-

efficiency optical absorbers and high-performance nano-electro-mechanical-systems, Nanomaterials: A

Guide to Fabrication and Applications, Editors: Sivashankar Krishnamoorthy and Krzysztof Iniewski,

Chapter 10, pp. 237, CRC Press-Taylor & Francis Group, 2016. ISBN: 13:978-1-4665-9126-4.

3. A. B. Kaul, J. Lee, and P. Feng, Review Chapter (invited), Nanostructures and Characteristics of Carbon

Nanofibers, Encyclopedia of Nanotechnology, Editors: Bharat Bhushan, pp. 237 – 260, Springer, Oct.

2015. ISBN: 978-94-007-6178-0. DOI: 10.1007/978-94-007-6178-0_101008-1

4. A. B. Kaul and L. Epp (invited), Suspended Carbon Nanotubes: Physical Sensor and Actuator Applications,

Carbon Nanotubes, Editor: Mauricio Marulanda, IN-TECH, Vienna, Austria, pp. 375-394, March 2010.

ISBN 978-953-307-054-4 (downloaded more than 10,000 times).

5. A. B. Kaul and P. R. Bandaru, Review Chapter (invited), Electronic and Photonic Applications of One-

Dimensional Carbon and Silicon Nanostructures, Encyclopedia of Semiconductor Nanotechnology, Editor:

A. Umar, Chapter 2, vol. 3, pp. 1-71, American Scientific Publishers, CA (in press).

BOOKS and SPECIAL ISSUES

1. A. B. Kaul, Editor, Microelectronics to Nanoelectronics: Materials, Devices and Manufacturability, CRC

Press, 2012. ISBN 9781466509542.

2. A. B. Kaul and E. H. Yang, Guest Editors for Special Issue, Nanoscale Materials, Structures and Devices for

Sensors and Systems Applications, Nanosci. Nanotechnol. Lett. vol. 2, number 2 (2010).

3. T. Blaudeck, G. Cho, M. R. Dokmeci, A. B. Kaul and M. D. Poliks, Editors, Roll-to-Roll Processing of

Electronics and Advanced Functionalities, Materials Research Society Symposium Proceedings, vol. 1529,

Cambridge University Press (2013).

4. P. M. Ajayan, J. A. Garrido, K. Haenen, S. Kar, A. B. Kaul, C. J. Lee, J. A. Robinson, J. T. Robinson, I. D.

Sharp, S. Talapatra, R. Tenne, M. Terrones, A. L. Elias, M. Paranjape and N. Karche, Editors, Carbon

Functional Nanomaterials, Graphene and Related 2D-Layered Systems, Materials Research Society

Symposium Proceedings, vol. 1549, Cambridge University Press (2013).

B. BOOK CHAPTERS

6. A. B. Kaul and L. Epp (invited), Suspended Carbon Nanotubes: Physical Sensor and Actuator Applications, Carbon Nanotubes, Editor: Mauricio Marulanda, IN-TECH, Vienna, Austria, pp. 375-394, March 2010. ISBN 978-953-307-054-4 (downloaded more than 10,000 times).

7. A. B. Kaul and P. R. Bandaru, Review Chapter (invited), Electronic and Photonic Applications of One-

Dimensional Carbon and Silicon Nanostructures, Encyclopedia of Semiconductor Nanotechnology, Editor: A. Umar, Chapter 2, vol. 3, pp. 1-71, American Scientific Publishers, CA (in press).

8. A. B. Kaul and J. T. Robinson, Review Chapter (invited), Graphene and Graphene Nano Ribbons (GNRs) for

Novel Electronic, Nano-electro-mechanical, and Photonic Devices, Graphene Science Handbook, vol. 3 (Electrical and Optical Properties), Editors: M. Aliofkhazari, N. Ali, W. I. Milne, C. S. Ozkan, S. Mitura, J. L. Gervasoni, CRC Press (submitted, in press).

Page 19: CURRICULUM VITAE ANUPAMA BHAT KAUL EDUCATIONhb2504.utep.edu/vitas/akaul.pdf · Anupama B. Kaul, Mar. 2017 Page 5 of 33 NEEDS is designed to develop computation, simulation and educational

Anupama B. Kaul, Mar. 2017 Page 19 of 33

9. A. B. Kaul, J. Lee, and P. Feng, Review Chapter (invited), Carbon nanomaterials: Applications as high-

efficiency optical absorbers and high-performance nano-electro-mechanical-systems, Fabrication and Applications of NanoMaterials, Editors: G. Harling and K. Iniewski, CRC Press (submitted June 2014, in press).

10. A. B. Kaul, J. Lee, and P. Feng, Review Chapter (invited), Nanostructures and Characteristics of Carbon

Nanofibers, Encyclopedia of Nanotechnology, Editors: Bharat Bhushan, Springer (submitted Jan 2015, in press).

C. BOOKS and SPECIAL ISSUES

11. A. B. Kaul, Editor, Microelectronics to Nanoelectronics: Materials, Devices and Manufacturability, CRC Press, 2012. ISBN 9781466509542.

12. A. B. Kaul and E. H. Yang, Guest Editors for Special Issue, Nanoscale Materials, Structures and Devices for

Sensors and Systems Applications, Nanosci. Nanotechnol. Lett. vol. 2, number 2 (2010).

13. T. Blaudeck, G. Cho, M. R. Dokmeci, A. B. Kaul and M. D. Poliks, Editors, Roll-to-Roll Processing of Electronics and Advanced Functionalities, Materials Research Society Symposium Proceedings, vol. 1529, Cambridge University Press (2013).

14. P. M. Ajayan, J. A. Garrido, K. Haenen, S. Kar, A. Kaul, C. J. Lee, J. A. Robinson, J. T. Robinson, I. D. Sharp,

S. Talapatra, R. Tenne, M. Terrones, A. L. Elias, M. Paranjape and N. Karche, Editors, Carbon Functional Nanomaterials, Graphene and Related 2D-Layered Systems, Materials Research Society Symposium Proceedings, vol. 1549, Cambridge University Press (2013).

CONFERENCE PUBLICATIONS & PROCEEDINGS ARTICLES

1. A. S. Bandyopadhyay, G. A. Saenz, C. Biswas, and A. B. Kaul, “Characterization of monolayer tungsten

diselenide based devices under optical excitation,” abstract submitted to the SPIE Defense, Securities and

Sensing Conference, Anaheim, April 2017.

2. G. A. Saenz, D. Fadil, and A. B. Kaul, “Temperature-dependence of photocurrent generation mechanisms

in black phosphorus,” abstract submitted to the SPIE Defense, Securities and Sensing Conference,

Anaheim, April 2017.

3. A. S. Bandyopadhyay, G. A. Saenz, C. Biswas, and A. B. Kaul, “Synthesis and characterization of two-

dimensional WSe2 grown using chemical vapor deposition,” abstract 1745 accepted, to appear in Proc. of

the American Vacuum Society (AVS) 63rd International Symposium and Exhibition, Nashville TN, Nov.

2016.

4. J. Catalan, A. Delgado, and A. B. Kaul, “Two-dimensional layered materials for composites applications,”

abstract 1771 accepted, to appear in Proc. of the American Vacuum Society (AVS) 63rd International

Symposium and Exhibition, Nashville TN, Nov. 2016.

Page 20: CURRICULUM VITAE ANUPAMA BHAT KAUL EDUCATIONhb2504.utep.edu/vitas/akaul.pdf · Anupama B. Kaul, Mar. 2017 Page 5 of 33 NEEDS is designed to develop computation, simulation and educational

Anupama B. Kaul, Mar. 2017 Page 20 of 33

5. S. Chugh, C. Biswas, A. S. Bandyopadhyay, G. A. Saenz, L. Echegoyen, and A. B. Kaul, “Electronic transport

properties of hybrid graphene-C60 structures,” abstract 1760 accepted, to appear in Proc. of the

American Vacuum Society (AVS) 63rd International Symposium and Exhibition, Nashville TN, Nov. 2016.

6. J. Desai, M. Michel, C. Biswas, R. Hossain, J. Catalan, and A. B. Kaul, “Ink-jet printing of liquid-exfoliated,

highly conducting graphene:PEDOT PSS films for Organic Electronics,” abstract 1772 accepted, to appear

in Proc. of the American Vacuum Society (AVS) 63rd International Symposium and Exhibition, Nashville TN,

Nov. 2016.

7. A. B. Kaul, “Chemically and mechanically exfoliated MoS2 for electronic and opto-electronic devices,”

invited paper, Proc. of the IEEE Lester Eastman Conference, pp. 4-7, August 2016.

8. G. A. Saenz, G. Karapetrov, J. Curtis, and A. B. Kaul, “MoS2 Synthesis and high-performance broadband

photodetector,” Proc. of the IEEE Lester Eastman Conference, pp. 50-54, August 2016.

9. R. F. Hossain, I. G. Deaguero, T. Boland, and A. B. Kaul, “Solution dispersed 2D graphene and MoS2 for an

ink-jet printed biocompatible photodetector,” Proc. of the IEEE Lester Eastman Conference, pp. 19-22,

August 2016.

10. M. Michel, C. Biswas, J. A. Desai, A. Delgado, and A. B. Kaul, “ Optimization of fluid characteristics of 2D

materials for inkjet printing,” MRS Advances, vol. 1, issue 30, pp. 2199-2206, June 2016.

11. A. Delgado, J. A. Catalan, H. Yamaguchi, C. N. Villarrubia, A. Mohite, and A. B. Kaul, “Characterization of

2D MoS2 and WS2 dispersed in organic solvents for composites applications,” to appear in Proc. of the

Materials Research Society Spring Meeting, Phoenix, AZ, August 2016.

12. D. Fadil, R. F. Hossain, and A. B. Kaul, “Electronic and optical property characterization of MoS2 two-

dimensional exfoliated nanomaterials,” MRS Advances (Proc. of the Materials Research Society Spring

Meeting), pp. 1-6, July 2016.

13. N. Dhasmana, D. Fadil, A. B. Kaul, and J. A. Thomas, “Investigation of nonlinear optical properties of

exfoliated MoS2 using photoacoustic Z-scan,” MRS Advances (Proc. of the Materials Research Society

Spring Meeting), pp. 1-7, June 2016.

14. G. L. Saenz, C. Biswas, H. Yamaguchi, C. N. Villarrubia, A. Mohite, and A. B. Kaul, “Effects of synthesis

parameters on CVD growth of Molybdenum Disulfide,” MRS Advances, vol. 1, issue 32, pp. 2291-2296,

July 2016.

15. C. Biswas, G. A. Saenz, D. Fadil, and A. B. Kaul, “Characterization of electronic properties of two-

dimensional refractory selenides and tellurides,” MRS Advances (Proc. of the Materials Research Society

Spring Meeting), pp. 1-6, July 2016.

16. A. B. Kaul, “Solution-based production of 2D-layered materials,” invited paper, MRS Advances, vol. 1,

issue 32, pp. 2267-2272, July 2016.

17. M. Michel, D. Fadil, G. E. Lara, M. Michel, A. Delgado, E. Escaraga, and A. B. Kaul, “2D Material

Characterization for Printed Electronics Applications,” Proc. IEEE Photonics Society 2015 Summer Topicals

(Topic on Functional Two-dimensional Materials (FTDM)), pp. 101-102, July 2015.

18. D. Fadil, G. E. Lara, M. Michel, A. Delgado, C. Gaytan, and A. B. Kaul, “Properties of 2D Layered Crystals:

MoS2, NbSe2 and Black Phosphorus,” Proc. IEEE Photonics Society 2015 Summer Topicals (Topic on

Functional Two-dimensional Materials (FTDM)), pp. 3-4, July 2015.

Page 21: CURRICULUM VITAE ANUPAMA BHAT KAUL EDUCATIONhb2504.utep.edu/vitas/akaul.pdf · Anupama B. Kaul, Mar. 2017 Page 5 of 33 NEEDS is designed to develop computation, simulation and educational

Anupama B. Kaul, Mar. 2017 Page 21 of 33

19. A. B. Kaul “Van der Waals solids: properties and device applications,” (keynote paper), Proc. SPIE (Micro-

and Nanotechnology Sensors, Systems and Applications Conference, Editors: T. George, M. Saif Islam,

and A. K. Dutta), to appear, June 2015.

20. A. B. Kaul and P. X.L.- Feng “Nano carbon 1D and 2D nanomechanical resonators and switches,” invited

paper, Proc. of the Materials Research Society Spring Meeting, Symposium on Silicon Carbide - Materials,

Processing and Devices, pp. 1693, April 2014.

21. A. B. Kaul, J. B. Coles, K. G. Megerian, M. Eastwood, R. O. Green, and P. R. Bandaru, “A bottom-up

engineered, broadband optical nanoabsorber for radiometry and energy harnessing applications,”

(invited paper), Proc. 13th IEEE Nano Conference, Beijing, China, August 2013.

22. A. B. Kaul, “Graphene and Two-Dimensional Layered Materials for Device Applications,” (invited paper),

Proc. 13th IEEE Nano Conference, pp. 1-4, Beijing, China, August 2013.

23. J. Lee, A. B. Kaul, and P. Feng, “Vertical carbon nanofiber arrays and nanomechanical resonators for

potential radiation sensing,” Proc. of IEEE Transducers Conference, pp. 1887-1890, Barcelona, Spain, June

2013.

24. A. B. Kaul, “Layered nanomaterials for nanoelectronics, photonics, sensing and related applications”

CMOS Emerging Technologies Research Symposium, (invited), in Conference Abstracts, Whistler, Canada,

July 2013.

25. A. B. Kaul, “Organic and Flexible Electronics: Opportunities, Challenges and Future Trends,” (invited

paper) Proc. Nanotech.’2013, Washington D.C, May 2013.

26. A. B. Kaul, “Carbon-based nanomaterials for nanoelectronics applications,” (invited), Proc. New Diamond

and Nanocarbon Conference (NDNC) 2013, Singapore, May 2013.

27. A. B. Kaul, “Graphene and the advent of other layered 2D materials for nanoelectronics, photonics and

related applications,” (invited paper), Mat. Res. Soc. Symp. Proc. (Symposium on Graphene and Related

Nanomaterials: Pushing The Frontiers), vol. 1549, 2013.

28. A. B. Kaul “New frontiers in energy-efficient nanoelectronic devices enabled by novel materials” (keynote

paper), Proc. SPIE (Micro- and Nanotechnology Sensors, Systems and Applications Conference, Editors: T.

George, M. Saif Islam, and A. K. Dutta), vol. 8725, June 2013.

29. A.B.Kaul, “Two-dimensional layered nanomaterials for nanoelectronics and nanophotonics, applications”

Workshop on Beyond Graphene: Advanced 2D Electronic and Optoelectronic Crystals and Devices for

Next Generation Applications,” Materials Research Institute, Penn State University, abstract for invited

presentation, March 2013.

30. A. B. Kaul, J. Coles, M. Eastwood, R. Green, and P. Bandaru “Broad-band, high-efficiency optical

absorbers derived from carbon nanomaterials,” (invited paper), Mat. Res. Soc. Symp. Proc. (Symposium

on Carbon Nanomaterials), vol. 1505, 2013.

31. A. B. Kaul, “Carbon nanofiber switches and sensors,” (invited paper), Proc. IEEE International Frequency

Control Symposium, pp. 1-4, June 2012.

32. J. Lee, P. Feng, and A. B. Kaul “Characterization of plasma synthesized vertical carbon nanofibers for

nanoelectronics applications),” Mat. Res. Soc. Symp. Proc. (Nanocarbon Materials & Devices), vol. 1451,

pp. 117-122, May 2012.

Page 22: CURRICULUM VITAE ANUPAMA BHAT KAUL EDUCATIONhb2504.utep.edu/vitas/akaul.pdf · Anupama B. Kaul, Mar. 2017 Page 5 of 33 NEEDS is designed to develop computation, simulation and educational

Anupama B. Kaul, Mar. 2017 Page 22 of 33

33. A. B. Kaul “Organic semiconductors and their application in energy harvesting” (keynote paper), Proc.

SPIE, vol. 8377 (SPIE Energy Harvesting and Storage: Materials, Devices and Applications III, Editors: N. K.

Dhar, P. S. Wijewarnasuriya, and A. K. Dutta), 2012.

34. A. B. Kaul “Nano-enabled green technologies for electronics and energy applications,” (invited paper),

Proc. Nanotech’12, vol. 3, pp. 716-719 (Chapter 10: Green electronics, chemistry and materials), 2012.

35. A. B. Kaul “Carbon nanomaterials for energy-efficient green electronics,” (invited paper), Proc. XXI

International Materials Research Congress (sponsored by MRS), (Nanostructured carbon materials for

MEMS/NEMS & nanoelectronics), vol. 1478, Jan. 2012.

36. A. B. Kaul, J. B. Coles, K. G. Megerian, R. O. Green, T. Pagano, P. R. Bandaru, and M. R. Dokmeci, “High-

efficiency optical absorbers derived from carbon nanostructures,” Proc. Nanotech’11, vol. 2 (Chapter 2:

Nanostructured Materials & Devices), June 2011.

37. A. B. Kaul, A. R. Khan, K. Megerian, L. Bagge, L. Epp and M. R. Dokmeci, “AC and DC Applications of

Three-dimensional nano-electro-mechanical-systems,” Proc. Nanotech’11, vol. 2 (Chapter 5: MEMS &

NEMS Fabrication, Devices and Applications), June 2011.

38. A. B. Kaul, K. G. Megerian, A. Khan, L. Bagge, L. Epp, J. Coles, M. Eastwood, R. Green and M. Foote

“Carbon-based nanodevices for electronic and optical applications,” Proc. Nanotech’10, (Electronics and

Microsystems - MEMS and NEMS: Devices and Applications), vol. 2, pp. 304-307, June 2010.

39. A. B. Kaul, A. Khan, L. Bagge, K. G. Megerian, L. Epp, A. T. Jennings and J. R. Greer “Carbon-based NEMS,”

(invited paper), Proc. SPIE, vol. 7679-22 (SPIE Micro- and Nanotechnology Sensors, Systems and

Applications Conference), May 2010.

40. L. Bagge and A. B. Kaul “Carbon nanofiber-based mechanical resonators” Proc. SPIE, vol. 7679-87 (SPIE

Micro- and Nanotechnology Sensors, Systems and Applications Conference), May 2010.

41. A. B. Kaul, P. Khan, A. T. Jennings, J. R. Greer, K. Megerian, and P. von Allmen, “Nanoelectromechanical

switching devices for 3D electronics,” Mat. Res. Soc. Symp. Proc., vol. 1186E (Nanoscale

Electromechanics, and Piezoresponse Force Microscopy of Inorganic, Macromolecular and Biological

Systems), April 2009.

42. A. B. Kaul, K. Megerian, P. von Allmen, Robert Kowalczyk, and R. L. Baron, “High throughput top-down

and bottom-up processes for forming single-nanotube based architectures for 3D electronics,” Mat. Res.

Soc. Symp. Proc., vol. 1179E (Material Systems and Processes for Three-Dimensional Micro- and

Nanoscale Fabrication and Lithography), April 2009.

43. T. Vo, P. von Allmen, and A. B. Kaul, “Parallel polarizability of metallic carbon nanotubes,” Mat. Res. Soc.

Symp. Proc., vol. 1177E (Computational Nanoscience: How to Exploit Synergy Between Predictive

Simulations and Experiment), April 2009.

44. P. von Allmen, T. Vo, K. Megerian, R. L. Baron and A. B. Kaul, “Switching voltage in a carbon nanotube

memory device,” Mat. Res. Soc. Symp. Proc., vol. 1186E (Nanoscale Electromechanics, and Piezoresponse

Force Microscopy of Inorganic, Macromolecular and Biological Systems), April 2009.

45. A. B. Kaul, K. G. Megerian, R. L. Baron, A. T. Jennings, D. Jang, and J. R. Greer “High-throughput processes

and structural characterization of single-nanotube based devices for 3D electronics,” Proc. SPIE, vol.

7318, (Micro-and Nano-technology Sensors, Systems and Applications), April 2009.

Page 23: CURRICULUM VITAE ANUPAMA BHAT KAUL EDUCATIONhb2504.utep.edu/vitas/akaul.pdf · Anupama B. Kaul, Mar. 2017 Page 5 of 33 NEEDS is designed to develop computation, simulation and educational

Anupama B. Kaul, Mar. 2017 Page 23 of 33

46. H.M. Manohara, R. Toda, R.H. Lin, A. Liao, R. Kowalczyk, A. B. Kaul, M. M. Mojarradi, and J. Hong,

“Vacuum microelectronics applications using carbon nanotube cathodes” Proc. of the 33rd International

Conf. on Infrared, Millimeter and Terahertz Waves, IRMMW-THz 2008., pp. 1-2, Sep. 2008.

47. A. B. Kaul and H. M. Manohara, “Low power, wide dynamic range carbon nanotube vacuum gauges,”

Proc. of the 21st IEEE International Conference on Micro Electro Mechanical Systems (MEMS), pp. 156 –

160, Jan. 2008.

48. A. B. Kaul and H. Manohara, “Low power, wide dynamic range carbon nanotube pressure sensors,”

Government Micro-Circuit Appl. and Critical Tech. Conf. Proc., GOMACTech’08, Mar. 2008.

49. H.M. Manohara, M. J. Bronikowski, R. Toda, A. B. Kaul, M. Mojarradi, and J. Hong, “Vacuum

microelectronics and miniature instruments based on application-specific electrode-integrated nanotube

cathodes (ASINCs)” Government Micro-Circuit Appl. and Critical Tech. Conf. Proc., GOMACTech’08, Mar.

2008.

50. A. B. Kaul and H. M. Manohara, “Carbon nanotube vacuum gauges utilizing long, dissipative tubes,” Proc.

SPIE, vol. 6959 (Micro (MEMS) and Nanotechnologies for Space, Defense and Securities III), pp. 69590F-1-

8, Mar. 2008.

51. A. B. Kaul, L. Epp, E. Wong and R. Kowalczyk “Carbon nanotube switches for communication and memory

applications,” Proc. SPIE, vol. 6959 (Micro (MEMS) and Nanotechnologies for Space, Defense and

Securities III), pp. 695909-1-8, Mar. 2008.

52. A. B. Kaul, R. Kowalczyk, K. Megerian, P. von Allmen and R. Baron “Vertically aligned carbon nanotubes

formed using PECVD for switching applications in extreme environment space electronics,” Mat. Res. Soc.

Symp. Proc., vol. 1081E (Carbon Nanotubes and Related Low Dimensional Materials), pp. 1081-P15-06,

Mar. 2008.

53. H.M. Manohara, M. J. Bronikowski, R. Toda, E. Urgiles, R. Lin, K. Yee, A. B. Kaul, and J. Hong, “Application

specific electrode-integrated nanotube cathodes (ASINCs) for miniature analytical instruments for space

exploration,” (invited paper), Proc. SPIE, vol. 6959 (Micro (MEMS) and Nanotechnologies for Space,

Defense and Securities III), pp. 695906-1-6, Mar. 2008.

54. A. B. Kaul, E. W. Wong, L. Epp, M. J. Bronikowski, and B. D. Hunt “Air-bridge and vertical carbon

nanotube switches for high performance switching applications,” Mat. Res. Soc. Symp. Proc., vol. 924E

(Mechanics of Nanoscale Materials and Devices), pp. 0924-Z06-04-09, Mar. 2006.

55. E. Wong, A. B. Kaul, L. Epp, B. Hunt, “Air-bridge and vertical carbon nanotube switches for high

performance switching applications,” Proc. of the 7th Inter. Conf. on the Sci. and Appl. of Nanotubes,

NT’06, pp. 191, June 2006.

56. H. Manohara, E. Wong, M. Bronikowski, A. B. Kaul. E. Schlecht, L. Epp, P. Siegel and B. Hunt, “Carbon

nanotube devices for high frequency electronic applications,” Proc. of the 6th Inter. Conf. on the Sci. and

Appl. of Nanotubes, NT’05, June 2005.

57. A. B. Kaul, T. Klosowiak, and J. Liu “A static technique for the electro-mechanical characterization of

MEMS devices for RF and microwave applications,” Mat. Res. Soc. Proc., vol. 729 (BioMEMS and

Bionanotechnology), pp. 107-112, MRS San Francisco, 2002.

58. A. Bhat, X. Meng, A. Wong, and T. Van Duzer, Extended Abstracts of the 7th International Supercond.

Electronics Conf., ISEC'99, Berkeley, CA, pp. 515-517, June 1999.

59. X. Meng, A. Bhat, L. Zheng, A. Wong, and T. Van Duzer, Extended Abstracts of the 7th International

Supercond. Electronics Conf., ISEC'99, Berkeley, CA, pp. 235-237, June 1999.

Page 24: CURRICULUM VITAE ANUPAMA BHAT KAUL EDUCATIONhb2504.utep.edu/vitas/akaul.pdf · Anupama B. Kaul, Mar. 2017 Page 5 of 33 NEEDS is designed to develop computation, simulation and educational

Anupama B. Kaul, Mar. 2017 Page 24 of 33

60. X. Meng, H. Jiang, A. Bhat, and T. Van Duzer, “Precise control of critical current and resistance in a

Nb/AlOx/Nb integrated circuit process,” Extended Abstracts of the 6th International Supercond.

Electronics Conf., ISEC'97, Berlin, Germany, June 1997.

KEYNOTE, INVITED TALKS & OTHER PRESENTATIONS

1. INVITED: A. B. Kaul, “Top-down and bottom-up synthesis of 2D transition metal sulphides and

selenides and their device applications,” Graphene EU-US Workshop on 2D Materials, Heterostructures

and Devices, National Graphene Institute, University of Manchester, Manchester, U.K., Oct. 2016.

2. INVITED: A. B. Kaul, “Chemically and mechanically exfoliated MoS2 for electronic and opto-electronic

devices,” IEEE Lester Eastman Conference, Lehigh University, Lehigh, PA, August 2016.

3. INVITED: A. B. Kaul, “Black phosphorus, graphene and 2D binary transition metal dichalcogenides for

device applications” CIMTEC - 5th International Conference on “Smart and Multifunctional Materials,

Structures, and Systems,” Perugia, Italy, June 2016.

4. INVITED: A. B. Kaul, “Advanced Materials Research in the Nanomaterials and Devices Laboratory,

UTEP,” University of Milan, Milan, Italy, June 2016.

5. INVITED: A. B. Kaul, “Solution and vapor-based synthesis of 2D layered materials for nanodevice

applications,” 2D Materials Science-Industry Workshop, NanoMat, EMPA, Dubendorf, Switzerland,

March 2016.

6. INVITED: A. B. Kaul, “Synthesis and characterization of layered materials for nanodevices” Materials

Research Society Spring Meeting, Phoenix, AZ, April 2016.

7. A. S. Bandyopadhyay, G. A. Saenz, C. Biswas, and A. B. Kaul, “Synthesis and characterization of two-

dimensional WSe2 grown using chemical vapor deposition,” oral presentation, The American Vacuum

Society (AVS) 63rd International Symposium and Exhibition, Nashville TN, Nov. 2016.

8. J. Catalan, A. Delgado, and A. B. Kaul, “Two-dimensional layered materials for composites applications,”

oral presentation, Proc. of the American Vacuum Society (AVS) 63rd International Symposium and

Exhibition, Nashville TN, Nov. 2016.

9. S. Chugh, C. Biswas, A. S. Bandyopadhyay, G. A. Saenz, L. Echegoyen, and A. B. Kaul, “Electronic

transport properties of hybrid graphene-C60 structures,” poster presentation, The American Vacuum

Society (AVS) 63rd International Symposium and Exhibition, Nashville TN, Nov. 2016.

10. J. Desai, M. Michel, C. Biswas, R. Hossain, J. Catalan, and A. B. Kaul, “Ink-jet printing of liquid-exfoliated,

highly conducting graphene:PEDOT PSS films for organic electronics,” poster presentation, The

American Vacuum Society (AVS) 63rd International Symposium and Exhibition, Nashville TN, Nov. 2016.

11. G. A. Saenz, G. Karapetrov, J. Curtis, and A. B. Kaul, “MoS2 Synthesis and high-performance broadband

photodetector,” poster presentation, The IEEE Lester Eastman Conference, Lehigh University, Lehigh,

PA, August 2016.

12. R. F. Hossain, I. G. Deaguero, T. Boland, and A. B. Kaul, “Solution dispersed 2D graphene and MoS2 for

an ink-jet printed biocompatible photodetector,” oral presentation, The IEEE Lester Eastman

Conference, Lehigh University, Lehigh, PA, August 2016.

Page 25: CURRICULUM VITAE ANUPAMA BHAT KAUL EDUCATIONhb2504.utep.edu/vitas/akaul.pdf · Anupama B. Kaul, Mar. 2017 Page 5 of 33 NEEDS is designed to develop computation, simulation and educational

Anupama B. Kaul, Mar. 2017 Page 25 of 33

13. M. Michel, J. A. Desai, C. Biswas, A. Delgado, and A. B. Kaul, “Solution based processing of 2D materials

for ink jet printing,” poster presentation, MRS Society Spring Meeting, Phoenix, AZ, March 2016.

14. C. Biswas, G. Lara, D. Fadil, and A. B. Kaul, “Electrical characterization of 2D refractory nitrides and

sulphides,” poster presentation, MRS Society Spring Meeting, Phoenix, AZ, March 2016.

15. G. Lara, C. Biswas, H. Yamaguchi, A. D. Mohite and A. B. Kaul, “Chemical vapor deposition of MoS2 and

characterizing its properties using Raman Spectroscopy,” poster presentation, MRS Society Spring

Meeting, Phoenix, AZ, March 2016.

16. A. Delgado, J. Catalan and A. B. Kaul, “2D composites for sensing applications,” poster presentation,

MRS Society Spring Meeting, Phoenix, AZ, March 2016.

17. D. Fadil, R. Hossain, and A. B. Kaul, “Excitonic and hot luminescence effects in 2D WS2 and MoS2,” oral

presentation, MRS Society Spring Meeting, Phoenix, AZ, March 2016.

18. D. Fadil, G. E. Lara, M. Michel, A. Delgado, C. Gaytan, and A. B. Kaul, “Properties of 2D Layered Crystals:

MoS2, NbSe2 and Black Phosphorus,” Oral presentation by D. Fadil, IEEE Photonics Society 2015

Summer Topicals (Topic on Functional Two-dimensional Materials (FTDM)), Nassau, Bahamas, July

2015.

19. M. Michel, D. Fadil, G. E. Lara, M. Michel, A. Delgado, E. Escaraga, and A. B. Kaul, “2D Material

Characterization for Printed Electronics Applications,” poster presentation by D. Fadil, IEEE Photonics

Society 2015 Summer Topicals (Topic on Functional Two-dimensional Materials (FTDM)), Nassau,

Bahamas, July 2015.

20. INVITED: A. B. Kaul, “Overview of 2D layered Materials,” NSF US EU Workshop on 2D Layered Materials

and Devices, Arlington, VA, April 2015.

21. M. Michel, D. Fadil, G. E. Lara, A. Delgado, C. Gaytan, E. Escaraga, and A. B. Kaul, “Material

characterization of 2D layered crystals for printed electronics applications,” poster presentation, NSF

US EU Workshop on 2D Layered Materials and Devices, Arlington, VA, April 2015.

22. KEYNOTE: A. B. Kaul, “Van der Waals solids: materials properties, synthesis and device applications,”

SPIE’s Micro- and Nanotechnology Sensors, Systems and Applications Conference, Baltimore, MD, April

2015.

23. INVITED: A. B. Kaul, “2D Beyond Graphene Materials: Synthesis, Characterization and Device

Applications,” CMOS Emerging Technologies Research Symposium, Vancouver BC, Canada, May 2015.

24. INVITED: A. B. Kaul, “Layered nanomaterials: unveiling electronic, photonic & mechanical properties

for emergent applications,” Mat. Res. Soc. Symposium on Emerging Non-Graphene 2D Atomic Layers

and van der Waals Solids, MRS Fall 2014 Meeting, Boston, MA, Dec. 2014.

25. INVITED: A. B. Kaul, “2D Materials as Modular Building Blocks for 3D Architectures,” WTEC-NSF

Workshop on Nanomodular Materials, Devices and Systems, Arlington, VA, Oct. 2014.

26. INVITED: J. Hwang, et al., A. B. Kaul, “2D Materials and Device beyond Graphene,” Lester Eastman

Conference, Ithaca, NY, August 2014.

27. INVITED: A. B. Kaul, “Graphene – A stepping-stone to other emerging atomic-layered materials,” New

Diamond and Nanocarbon Conference, Chicago, IL, May 2014.

28. INVITED: A. B. Kaul, “2D Atomic-layered Materials: Progress and Prospects,” The Tenth International

Nanotechnology Conference on Communication and Cooperation, Gaithersburg, Maryland, May 2014.

Page 26: CURRICULUM VITAE ANUPAMA BHAT KAUL EDUCATIONhb2504.utep.edu/vitas/akaul.pdf · Anupama B. Kaul, Mar. 2017 Page 5 of 33 NEEDS is designed to develop computation, simulation and educational

Anupama B. Kaul, Mar. 2017 Page 26 of 33

29. INVITED: A. B. Kaul, “2D atomic-layered Materials and their Applications,” Graphene 2014 Conference,

Toulouse, France, May 2014.

30. INVITED: A. B. Kaul, “Nanomaterials and nanodevices,” ETH Zurich, Zurich, Switzerland, May 2014.

31. INVITED: A. B. Kaul, “Properties and applications of nanocarbons and related materials,” Indian

Institute of Technology-Delhi (IIT-Delhi), Delhi, India, May 2014.

32. INVITED: A. B. Kaul, “Nano carbon 1D and 2D nanomechanical resonators and switches,” Mat. Res. Soc.

Symposium on Silicon Carbide - Materials, Processing and Devices, MRS Spring 2014 Meeting, San

Francisco, CA, April 2014.

33. KEYNOTE: A. B. Kaul, “2-Dimensional Atomic-layer Research and Engineering - 2-DARE Beyond

Graphene,” SPIE’s Micro- and Nanotechnology Sensors, Systems and Applications Conference,

Baltimore, MD, April 2014.

34. KEYNOTE: A. B. Kaul, “Current progress in 2D-layered materials for nanoelectronics, flexible electronics

and related applications,” The Minerals, Metals and Materials Society (TMS) Annual Meeting, San

Diego, CA, Feb. 2014.

35. INVITED: A. B. Kaul, “The Electronics, Photonics and Magnetic Devices (EPMD) Program in the

Engineering Directorate at NSF and Recently Launched Initiatives,” Conference on Electronic Devices,

Materials and Systems for a Sustainable Future, King Abdullah University of Science and Technology

(KAUST), Saudi Arabia, Feb. 2014.

36. INVITED-Panelist: A. B. Kaul, “Graphene-like layered materials for device applications,” The

International Semiconductor Device Research Conference (ISDRC), Bethesda, MD, Dec. 2013.

37. INVITED: A. B. Kaul, “Revisiting Layered Materials In The Nano-age: The promise of transition metal di-

chalcogenides and other 2D-layered materials for nanoelectronics, sensing and photonics applications”

IEEE Electron Devices Society (EDS) and Solid State Circuits Societies Chapter of Baltimore, Colloquium

on Sensor Devices, University of Maryland, College Park, MD, Sep. 2013.

38. INVITED: A. B. Kaul, “Graphene-like 2D-layered materials for nanoelectronics and sensing applications,”

IEEE Nano Conference, Beijing, China, August 2013.

39. INVITED: A. B. Kaul, “A bottom-up engineered, broadband optical nanoabsorber for radiometry and

energy harnessing applications,” IEEE Nano Conference, Beijing, China, August 2013.

40. INVITED: A. B. Kaul, “Layered nanomaterials for nanoelectronics, photonics, sensing and related

applications” CMOS Emerging Technologies Research Symposium, Whistler, Canada, July 2013.

41. INVITED: A. B. Kaul, “Women in STEM” IEEE Women in Engineering (WIE) Meeting, held in conjunction

with the IEEE International Symposium on Antennas and Propagation, Orlando, FL, July 2013.

42. INVITED/KEYNOTE: A. B. Kaul, “Organic and Flexible Electronics: Opportunities, Challenges and Future

Trends,” Nanotech Conference & Expo, NSTI, Washington D.C., May 2013.

43. INVITED: A. B. Kaul, “Carbon-based nanomaterials including 2D-layered materials for nanoelectronics &

related applications,” New Diamond and Nanocarbon Conference (NDNC) 2013, Singapore, May 2013.

44. KEYNOTE: A. B. Kaul, “New frontiers in NEMS and energy-efficient nanoelectronic devices enabled by

2D layered and other low-dimensionality nanomaterials,” SPIE’s Micro- and Nanotechnology Sensors,

Systems and Applications Conference, Baltimore, MD, April 2013.

Page 27: CURRICULUM VITAE ANUPAMA BHAT KAUL EDUCATIONhb2504.utep.edu/vitas/akaul.pdf · Anupama B. Kaul, Mar. 2017 Page 5 of 33 NEEDS is designed to develop computation, simulation and educational

Anupama B. Kaul, Mar. 2017 Page 27 of 33

45. INVITED: A. B. Kaul, “2D Materials and Devices beyond Graphene,” Mat. Res. Soc. Symposium on

Graphene and Related Nanomaterials: Pushing the Frontiers, MRS Spring 2013 Meeting, San Francisco,

CA, April 2013.

46. INVITED: A. B. Kaul, “The promise of transition metal di-chalcogenides and other 2D-layered materials

for nanoelectronics, energy harvesting, sensing and photonics applications” Workshop on

Nanotechnology, George Washington University, Nano@GW, March 2013.

47. INVITED: A. B. Kaul, “Two-dimensional layered nanomaterials for nanoelectronics and nanophotonics,

applications” Workshop on Beyond Graphene: Advanced 2D Electronic and Optoelectronic Crystals and

Devices for Next Generation Applications,” Materials Research Institute, Penn State University, March

2013.

48. INVITED: A. B. Kaul, “Nanoengineered Materials Spur The Engines of Innovation in Nanoelectronics and

Organic Electronics,” 2012 Invited Speaker Series, IEEE Sensors Council, IEEE Washington D.C. /

Northern Virginia Sensors Council Chapter Meeting, Arlington, VA, Dec. 2012.

49. INVITED: A. B. Kaul, “Device applications of nanomaterials for nanoelectronics and organic

electronics,” Georgia Institute of Technology, Georgia Tech., Fall 2012.

50. INVITED: A. B. Kaul, “Low-dimensionality nanomaterials for electronic device applications,” National

Institute of Standards and Techniques (NIST), Gaithersburg, Maryland, Nov. 2012.

51. INVITED: A. B. Kaul, “Carbon-based nanomaterials and their role in nanoelectronics and related

applications,” Washington State University, Fall 2012.

52. INVITED: A. B. Kaul, “Optical absorbers derived from carbon nanostructures,” Mat. Res. Soc.

Symposium on Carbon Nanomaterials, MRS Fall 2012 Meeting, Boston, MA, Nov. 2012.

53. INVITED: A. B. Kaul, “Nanoelectronics and Organic Electronics: Materials, Devices and Applications,”

Portland State University, Fall 2012.

54. INVITED: A. B. Kaul, “Nanomaterials and nanomanufacturing for enabling advances in

nanoelectronics,” Washington State University, Fall 2012.

55. INVITED: A. B. Kaul, “Nanomaterials and devices for nanoelectronics and organic electronics

applications,” North Carolina State University, Fall 2012.

56. INVITED: A. B. Kaul, “Nanoengineered materials for electronic device applications,” University of

Houston, Fall 2012.

57. INVITED: A. B. Kaul, “Low-dimensionality nanomaterials for electronic device applications,”

Microelectronics Distinguished Lecture, University of Texas-Austin, Fall 2012.

58. INVITED: A. B. Kaul, “Nanoengineered materials for electronics and optical device applications,” Texas

A&M University, Fall 2012.

59. INVITED – Panelist: A. B. Kaul, “Opportunities and Challenges in realizing low-cost, high efficiency

organic solar cells,” in “Paths to Reliable, Efficient, low-cost solar cells,” IEEE Electron Devices Society

(EDS) and Solid State Circuits Societies Chapter of Baltimore, Colloquium on Energy Harvesting Devices,

University of Maryland, College Park, MD, Sep. 2012.

60. INVITED: A. B. Kaul “Carbon-based nanomaterials for nanoelectronics and NEMS,” XXI International

Materials Research Congress (sponsored by MRS), (Nanostructured carbon materials for MEMS/NEMS

and Nanoelectronics), Cancun, Mexico, August 2012.

Page 28: CURRICULUM VITAE ANUPAMA BHAT KAUL EDUCATIONhb2504.utep.edu/vitas/akaul.pdf · Anupama B. Kaul, Mar. 2017 Page 5 of 33 NEEDS is designed to develop computation, simulation and educational

Anupama B. Kaul, Mar. 2017 Page 28 of 33

61. INVITED: A. B. Kaul “Carbon-based Sensors and Resonators,” 2012 IEEE International Frequency

Control Symposium, Baltimore MD, June 2012.

62. INVITED: A. B. Kaul “Electronic Device applications of nanomaterials overview in the Engineering

directorate at the National Science Foundation,” Air Force Office of Scientific Research – Australia

Partnerships, Washington D. C., May 2012.

63. KEYNOTE: A. B. Kaul, “Organic Semiconductors for Energy Harvesting,” SPIE Energy Harvesting and

Storage: Materials, Devices and Applications III, Baltimore, MD, April 2012.

64. INVITED: A. B. Kaul “Nano-enabled Green Technologies for Electronics & Energy Applications,”

Nanotech Conference & Expo, NSTI, Santa Clara, CA, June 2012.

65. INVITED: A. B. Kaul, “Carbon-based nanomaterials and their applications,” Research Triangle Institute,

Raileigh, NC, 2011.

66. INVITED: A. B. Kaul, “Nanoengineered materials for nanoelectronics applications,” Oklahoma State

University, OK, Fall 2010.

67. INVITED: A. B. Kaul, “Electronic and optical applications of low-dimensional nanomaterials,” University

of Waterloo, Canada, Fall 2011.

68. INVITED: A. B. Kaul, “Electronic applications of carbon-based nanomaterials,” Indian Institute of

Sciences, Bangalore, India, Spring 2011.

69. A. B. Kaul, J. B. Coles, K. Megerian, M. Eastwood, M. Anderson, R. O. Green, M. Foote, and T. Pagano,

“Nanostructured carbon-based optical absorbers as blackbody calibration targets for NASA’s

spectrometers,” JPL Annual Research and Technology Development Poster Session, poster #SC-25, Nov.

2010.

70. K. A. Son, A. Liao, and A. B. Kaul, “High voltage GaN power switching electronics,” JPL Annual Research

and Technology Development Poster Session, poster #SC-18, Nov. 2010.

71. A. B. Kaul, K. G. Megerian, A. Khan, L. Bagge, L. Epp, J. Coles, M. Eastwood, R. Green and M. Foote,

“Nanoelectronic and optical applications of carbon-based nano-materials,” oral presentation,

Nanotech’10 (Electronics and Microsystems Track: MEMS and NEMS: Devices and Applications),

Anaheim, CA, June 2010.

72. INVITED: A.B. Kaul, “Carbon-based nanoelectronics for space applications,” IEEE Electron Devices

Society (EDS), Microwave Theory and Techniques (MTT) joint chapter meeting, Irvine, CA, April 2010.

73. INVITED: A. B. Kaul, “Carbon-based NEMS,” oral presentation, SPIE Micro- and Nanotechnology

Sensors, Systems and Applications Conference, Orlando, FL, April 2010.

74. L. Bagge and A. B. Kaul “Carbon nanofiber-based mechanical resonators” poster presentation, SPIE

Micro- and Nanotechnology Sensors, Systems and Applications Conference, Orlando, FL, April 2010.

75. A. B. Kaul, K. Megerian, P. von Allmen, R. Kowalczyk, and R. Baron “Carbon nanotube switches for

extreme environment electronics,” JPL Annual Research and Technology Development Poster Session,

poster #09-T-119, Nov. 2009.

76. A. B. Kaul, P. von Allmen, K. Megerian, R. L. Baron, A. Khan, A. Jennings, and J. R. Greer

“Nanoelectromechanical switching devices for 3D electronics,” oral presentation, Nanoscale

Electromechanics, and Piezoresponse Force Microscopy of Inorganic, Macromolecular and Biological

Systems Symposium, Materials Research Society Spring Meeting, San Francisco, CA, April 2009.

Page 29: CURRICULUM VITAE ANUPAMA BHAT KAUL EDUCATIONhb2504.utep.edu/vitas/akaul.pdf · Anupama B. Kaul, Mar. 2017 Page 5 of 33 NEEDS is designed to develop computation, simulation and educational

Anupama B. Kaul, Mar. 2017 Page 29 of 33

77. A. B. Kaul, P. von Allmen, K. Megerian, and R. L. Baron, “Aligned carbon nanotubes in 3D nanoscale

architectures for electronics applications formed using high throughput processes,” poster

presentation, Material Systems and Processes for Three-Dimensional Micro- and Nanoscale Fabrication

and Lithography Symposium, Materials Research Society Spring Meeting, San Francisco, CA, April 2009.

78. T. Vo, P. von Allmen, and A. B. Kaul, “Parallel polarizability of metallic carbon nanotubes,” poster

presentation, Materials Research Society Spring Meeting, San Francisco, CA, April 2009.

79. P. von Allmen, T. Vo, K. Megerian, R. L. Baron and A. B. Kaul, “Switching voltage in a carbon nanotube

memory device,” oral presentation, Nanoscale Electromechanics, and Piezoresponse Force Microscopy

of Inorganic, Macromolecular and Biological Systems Symposium, Materials Research Society Spring

Meeting, San Francisco, CA, April 2009.

80. A. B. Kaul, P. von Allmen, K. Megerian, and R. L. Baron, “Single, vertically aligned carbon nanotubes in

3D nanoscale architectures enabled by manufacturable processes,” oral presentation, SPIE Micro-and

Nano-technology Sensors, Systems and Applications Conference, Orlando, FL, April 2009.

81. A. B. Kaul, K. Megerian, P. von Allmen, R. Kowalczyk, and R. Baron “Carbon nanotube switches for

extreme environment electronics,” JPL Annual Research and Technology Development Poster Session,

poster #08-T-042, Nov. 2008.

82. ORAL (PODIUM): A. B. Kaul “Low power, wide-dynamic range carbon nanotube vacuum gauges,” The

21st IEEE International Conference on Micro-Electro-Mechanical Systems (MEMS), Tucson, AZ, Jan.

2008.

83. A. B. Kaul and H. Manohara “Carbon nanotubes vacuum gauges,” oral presentation, SPIE Micro

(MEMS) and Nanotechnologies for Space, Defense and Securities III Conference, Orlando, FL, Mar.

2008.

84. A. B. Kaul, L. Epp, E. Wong and R. Kowalczyk, “Carbon nanotube switches for communication and

memory applications,” oral presentation, SPIE Micro (MEMS) and Nanotechnologies for Space, Defense

and Securities III Conference, Orlando, FL, Mar. 2008.

85. A. B. Kaul, R. Kowalczyk, P. von Allmen, K. Megerian, R. Baron and E. Wong, “Vertically aligned PECVD

grown carbon nanotubes as switching elements in extreme environment space electronics,” poster

presentation, Carbon and Related Low Dimensional Materials Symposium, Materials Research Society

Spring Meeting, San Francisco, CA, Mar. 2008.

86. H. Manohara and A. B. Kaul “High-sensitivity, broad range vacuum gauges using nanotubes,” JPL Lew

Allen Award, Annual Research and Technology Development Poster Session, poster #07-l-040, Nov.

2007.

87. A. B. Kaul and H. Manohara, “Low power, wide dynamic range carbon nanotube pressure sensors,”

oral presentation, Government Micro-Circuit Applications and Critical Technology Conference,

GOMACTech’08, Las Vegas, NV, Mar. 2008 (presenter M. Mojarradi).

88. H. M. Manohara, M. J. Bronikowski, R. Toda, K. Y. Yee, A. B. Kaul, M. M. Mojarradi, J. Hong, “Vacuum

Microelectronics and Miniature Instruments Based on Application Specific electrode-integrated

nanotube cathodes (ASINCS),” Government Micro-Circuit Applications and Critical Technology

Conference, GOMACTech’08, Las Vegas, NV, Mar. 2008.

Page 30: CURRICULUM VITAE ANUPAMA BHAT KAUL EDUCATIONhb2504.utep.edu/vitas/akaul.pdf · Anupama B. Kaul, Mar. 2017 Page 5 of 33 NEEDS is designed to develop computation, simulation and educational

Anupama B. Kaul, Mar. 2017 Page 30 of 33

89. INVITED: H. M. Manohara, M. J. Bronikowski, R. Toda, K. Y. Yee, A. B. Kaul, M. M. Mojarradi, J. Hong,

“Application specific electrode-integrated nanotube cathodes (ASINCs) for miniature analytical

instruments for space exploration,” SPIE Micro (MEMS) and Nanotechnologies for Space, Defense, and

Securities III Conference, Orlando, FL, Mar. 2008; (presenter H. Manohara).

90. H. M. Manohara, M. J. Bronikowski, R. H. Lin, R. Toda, E. Luong, A. B. Kaul, B. D. Hunt, P. H. Siegel, and

J. Hong, “High performance cold cathodes for RF-to-THz Applications,” poster presentation,

Microsystems Technology Office (MTO) Symposium, Defense Advanced Research Program Agency

(DARPA), San Jose, CA, Mar. 2007.

91. H. M. Manohara, M. J. Bronikowski, P. H. Siegel, R. H. Lin, R. Toda, E. Luong, B. D. Hunt, R. Kowalczyk, A.

B. Kaul, E. Urgiles, and J. Wilcox, “THz Vacuum Device for Space: nanoklystron and components,”

advisory group on electron devices, Special Technology Review on compact THz sources, ONR/AFOSR

Headquarters, Mar. 2007.

92. INVITED: A. B. Kaul, “Carbon nanotubes for high performance switching applications,” Berkeley Sensor

and Actuator Center (BSAC) Seminar Series, Department of Electrical Engineering, UC Berkeley,

Berkeley, CA, Oct. 2006.

93. H. Manohara, M. J. Bronikowski, R. Lin, A. B. Kaul, G. Chattopadyay, et al. “Carbon nanotube cathodes”

DARPA Seedling Review, Arlington, VA, Sep., 2006.

94. H. Manohara, M. J. Bronikowski, E. W. Wong, A. B. Kaul, R. Toda, J. Wilcox, E. Urgiles et al. “Nanotubes

for instruments,” JPL Research and Technology Poster Presentation, Sep. 2006.

95. A. B. Kaul, A. W. Kleinsasser, B. Bumble, H. G. LeDuc, and K. A. Lee, “Ion beam nitridation of Aluminium

for tunnel barrier applications,” poster presentation, Applied Superconductivity Conference, Seattle,

WA, Aug. 2006.

96. E. Wong, A. B. Kaul, L. Epp, B. Hunt, “Air-bridge and vertical carbon nanotube switches for high

performance switching applications,” poster presentation, NT’06, 7th International Conference on the

Science and Applications of Nanotubes, Nagano, Japan, Jun. 2006.

97. A. B. Kaul, E. W. Wong, L. Epp, M. J. Bronikowski, and B. D. Hunt “Air-bridge and vertical carbon

nanotube switches for high performance switching applications,” oral presentation, Mechanics of

Nanoscale Materials and Devices Symposium, Materials Research Society Spring Meeting, San

Francisco, CA, Apr. 2006.

98. INVITED: A. B. Kaul, “A nanotube switch with potential applications in high data rate, low power

satellite communication systems” National Reconnaissance Office Headquarters, Chantilly, VA, Feb.

2006.

99. M. Foote, J. Blacksberg, A. B. Kaul, and M. J. Kenyon, “Single crystal bolometric materials for high

performance thermal infrared planetary instruments” JPL Annual Research and Technology

Development Poster Session, Poster #05-133, Sep. 2005.

100. B. Hunt, E. Wong, M. Bronikowski, A. B. Kaul. E. Schlecht, L. Epp, P. Siegel and H. Manohara, “Carbon

nanotube devices for high frequency electronic applications,” poster presentation, 6th International

Conference on the Science and Applications of Nanotubes, NT’05, Gothenburg, Sweden, Jun. 2005.

101. A. B. Kaul, B. Bumble, K. Lee, H. LeDuc, F. Rice, and J. Zmuidzinas, “Fabrication of wide-IF 200 – 300

GHz SIS mixers with suspended metal beam leads formed on SOI” oral presentation at AVS 51st

International Symposium, MEMS and NEMS Session, Anaheim, Nov. 2004.

Page 31: CURRICULUM VITAE ANUPAMA BHAT KAUL EDUCATIONhb2504.utep.edu/vitas/akaul.pdf · Anupama B. Kaul, Mar. 2017 Page 5 of 33 NEEDS is designed to develop computation, simulation and educational

Anupama B. Kaul, Mar. 2017 Page 31 of 33

102. K. A. Lee, R. LeDuc, P. Siegel, P. Stek, J. Waters, A. B. Kaul, B. Bumble, G. Chattopadhyay, J. Ward, F.

Rice, E. Schlecht, R. Dengler and D. Dawson, “Superconducting cooled heterodyne receivers,” JPL

Annual Research and Technology Development Poster Session, Poster #04-111, Sep. 2003, and 2004.

103. A. B. Kaul, RF MEMS device characterization quarterly progress reviews over 7 quarters (2000-2002).

Oral presentations made to Air Force Research Labs and DARPA program managers in Schaumburg, IL

and Rolla, Missouri, for DARPA-sponsored RF MEMS program at Motorola Labs (F33615-00-2-1718).

104. A. B. Kaul, T. Klosowiak and J. Liu, “A static technique for the electro-mechanical characterization of

MEMS devices for RF and microwave applications” poster presentation, BioMEMS and Bio-nanoMEMS

Session, Materials Research Society Spring Meeting, San Francisco, CA, Apr. 2002.

105. INVITED: A. B. Kaul, et al. “Electrical characterization of meso-MEMS RF switches fabricated in an HDI

PWB process,” Motorola Labs Tech. Conf., Schaumburg, IL, Sep. 2002.

106. M. Eliacin, K. Lian, and A. B. Kaul “Fabrication of RF MEMS switches in a PWB HDI process,” Level 0

Netference, Schaumburg, IL, Apr. 2002.

107. INVITED: A. B. Kaul, “Josephson junctions for high-speed electronic applications,” Center for Quantum

Devices, Dept. of Electrical Engineering, Northwestern University, Evanston, IL, Mar. 2000.

108. A. Bhat, X. Meng, A. Wong, and T. Van Duzer, "Superconducting NbN films grown using pulsed laser

deposition for potential application in internally shunted Josephson junctions," poster presentation,

The 7th International Superconductive Electronics Conference, ISEC'99, Berkeley, CA, Jun. 1999.

109. INVITED: A. B. Kaul, “Josephson junctions for high-speed electronic applications,” HP-Labs, Palo Alto,

CA, Dec. 1999.

110. X. Meng, A. Bhat, L. Zheng, A. Wong, and T. Van Duzer, "Submicron Nb/Al-AlOx/Nb tunnel Junctions

with high critical current densities," poster presentation, The 7th International Superconductive

Electronics Conference, ISEC'99, Berkeley, CA, Jun. 1999.

111. A. Bhat, X. Meng, S. Whiteley, M. Jeffery, and T. Van Duzer, "High current density Nb/Al-AlOx/Nb

Josephson junctions and their implementation in a high speed digital amplifier," poster presentation,

Applied Superconductivity Conference, Palm Desert, CA, Sep. 1998.

112. X. Meng, A. Bhat, and T. Van Duzer, "Very small critical current spreads in Nb/Al-AlOx/Nb integrated

circuits using low-temperature and low-stress ECR PECVD silicon oxide films," poster presentation,

Applied Superconductivity Conference, Palm Desert, CA, Sep. 1998.

113. X. Meng, A. Bhat, and T. Van Duzer, "UC Berkeley Nb Integrated Circuit Process Developments," poster

presentation, Workshop on Superconductive Electronics, Winter Park, Colorado, Sept. 1997;

Rosendale, New York, Oct. 1999.

114. X. Meng, H. Jiang, A. Bhat, and T. Van Duzer "Precise control of critical current and resistance in a

Nb/AlOx/Nb integrated circuit process," poster presentation, The 6th International Superconductive

Electronics Conference, ISEC'97, Berlin, Germany, Jun. 1997.

115. A. Bhat, "Accelerated materials testing," oral presentation, Writing Systems International Conference,

Hewlett-Packard Company, Bend, OR, 1995.

Page 32: CURRICULUM VITAE ANUPAMA BHAT KAUL EDUCATIONhb2504.utep.edu/vitas/akaul.pdf · Anupama B. Kaul, Mar. 2017 Page 5 of 33 NEEDS is designed to develop computation, simulation and educational

Anupama B. Kaul, Mar. 2017 Page 32 of 33

MAGAZINE ARTICLES & NASA TECH BRIEFS 1. A. B. Kaul, Topic related to nanotechnology (title TBD), invited, American Scientist (in preparation, to be

submitted).

2. A. B. Kaul, and J. B. Coles “Thermally resilient, bottom-up engineered broadband optical absorbers from

UV-to-IR derived from carbon-based nanomaterials,” NASA Tech. Briefs (in press); NASA New Technology

report (NTR#47876), Oct. 2010.

3. A. B. Kaul, L. Bagge, and L. Epp, “Carbon nanofiber based high frequency, high Q, miniaturized

mechanical resonators,” NASA Tech. Briefs (in press); NASA New Technology report (NTR#47238), Sep.

2009.

4. A. B. Kaul, K. G. Megerian, A. T. Jennings, and J. R. Greer, “Monolithically integrated, mechanically

resilient, carbon-based probes for Scanning Probe Microscopy,” NASA Tech. Briefs, Nov. 2010; NASA New

Technology report (NTR#47185).

5. A. B. Kaul and A. R. Khan, “Carbon nanofibers synthesized on selective substrates for nonvolatile memory

and 3D electronics applications,” NASA Tech. Briefs, vol. 35, no. 1, pp. 44, Jan. 2011 ; NASA New

Technology report (NTR#47157).

6. A. B. Kaul, “Carbon nanotube based chemical gas sensor,” NASA Tech. Briefs, Oct. 2010; NASA New

Technology report (NTR#46844).

7. A. B. Kaul, K. Megerian, P. von Allmen, R. L. Baron, “Fabrication of single, vertically aligned carbon

nanotubes in 3D nanoscale architectures,” NASA Tech. Briefs, Oct. 2010; NASA New Technology report

(NTR#46552).

8. A. B. Kaul, E. W. Wong, and L. Epp “Fast electromechanical switches based on carbon nanotubes” NASA

Tech. Briefs, vol. 32, no. 5, pp. 32, May 2008.

9. H. M. Manohara and A. B. Kaul, “High Sensitivity, broad-range vacuum gauge using nanotubes for

micromachined cavity applications,” NASA Tech. Briefs vol. 35, no. 1, pp. 44, Jan. 2011; NASA New

Technology report (NTR#45383).

10. A. B. Kaul, E. Wong, L. Epp, and B. D. Hunt “Fast switches based on carbon nanotubes,” Nanotech Briefs,

vol. 4, no. 2, pp. 12-13, Feb. 2007.

11. M. J. Bronikowski, A. B. Kaul, R. L. Baron, and H. Manohara, “Carbon nanotubes for high performance

structural materials applications,” NASA Tech. Briefs (in press); NASA New Technology report

(NTR#44231), Sep. 2006.

12. A. B. Kaul, B. Bumble, K. A. Lee, H. LeDuc, F. Rice and J. Zmuidzinas, “Making wide-IF SIS mixers with

suspended metal beam leads,” NASA Tech. Brief, pp. 40, Sept. 2005; NASA New Technology Report (NTR

#41296).

13. A. B. Kaul, A. W. Kleinsasser, B. Bumble, H. G. LeDuc, and K. A. Lee, “Making AlNx tunnel barriers using a

low-energy nitrogen-ion beam,” NASA Tech. Brief, pp. 42-44, Sept. 2005; NASA New Technology Report

(NTR #41197).

TECHNOLOGY REPORTS

1. K. A. Son, A. Liao, and A. B. Kaul, “High voltage GaN power switching electronics,” JPL Research and

Technology (R&TD) Final Report, Task 01STCR.R.10.021.067, Sep. 2010.

Page 33: CURRICULUM VITAE ANUPAMA BHAT KAUL EDUCATIONhb2504.utep.edu/vitas/akaul.pdf · Anupama B. Kaul, Mar. 2017 Page 5 of 33 NEEDS is designed to develop computation, simulation and educational

Anupama B. Kaul, Mar. 2017 Page 33 of 33

2. A. B. Kaul, J. B. Coles, M. Eastwood, T. Pagano, R. Green, and M. Foote, “Carbon nanostructured optical

absorbers as blackbody calibration targets for NASA’s spectrometers,” JPL Research and Technology

(R&TD) Final Report, Task 01STCR.R.10.021.067, Sep. 2010.

3. Author/Co-Author on 14 NASA New Technology Reports (2002 – present).

4. A. B. Kaul, K. Megerian, P. von Allmen, R. Kowalczyk, and R. Baron, “Carbon nanotube switches for

extreme environment electronics,” JPL Research and Technology (R&TD) Final Year 1 & Year 2 Report,

Task 01STCR.R.08.023.060, Sep. 2008 and Sep. 2009.

5. H. M. Manohara and A. B. Kaul “High-sensitivity, broad-range vacuum gauges using nanotubes,” JPL Lew

Allen Award Final Report for Task 01STCR, R.07.022.053, Sep. 2007.

6. A. B. Kaul, E. Wong, and L. Epp “A carbon nanotube switch with potential applications in high data rate,

low power, satellite communications” Final Report NASA NMO 715770, NRO DII, Mar. 2006.

7. M. Foote, J. Blacksberg, A. B. Kaul, and M. J. Kenyon, “Single crystal bolometric materials for high

performance thermal infrared planetary instruments” JPL Research and Technology (R&TD) Final Report,

Task 01STCR.R.05.021.068, Sep. 2005.

8. A. B. Kaul, T. Klosowiak, and J. Liu “A static technique for the electro-mechanical characterization of

MEMS devices for RF and microwave applications,” Scientific and Technical Aerospace Reports, vol. 40,

pp. 84, Nov. 2002.

9. K. Lian, M. Eliacin, A. B. Kaul, J. Liu, T. Klosowiak and B. Lempkowski, “An RF MEMS switch in a PWB HDI

process,” Motorola Labs Annual Conf. Proc., Sep. 2001.

10. A. B. Kaul, RF MEMS device characterization quarterly progress reports, Q2 (1/2001), Q3 (4/2001), Q4

(7/2001), Q5 (10/01), Q6 (1/02), Q7 (4/02), DARPA-AFRL MEMS program at Motorola Labs (F33615-00-2-

1718) in collaboration with University of Missouri-Rolla.

11. A. Bhat “An analysis of thermally-driven failure modes to address reliability issues (of a next generation

print-head design),” Thermal Ink-Jet Architecture Report, an internal Hewlett-Packard publication

distributed worldwide within Ink-Jet Printer Divisions, 1995.

12. A. Bhat, “Materials selection using Arrhenius Modeling for accelerated testing,” Thermal Ink-Jet

Architecture Report, an internal Hewlett-Packard publication distributed worldwide within Ink-Jet Printer

Divisions, 1994.

EXTRA-CURRICULAR ACTIVITIES Represented UC Berkeley in intercollegiate badminton competitions within CA, 1998.

Represented state of Tasmania (Australia), in inter-state badminton championships held in Melbourne,

Australia, 1987.