selected topics in nanoscience and nanotechnology …chem.ch.huji.ac.il/~porath/nst2/lecture...
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Selected Topics in Nanoscience and Selected Topics in Nanoscience and Selected Topics in Nanoscience and Selected Topics in Nanoscience and
NanotechnologyNanotechnologyNanotechnologyNanotechnology
Danny Porath 2006Physical Chemistry Department, The Hebrew University
Administrative issues:Administrative issues:Administrative issues:Administrative issues:
Danny Porath
Tel: 65-86948,
Monday, 11:00-13:00 (14:00)
�Papers reading and presentation
�Research proposal – as a final work
�Lecture notes – in my homepage: http://chem.ch.huji.ac.il/~porath/ (69706)
�References – on the web
Course SyllabusCourse SyllabusCourse SyllabusCourse Syllabus1. General survey of NST (1)2. Selected experimental techniques
a. Scanning electron/transmission microscopy (SEM/TEM) (1)
b. Lithography techniques (optical, e-beam, direct) (2)c. Scanning probe microscopy (STM/STS, AFM, EFM …) (2)
3. Single electron tunneling – short theory and examples (2)4. Leading directions in NST:
a. Nanoelectronics (2)
b. Nanomechanics (1)
c. Nanobiotechnology and nanomedicine (1)
5. Summary and future directions (1)6. Presentation of research proposals….
Links to NSTLinks to NSTLinks to NSTLinks to NSThttp://www.foresight.org/
http://dir.yahoo.com/Science/Nanotechnology/http://www.zyvex.com/nano/
http://www.nano.gov/http://nanonet.rice.edu/intronanosci/index.html
http://www.the21century.com/nano.htmhttp://www.nanozine.com/
http://seemanlab4.chem.nyu.edu/http://www.matar.ac.il/eureka/newspaper15/dreams.asphttp://www.science.org.au/nova/077/077key.htm
.
.
.
.
Some BooksSome BooksSome BooksSome Books……………………....
1. “Nanotechnology” – M. Ratner & D. Ratner
2. “Nanotechnology” – G. Timp
3. “Understanding Nanotechnology” – Scientific American
4. “Nanoelectronics and Information Technology”– R. Waser
With the help ofWith the help ofWith the help ofWith the help of……………………....
1. Jim Heath - UCLA
2. Jim Hutchbi - SRC
3. Yosi Shacam – TAU4. Cees Dekker – Delft
5. Yossi Rosenwacks - TAU
6. Julio Gomez - UAM7. Joshua Jortner - TAU
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Outline Survey NST:Outline Survey NST:Outline Survey NST:Outline Survey NST:1. Definition and description of the term “Nano”2. Why now? Why interdisciplinary? What is new here?3. NST in Israel and in the world4. Top-bottom vs. Bottom-up approaches5. Some of the “tools” for NST
1. SEM/TEM/SPM – The “eyes” to the nano world
2. Lithography – The “hands” in the nano world
3. Self-assembly and chemical manipulations
6. Examples of “nano” activitya. Nanoelectronics
b. Nanomechanics
c. Nanobiotechnology and Nanomedicine
7. Future ….. In the end of the course…Maybe
Homework 1Homework 1Homework 1Homework 11. Read the lecture on nanotechnology by R.P. Feynmann, "There's Plenty of
Room at the Bottom": http://www.zyvex.com/nanotech/feynman.htmlDoes it promise too much; is it unphysical by today's technology (2002) compared to the 1959 date when it was delivered? Is Nanotechnology just a continuation of the trend toward miniaturization that began decades ago, or is it something qualitatively different?
2. Read the US Government report: "Nanotechnology: Shaping The World Atom By Atom": http://itri.loyola.edu/nano/IWGN.Public.Brochure/Analyze in the same spirit as assignment 1 above.
Here I am looking for the clever insights that a graduate level student can glean from these articles.
3. Presentations to the class: ~ 10 minutes.
×××××××× 300300
×××××××× 300300
A pictorial definition of NanoA pictorial definition of NanoAphid
×××× 100
Paramecium ×××× 100
Tina (Weatherby) Carvalho
Bio Images by:
×××× 100
Electronics, circa 1985Electronics, circa 1985
40 nanometers40 nanometers
×××× 1000
Electronics, circa 2010Electronics, circa 2010
Electronics, circa 1985Electronics, circa 1985
Electronics, circa 2010Electronics, circa 2010
Electronics, circa 2040Electronics, circa 2040
X 100
1 nm diameter 1 nm diameter
molecular wires molecular wires
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A scanning tunneling microscope image of a Single-Walled Carbon NanotubeA symbol of the origins of Nanoscience & Nanotechnology
The visionThe visionThe visionThe vision
�The classic talk: “There's Plenty of Room at the Bottom”Richard Feynman, December 29, 1959. The annual meeting of the American Physical Society at Caltech
� “Why cannot we write the entire 24 volumes of the Encyclopedia Britannica on the head of a pin?”
� “Biology is not simply writing information; it is doing something about it. A biological system can be exceedingly small.”
� “I want to build a billion tiny factories, models of each other, which are manufacturing simultaneously, drilling holes, stamping parts, and so on.”
The visionThe visionThe visionThe vision
�The classic talk: “There's Plenty of Room at the Bottom”:
Richard Feynman, December 29, 1959. The annual meeting of the American Physical Society at Caltech
� “Why cannot we write the entire 24 volumes of the Encyclopedia Britannica on the head of a pin?”
� “Biology is not simply writing information; it is doing something about it. A biological system can be exceedingly small.”
� “I want to build a billion tiny factories, models of each other, which are manufacturing simultaneously ,drilling holes, stamping parts, and so on.”
Definition ??? T-B/B-UWorld/Israel ExamplesTools
VisionVisionVisionVision………….(a).(a).(a).(a)1. Nanostructures:
a. Contain a countable number of atoms
b. Suites for atomic level detailed engineering
c. Provide access to realms of quantum behaviorthat is not observed in larger (even 0.1 µm)
structures
d. Combine small size, complex organizational
patterns, potential for very high packingdensities, strong lateral interactions and high
ratios of surface area to volume.
VisionVisionVisionVision………….(b).(b).(b).(b)1. Small => …………means not only x1000 smaller but alsomeans not only x1000 smaller but alsomeans not only x1000 smaller but alsomeans not only x1000 smaller but also…………....
a. High packing density
b. Potential to bring higher speed to information processing
c. Higher areal and volumetric capacity to information storage.
d. Dense packing is also the cause of complex electronic and magnetic interactions between adjacent (and sometimes nonadjacent) structures.
e. The small energetic differences between the various possible nanostructures configurations may be significantly shaped by those interactions.
These complexities also promise access to These complexities also promise access to These complexities also promise access to These complexities also promise access to
complex complex complex complex nonnonnonnon----linear systemslinear systemslinear systemslinear systems that may that may that may that may
exhibit classes of behavior fundamentally exhibit classes of behavior fundamentally exhibit classes of behavior fundamentally exhibit classes of behavior fundamentally
different fromdifferent fromdifferent fromdifferent from those of both those of both those of both those of both molecular molecular molecular molecular
and microand microand microand micro----scale structuresscale structuresscale structuresscale structures....
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VisionVisionVisionVision………….(c).(c).(c).(c)New established disciplines:
a. Electronics: nanostructures represent the
limiting extension of Moore’s law and classical devices to small devices, and they
represent a step into quantum devices and
fundamentally new processor architectures.
b. Molecular biology: nanostructures are the
fundamental machines that drive the cell — histones and proteosomes — and they
are components of the mitochondrion, the
chloroplast, the ribosome, and the replication and transcription complexes. In
catalysis, nanostructures are the templates
and pores of zeolites and other vitally important structures.
c. Materials science: the nanometer length
scale is the largest one over which a crystal can be made essentially perfect. The ability
to precisely control the arrangements of
impurities and defects with respect to each other, and the ability to integrate perfect
inorganic and organic nanostructures,
holds forth the promise of a completely new generation of advanced composites.
…………and beyond the nice definitions and beyond the nice definitions and beyond the nice definitions and beyond the nice definitions …………
What it really isWhat it really isWhat it really isWhat it really is…………....
…………and beyond the nice definitions and beyond the nice definitions and beyond the nice definitions and beyond the nice definitions …………
What it really isWhat it really isWhat it really isWhat it really is…………....SoSoSoSo………….What are Nanoscience and Nanotechnology?.What are Nanoscience and Nanotechnology?.What are Nanoscience and Nanotechnology?.What are Nanoscience and Nanotechnology?
�The ability to observe, measure, predict and construct — on the scale of atoms and molecules and exploit the novel properties found at that scale.
�Traditionally, the nanotechnology realm is defined as being between 0.1 and 100 nanometers.
1 nm = 1/1000 mm = 1/1000000 mm.
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Some Observations:Some Observations:Some Observations:Some Observations:� Nanoscience and nanotechnology pertain to the synthesis,
characterization, exploration, interrogation, exploitation and utilization of nanostructured materials, which are characterized by at least one dimension in the nanometer range.
� Such nanostructured systems constitute a bridge between single molecules and infinite bulk systems.
� Individual nanostructures involve: clusters, nanoparticles, nanocrystals, quantum dots, nanowires, nanotubes…..
Additional Observations:Additional Observations:Additional Observations:Additional Observations:� Collections of nanostructures involve: arrays, assemblies and
superlattices of individual nanostructures.
�The chemical and physical properties of nanomaterials can significantly differ from those of the atomic-molecular or the bulk materials of the same chemical composition.
�The uniqueness of the structural characteristics, energetics, response, dynamics and chemistry of nanostructures is novel and constitutes the experimental and conceptual background for the novel field of nanoscience.
�Suitable control of the properties and response of nanostructures can lead to new devices and technologies.
Nanostructures and their assembliesNanostructures and their assembliesNanostructures and their assembliesNanostructures and their assemblies
Metals, semiconductors,magnetic materials
Radiusseveral nm
3-D superlattices ofnanoparticles
Insulators, semiconductors,
metals, DNA
Thickness1 – 1000 nm
Surfaces and Thin films
Metals, semiconductors,magnetic materials
AreaSeveral nm2 – µµµµm2
2-D Arrays ofNanoparticles
DNADiameter: 5 nmNanobiorods
Carbon, layeredchalcogenides
Diameter1 – 100 nm
Nanotubes
Metals, semiconductors,oxides, sulphides, nitrides
Diameter1 – 100 nm
Nanowires
Membrane proteinRadius5 – 10 nm
NanobiomaterialsPhotosynthetic Reaction
Center
Ceramic OxidesRadius: 1 – 100 nm Other nanoparticles
Insulators,semiconductors,
metals,magnetic materials
Radius1 – 10 nm
ClustersNanocrystals
Quantum Dots
MaterialSizeNanostructureNanostructures and their assembliesNanostructures and their assembliesNanostructures and their assembliesNanostructures and their assemblies
Metals, semiconductors,magnetic materials
Radiusseveral nm
3-D superlattices ofnanoparticles
Insulators, semiconductors,metals, DNA
Thickness1 – 1000 nm
Surfaces and Thin films
Metals, semiconductors,magnetic materials
AreaSeveral nm2 – µm2
2-D Arrays ofNanoparticles
DNADiameter: 5 nmNanobiorods
Carbon, layeredchalcogenides
Diameter1 – 100 nm
Nanotubes
Metals, semiconductors,oxides, sulphides, nitrides
Diameter1 – 100 nm
Nanowires
Membrane proteinRadius5 – 10 nm
NanobiomaterialsPhotosynthetic Reaction Center
Ceramic OxidesRadius: 1 – 100 nm Other nanoparticles
Insulators,semiconductors,
metals,magnetic materials
Radius1 – 10 nm
ClustersNanocrystals
Quantum Dots
MaterialSizeNanostructure
(Schmidt et. al.)
ClustersClustersClustersClusters
TEM of CdSe quantum rods, with average size 25*4 nm.
(Banin et. al.)
NanoparticlesNanoparticlesNanoparticlesNanoparticles
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TEM of CdSe quantum rods, with average size 25*4 nm.
Membrane ProteinsMembrane ProteinsMembrane ProteinsMembrane ProteinsExamples of Quantum WiresExamples of Quantum WiresExamples of Quantum WiresExamples of Quantum Wires
Nanotube
(Dekker et. al.)The Fullerenes:Nanoscale control
over materials properties
Nobel Prize in Chemistry, 1996
NanotubesDNA
(Cohen et. al.)
3.4 Å
34 Å
Nanoscale Fabrication schemeNanoscale Fabrication schemeNanoscale Fabrication schemeNanoscale Fabrication scheme……………………For exampleFor exampleFor exampleFor example…………....
(Eigler et. al.)
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Nano ImprintNano ImprintNano ImprintNano Imprint…………....
(Mirkin et. al.)
AFM Images of DNAAFM Images of DNAAFM Images of DNAAFM Images of DNA----Based moleculesBased moleculesBased moleculesBased molecules
1.0µm 600nm
400nm 300nm
1.5 µµµµmNano ???Nano ???Nano ???Nano ???Not Yet!!!Not Yet!!!Not Yet!!!Not Yet!!!
Nano!!!Nano!!!Nano!!!Nano!!!
G4-
(Cohen et. al.)
Example of DNAExample of DNAExample of DNAExample of DNA----Nanotube hybridNanotube hybridNanotube hybridNanotube hybrid
(Dekker et. al.)
Nanotube circuits Nanotube circuits Nanotube circuits Nanotube circuits ((((CeesCeesCeesCees Science cover)Science cover)Science cover)Science cover)
Why now?Why now?Why now?Why now?
1 m 10 Å: 1,000,000,000
Towards the nano (=10Towards the nano (=10Towards the nano (=10Towards the nano (=10----9999) scale ) scale ) scale ) scale ---- MooreMooreMooreMoore’’’’s law:s law:s law:s law:
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Towards the nano (=10Towards the nano (=10Towards the nano (=10Towards the nano (=10----9999) scale ) scale ) scale ) scale ---- MooreMooreMooreMoore’’’’s law:s law:s law:s law:
For exampleFor exampleFor exampleFor example…………....
(Intel site)
65 nm Technology
The Fullerenes:
Nanoscale control over materials properties
Nobel Prize in Chemistry, 1996
The Scanning Tunneling Microscope: Resolving the atomic world
Nobel Prize in Physics, 1988
The Development of Technological Means The Development of Technological Means and Computational Power Sufficient for and Computational Power Sufficient for Visualizing and operating in the NanoVisualizing and operating in the Nano--WorldWorld
Why Interdisciplinary?Why Interdisciplinary?Why Interdisciplinary?Why Interdisciplinary?
Adapted from the Asia-Pacific Economic Cooperation on Nanotechnology (http://www.apectf.nstda.or.th/html/nano.html).
The emergence of the nanometer as a fundamental length The emergence of the nanometer as a fundamental length
scale of science, engineering & medicinescale of science, engineering & medicine
Adapted from the –Nanotechnology Magazine: (http://www.nanozine.com/WHATNANO.HTM).
The emergence of the nanometer as a fundamental length The emergence of the nanometer as a fundamental length
scale of science, engineering & medicinescale of science, engineering & medicine
Graphite latticeGraphite lattice
ModerateModerate--Sized ProteinSized Protein
21st century technology will arise from an understanding of how to manipulate, control & manufacture at the nanoscale –This means interacting assemblies of molecular & macromolecular-scale components
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Publishing and Patenting in Bioscience/technology and
Nanoscience/technology -- The First 10 Years
© 2002 Lynne G. Zucker, Michael R. Darby, James R. Heath, and Evelyn L. Hu
0
2000
4000
6000
0 2 4 6 8 10
Number of Years from Base Year
Biotech Publishing Index
Nano Patents (x 10)
Nano Pub. Index
Bio Patents (x 10)
Base year =1973 for Biotech; = 1989 for Nanotech
The Fundamental RealizationNano in IsraelNano in IsraelNano in IsraelNano in Israel
HUJI
TAU
BGU
BI
Weizmann
Technion
Industry…
From Israeli sites
From Israeli sites
From Israeli sites
From Israeli sites…………
....
לחג-המיטב של אתר הידען
החדשות האחרונות
למיקרסקופרובוט אלחוטי פועל מתחת : ננוטכנול וגיה 20.9.2002
HP הננוטכנוולוגיה דיווחו על התקדמות בתחום ואינטל 19.9.2002
8.9.2002 זהירות תמנע יצירת בועה-ננוטכנול וגיה
העתיד נראה קטן 14.8.2002
טכנולוגיה-וחברה ישראלית הכריזה על חומר הסיכה היבש הראשון בעולם המבוסס על ננ 10.6.2002
מצב הננוטכנולוגיה בעולם ובארץ: הדבר הגדול הזעיר הבא 7.6.2002
2.5.2002 למיקרו מנועיםננומטרייםלהוסיף שרירים
"בקרוב זריקות ללא מחטים" 20.4.2002
2001 התגלית המדעית החשובה של -ננו מחשבים 22.12.2001
עשרה מיליון טרנזיסטורים בתוך ראש סיכה 9.11.2001
פרס נובל בכימיה על פיתוחים מולקולרי ים 30.9.2001
30.8.2001 פיתחו מעגל משולב על גבי מולקולה בודדתיבממדעני
חזקות כמו פלדה, עצמות-ננו 11.7.2001
?מה הם יידעו לעשות. רובוטים הראשונים צפויים להופי ע בתחילת העשור הבא-הננו 19.6.2001
הנאנו ינ וע , ואף על פי כן 27.11.2000
אבק שואב 2.11.2000
"להביט אל תוך החומר"שיטה חדישה 3.10.2000
ש"א וב" באוני ת-טכנולוגיה מתדפק בדלת -עידן הננו 1.8.2000
12.3.2000 הרבה יותר מידע-אלקטרון אחד
הנשק האטומי פרייר על ידו-נשק נאנו טכנולוגי 1.4.1998
ערוצים זעירים רואים את האור: כותרת 1.4.1998
http://www.hayadan.org.il/
גיה נולווטכננ
–
ועהת בצירנע י תמרות זהי
TAUTAUTAUTAU
Nano in The WorldNano in The WorldNano in The WorldNano in The World
NASA for Example….
(From NASA web site)
• Nanotechnology Program Elements- Nanoelectronics and Computing
- Sensors- Structural Materials
Nanoelectronics and Computing Sensors
Structural Materials
•Molecular electronics & photonics•Computing architecture•Assembly
•Life detection•Crew health & safety•Vehicle health
•Composites•Multifunctional materials•Self healing
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• Onboard computing systems for future autonomous
intelligent vehicles - powerful, compact, low power consumption,
radiation hard• High performance computing (Tera- and Peta-flops)
- processing satellite data- integrated space vehicle engineering
- climate modeling
• Revolutionary computing technologies• Smart, compact sensors, ultrasmall probes
• Advanced miniaturization of all systems• Microspacecraft
• 'Thinking' spacecraft• Micro-, nano-rovers for planetary exploration
• Novel materials for future spacecraft
Materials
Electronics/
computing
Sensors, s/c
components
• Single-walled
nanotube fibers
• Low-Power CNT
electronic
components
• In-space
nanoprobes
• Nanotube
composites
• Molecular
computing/data
storage
• Nano flight
system
components
• Integral
thermal/shape
control
• Fault/radiation
tolerant
electronics
• Quantum
navigation
sensors
• Smart “skin”
materials
• Nano electronic
“brain” for space
Exploration
• Integrated
nanosensor
systems
• Biomimetic
material
systems
• Biological
computing
• NEMS flight
systems @ 1 µW
2002 2004 2006 2011 2016
NASA Nanotechnology Roadmap
>
Increasing levels of system design and integration
C A P A B I L I T Y
High StrengthMaterials(>10 GPa)
High StrengthMaterials(>10 GPa)
Reusable Launch Vehicle (20% less mass, 20% less noise)
Reusable Launch Vehicle (20% less mass, 20% less noise)
Revolutionary Aircraft Concepts (30% less mass, 20% less emission, 25% increased range)
Revolutionary Aircraft Concepts (30% less mass, 20% less emission, 25% increased range)
Autonomous Spacecraft (40% less mass)
Autonomous Spacecraft (40% less mass)
Adaptive Self-Repairing Space Missions
Adaptive Self-Repairing Space Missions
Multi-Functional MaterialsMulti-Functional Materials
Bio-Inspired Materialsand ProcessesBio-Inspired Materialsand Processes
2002 2005 2010 2015
Biomimetic,radiation resistant
molecular computing
Nanoelectronics and Computing RoadmapImpact on Space Transportation, Space Science and Earth Science
CNT Devices
Biological Molecules
Ultra high density storage
Mis
sio
n C
om
ple
xit
y
Compute Capacity
RLV
hνe-
Nano-electroniccomponents
Europa Sub
Robot Colony
Sensor Web
Nanosensor RoadmapImpact on Space Transportation, HEDS, Space Science and Astrobiology
2002 2005 2015
Mis
sion
Com
ple
xity
Sensor Capacity1999
DSI RAX
2003ISPP
Missions too earlyfor nanotechnology impact
Biosensors
Spacestation
Europa Sub
Mars Robot Colony
Sensor Web2020
Nanotube VibrationSensor for Propulsion
Diagnostics
Optical Sensorsfor Synthetic
Vision
Nanopore for in situbiomark-sensor
Multi-sensorArrays (Chemical,
optical and bio)
2010
Sharp CJV
2002 2005 2010 2015
NANOTUBE COMPOSITES
MULTIFUNCTIONAL MATERIALS
SO3
- SO3
SO3- -H
+ H +H +
SO3-
SO3-
Ca++
SO3-
SO3-Ca++
SO3-
SO3-Ca++
Ca++
Tacky
Non-tacky
temperature
SELF-HEALING MATERIALS
Nano-Materials RoadmapImpact on Space Transportation, Space Science and HEDS
SELF-ASSEMBLING MATERIALS
Generation 3 RLVHEDS Habitats
Nanotextiles
Mis
sio
n C
om
ple
xit
y
Strong Smart Structures
RLV Cryo Tanks
Production ofsingle CNT
CNT Tethers
CNT = Carbon Nanotubes
2002 2010 2020 2030
Biomimetics and Bio-inspired SystemsImpact on Space Transportation, Space Science and Earth Science
Mis
sion
Com
ple
xity
Biological Mimicking
Embryonics
Extremophiles
DNA Computing
Brain-like computing
Self Assembled Array
Artificial nanoporehigh resolution
Mars in situlife detector
Sensor Web
Biological nanoporelow resolution
Skin and Bone
Self healing structureand thermal protection
systems
Biologically inspired aero-space systems
Space Transportation
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Nano in The worldNano in The worldNano in The worldNano in The world
(Scientific American, September 2001)
Quantum Information ScienceQuantum Information ScienceNanoscale MaterialsNanoscale Materials
Biology & HealthcareBiology & Healthcare
Molecular ElectronicsMolecular Electronics
Micro and Nano technologies Micro and Nano technologies Micro and Nano technologies Micro and Nano technologies ---- statusstatusstatusstatus
• Micro technologies
• 1/1,000,000 of a meter• Devices dimensions
today in the Microelectronics industry ~0.13 µµµµm
• The dimensions will reach 30 nm in 2014
• ~1000 million devices on a chip
• Nano technologies
• 1/1,000,000,000 of a meter
• 1000 Billion devices on a chip
• Atomic scale devices• Not in production
……... yet.
There are two ways to build a house…...
TopTop--downdown
BottomBottom--upup
The TopThe TopThe TopThe Top----down Approachdown Approachdown Approachdown Approach…………
The BottomThe BottomThe BottomThe Bottom----up Approachup Approachup Approachup Approach…………
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Main Tools for Nano:Main Tools for Nano:Main Tools for Nano:Main Tools for Nano:
1. Observation:a) SEM/TEM (optical)b) SPM
2. Construction:a) E-beam/optical Lithography
b) SPM Lithography
c) Self assemblyd) Chemistry
Scanning Electron Microscope (SEM) Scanning Electron Microscope (SEM) Scanning Electron Microscope (SEM) Scanning Electron Microscope (SEM)
PrinciplePrinciplePrinciplePrinciple
Radiolarian (in Plankton) x 750
Scanning Electron Microscope (SEM) Scanning Electron Microscope (SEM) Scanning Electron Microscope (SEM) Scanning Electron Microscope (SEM)
PrinciplePrinciplePrinciplePrinciple
(From IOWA U. web site)
SEM Image SEM Image SEM Image SEM Image (Leo 1530)(Leo 1530)(Leo 1530)(Leo 1530)
High resolution image of a frozen, hydrated yeast
uncoated chromite
SEM ImagingSEM ImagingSEM ImagingSEM Imaging
~4 nm gap
Before Au55
trapping
After Au55
trapping
2 nm
Transmission Electron Microscope Transmission Electron Microscope Transmission Electron Microscope Transmission Electron Microscope
(TEM) Image (TEM) Image (TEM) Image (TEM) Image (Leo 922 OMEGA)(Leo 922 OMEGA)(Leo 922 OMEGA)(Leo 922 OMEGA)
Si[110] taken on LEO 922 Lattic spacings: [111] = 0.31nm, [200] = 0.27nm
Tunnelling device on the basis of a Si/Geheterostructure
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Scanning Tunneling Microscope (STM)Scanning Tunneling Microscope (STM)Scanning Tunneling Microscope (STM)Scanning Tunneling Microscope (STM)
Sample
Piezo
Electronics(Current+Feedback)
Computer(Control)
Matrix ofheights(Image)
Tip
I(V) ~ Ve-(ks)
� Tunneling between a sharp tip and conducting surface.
� Piezo enables xy and z movement.� Working mode: constant current.� The feedback voltage Vz(x,y) is translated to height
(topographic) information.
STM HeadSTM HeadSTM HeadSTM Head
דג�דג�דג�דג�
בידודבידודבידודבידוד
בסיסבסיסבסיסבסיס
STM ראש הראש הראש הראש ה
חודחודחודחוד
בורגבורגבורגבורג
מיקרומיקרומיקרומיקרו
מטרימטרימטרימטרי
גבישגבישגבישגביש
פייזופייזופייזופייזו
אלקטריאלקטריאלקטריאלקטרי
רכיבי היחידה המרכזיתרכיבי היחידה המרכזיתרכיבי היחידה המרכזיתרכיבי היחידה המרכזית
STM ImagesSTM ImagesSTM ImagesSTM Images
Graphite – atomic resolution: Supercoiled DNA
Atomic Force Microscope ( AFM) PrincipleAtomic Force Microscope ( AFM) PrincipleAtomic Force Microscope ( AFM) PrincipleAtomic Force Microscope ( AFM) Principle
AFM HeadAFM HeadAFM HeadAFM Head
Vibration isolation + Stiffness
1cm
Laser diodeWindow for
optical microscope
Photodiode
Coarse approach
Piezoelectric scanner
Photodiode adjustment
system
AFM ImagesAFM ImagesAFM ImagesAFM Images
Magnetic bits of a zip disk G4-DNA
100nm10µm
DNA-NanotubeNanotube between
electrodes
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Directions of development in Nano:Directions of development in Nano:Directions of development in Nano:Directions of development in Nano:
1. Nanoelectronics2. Nano-mechanics (MEMS/NEMS)3. Nano-bio(techno)logy4. Nano-medicine
APPLICATIONS:APPLICATIONS:APPLICATIONS:APPLICATIONS: NANODEVICES, NANOELECTRONICS, NANODEVICES, NANOELECTRONICS, NANODEVICES, NANOELECTRONICS, NANODEVICES, NANOELECTRONICS,
AND NANOSENSORSAND NANOSENSORSAND NANOSENSORSAND NANOSENSORS
Current Scientific Advances:1. The discovery and the controlled preparation of carbon
nanotubes and their use to fabricate individual electronic devices.
2. The ability to place engineered individual molecules onto electrical contacts and measure electrical transport through them.
3. The availability of proximal probe techniques and their use to manipulate matter and fabricate nanostructures.
APPLICATIONS:APPLICATIONS:APPLICATIONS:APPLICATIONS: NANODEVICES, NANOELECTRONICS, NANODEVICES, NANOELECTRONICS, NANODEVICES, NANOELECTRONICS, NANODEVICES, NANOELECTRONICS,
AND NANOSENSORSAND NANOSENSORSAND NANOSENSORSAND NANOSENSORS
4. The development of chemical synthetic methods to prepare nanocrystals and monolayers, and methods to further assemble them into larger organized structures.
5. The introduction of biomolecules and supermolecularstructures into the field of nanodevices.
6. The isolation of biological motors, and their incorporation into non-biological environments.
The Electrical Conductivity of a Single MoleculeThe Electrical Conductivity of a Single MoleculeThe Electrical Conductivity of a Single MoleculeThe Electrical Conductivity of a Single Molecule
(Reed et al. 1997)
Organic Nanostructures: The Electrical Organic Nanostructures: The Electrical Organic Nanostructures: The Electrical Organic Nanostructures: The Electrical
Conductivity of a Single Molecule (breakConductivity of a Single Molecule (breakConductivity of a Single Molecule (breakConductivity of a Single Molecule (break----junctions)junctions)junctions)junctions)
(Reed et al. 1997)
Organic Nanostructures: The Electrical Organic Nanostructures: The Electrical Organic Nanostructures: The Electrical Organic Nanostructures: The Electrical
Conductivity of a Single Molecule (breakConductivity of a Single Molecule (breakConductivity of a Single Molecule (breakConductivity of a Single Molecule (break----junctions)junctions)junctions)junctions)
(Reed et al. 1997)
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1. The size reduction of electronic devices to the molecular scale will dictate the use of a new physics, because current microelectronics is classical and nanoelectronics is quantum mechanical.
2. The cost of building the factories for fabricating electronic devices, or fabs, is increasing at a rate that is much larger than the market for electronics; therefore, much less expensive manufacturing process will need to be invented.
3. Molecular electronics: molecules, that are quantum electronic devices, are designed and synthesized using batch processesof chemistry and then assembled into useful circuits through the processes of self-organization and self-alignment.
Molecular Electronics ThemesMolecular Electronics ThemesMolecular Electronics ThemesMolecular Electronics Themes4. If molecular electronics achieves the ultimate goal of using
individual molecules as switches and carbon nanotubes as the wires in circuits, we can anticipate nonvolatile memories with one million times the bit area density of today’s DRAMsand power efficiency one billion times better than conventional CMOS circuitry.
5. Such memories would be so large and power-efficient that they could change the way in which computation is performed from using processors to calculate on the fly to simply looking up the answer in huge tables.
6. A major limitation of any such process is that chemically fabricated and assembled systems will necessarily contain defective components and connections. This limitation was addressed in a 1998 paper entitled “A Defect-Tolerant Computer Architecture: Opportunities for Nanotechnology”. (Heath et al.1998).
Molecular Electronics ThemesMolecular Electronics ThemesMolecular Electronics ThemesMolecular Electronics Themes
(Heath et al. 1998)Molecular ElectronicsMolecular ElectronicsMolecular ElectronicsMolecular Electronics
(Avouris et al. IBM)
A FieldA FieldA FieldA Field----Effect Transistor Made from a SingleEffect Transistor Made from a SingleEffect Transistor Made from a SingleEffect Transistor Made from a Single----
Wall Carbon NanotubeWall Carbon NanotubeWall Carbon NanotubeWall Carbon Nanotube
(Avouris et al. IBM)
Carbon Nanotube ManipulationCarbon Nanotube ManipulationCarbon Nanotube ManipulationCarbon Nanotube Manipulation
AFM Scanning
Lowering the tip and pushing
VDW forces hold the CNT
(Avouris et al. IBM)AFM OxidationAFM OxidationAFM OxidationAFM Oxidation
61 % Humidity 14 % Humidity
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(Avouris et al. IBM)Theory of CNTTheory of CNTTheory of CNTTheory of CNTTwisting angle
effect on energy band-gap
Bending effect of on CNT Electronic Structure
The NASA Avionic RoadmapThe NASA Avionic RoadmapThe NASA Avionic RoadmapThe NASA Avionic Roadmap
1. NASA has created the Deep Space Systems Technology Program, known as X2000.
2. Every 2-3 years starting in 2000, the program will develop and deliver advanced spacecraft systems and to missions in different areas of the solar system and beyond.
3. In order to achieve reduction in the size of spacecraft, the avionics systems of the spacecraft are being reduced in size with each delivery of X2000, in part by means of integrating nanotechnology with microtechnology.
4. The figure attempts to chart the forecasts of the mass, volume, and power of future avionics systems of spacecraft. The leftmost column shows the Mars Pathfinder spacecraft, which represents the current state of the art.
(NASA)
Avionic RoadmapAvionic RoadmapAvionic RoadmapAvionic RoadmapIntegrated Nanotechnology in MicrosystemsIntegrated Nanotechnology in MicrosystemsIntegrated Nanotechnology in MicrosystemsIntegrated Nanotechnology in Microsystems
Control of mechanical, electrical, optical, and chemical properties at the nanoscale will enable significant improvements in integrated microsystems.
1. When certain materials systems are exposed to a magnetic field, their electrical resistance changes. This effect - the magnetoresistive effect, is useful for sensing magnetic fields such as those in the magnetic bits of data stored on a computer hard drive.
2. In 1988, the giant magnetoresistance effect (GMR) was discovered in layers of nanometer-thick magnetic and nonmagnetic films.
3. a spin valve, could sense very small magnetic fields. This opened the door for the use of GMR in the read-heads of magnetic disk drives.
4. In the spin valve GMR head, the copper spacer layer is about 2 nm thick, and the cobalt GMR pinned layer is about 2.5 nm thick. The thickness of these layers must be controlled with atomic precision.
A Commercial IBM Giant A Commercial IBM Giant A Commercial IBM Giant A Commercial IBM Giant MagnetoresistanceMagnetoresistanceMagnetoresistanceMagnetoresistance
Read HeadRead HeadRead HeadRead Head
A Commercial IBM Giant A Commercial IBM Giant A Commercial IBM Giant A Commercial IBM Giant MagnetoresistanceMagnetoresistanceMagnetoresistanceMagnetoresistance
Read HeadRead HeadRead HeadRead Head
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Additional Nanoelectronic devicesAdditional Nanoelectronic devicesAdditional Nanoelectronic devicesAdditional Nanoelectronic devices…………device and architecture options for highdevice and architecture options for highdevice and architecture options for highdevice and architecture options for high----performance electronicsperformance electronicsperformance electronicsperformance electronics
Resonant Tunneling Devices in NanoelectronicsResonant Tunneling Devices in NanoelectronicsResonant Tunneling Devices in NanoelectronicsResonant Tunneling Devices in Nanoelectronics
1. The crucial technology for advancing these quantum devices has been epitaxial growth and process control at the nanoscale.
2. The resonant tunneling diode (RTD) consists of an emitter and collector regions, and a double-tunnel barrier structure that contains a quantum well, as shown in the energy band diagrams.
3. This quantum well is so narrow (5-10 nm) that it can only contain a single so-called “resonant”energy level.
Resonant Tunneling Devices in NanoelectronicsResonant Tunneling Devices in NanoelectronicsResonant Tunneling Devices in NanoelectronicsResonant Tunneling Devices in Nanoelectronics
4 bit 2 GHz analog-to-digital converter, 3 GHz (40 dB spur-free dynamic range) clocked quantizer, 3 GHz sample and hold (55 dB linearity), clock circuits, shift registers, and ultralow power SRAM (50 nW/bit)
(Seabaugh 1998)
The Future of NST ????The Future of NST ????The Future of NST ????The Future of NST ????
HmmmmmHmmmmmHmmmmmHmmmmm…………....
In the end of the course!!! In the end of the course!!! In the end of the course!!! In the end of the course!!! (Maybe)(Maybe)(Maybe)(Maybe)
The Future of NST ????The Future of NST ????The Future of NST ????The Future of NST ????
HmmmmmHmmmmmHmmmmmHmmmmm…………....
Still to be revealed!!! Still to be revealed!!! Still to be revealed!!! Still to be revealed!!! (Maybe)(Maybe)(Maybe)(Maybe)