thesis orientation day - technologisch gezelschaptg.tudelft.nl/tod/tod_beijerinckzaal.pdfnuclear...
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Thesis orientation day Welcome on behalf of Technologisch Gezelschap!
Section tours Date Section
Ma 12 dec OMI
Di 13 dec OM
Wo 14 dec PPE
Do 15 dec ASM
Vr 16 dec IRS
Ma 19 dec TP
Di 20 dec CE
Wo 21 dec BOC
Do 22 dec MECS
Guided tours of the various sections. 15 places available on each tour. Enrol at the TG website:
technologischgezelschap.nl/sectiontours
Schedule Time Beijerinckzaal Korvezeezaal
15:45 Start Start
15:50-16:00 MEP – Jan van Esch BEP – Erik Kelder
16:00-16:10 Break Break
16:10-16:20 OMI IRS
16:20-16:30 Break Break
16:30-16:40 MECS BOC
16:40-16:50 Break Break
16:50-17:00 PPE ASM
17:00-17:10 Break Break
17:10-17:20 OM TP
17:20-17:30 Break Break
17:30-17:40 CE BT
17:40-17:50
17:50-18:00 Poster market & drinks (atrium) 18:00-18:10
18:10-18:20
18:20-18:30
Jan van Esch
Thesis Orientation Day – 30 November 2016
Second Year: Thesis Project & Internship Thesis Project (40 ec, 28 weeks) : Research, carried out at TU Delft Industrial Internship (18 ec, 13 weeks): Design/Research/Operations/etc, done at a company or non-academic institute
Decide yourself which one first Complete (almost) all compulsory courses before starting thesis project Today about Thesis Project
Master Thesis Project Orientation (today, websites of research groups, lunch meetings, etc) Visit several research groups, speak with people, inform yourself Choose Group, Supervisor and Project Subject of the project People you’ll work with: responsible supervisor / daily supervisor / other group members Number of students in the group <> available support from supervisor Make time planning and register the project at the thesis office Reporting and presentation. Thesis defence after 7 months
Chemical Product Engineering Track
Thesis projects can be done in 6 Research groups in the ChemE department: Advanced Soft Matter (ASM) - van Esch Catalysis Engineering (CE) - Kapteijn Materials for Energy Conversion and Storage (MECS) - Dam Opto-Electronic Materials (OM) - Siebbeles Organic Materials & Interfaces (OMI)- Sudhölter Product and Process Engineering (PPE) - Kreutzer or in other groups at TU Delft if the project is approved by the board of examiners before the start of the project.
Process Engineering Track 7 Research groups in ChemE department: Advanced Soft Matter (ASM) - van Esch Catalysis Engineering (CE) - Kapteijn Materials for Energy Conversion and Storage (MECS) - Dam Opto-Electronic Materials (OM) - Siebbeles Organic Materials & Interfaces (OMI)- Sudhölter Product and Process Engineering (PPE) - Kreutzer Transport Phenomena (TP) – Kleijn 1 Research group in Process & Energy department (3mE): Intensified Reaction & Separation Systems (IRS) – Stankiewicz or in other groups at TU Delft if the project is approved by the board of examiners before the start of the project.
Nuclear Science & Engineering Track
5 Research groups in the Radiation Science and Technology department: Radiation and Isotopes for Health (RIH) - Wolterbeek Nuclear Energy and Radiation Applications (NERA) - Kloosterman Fundamental Aspects of Materials and Energy (FAME) - Brück Neutron and Positron Methods in Materials (NPM2) - Pappas Radiation Detection and Medical Imaging (RD&M) - Beekman or in other groups at TU Delft if the project is approved by the board of examiners before the start of the project.
Information Blackboard Stagebureau TNW / Internship Office Applied Sciences Eindprojecten Administratie TNW / Thesis Office Applied Sciences Guidelines and forms, assessment criteria Information Experiences from fellow students Assessment done by Thesis Committee: at least three academic staff members (assistant, associate, full professors) from at least two different groups, and at least one full professor.
Internship & Thesis Office Applied Sciences
Internship Office
TN-building, Room A.210 [email protected]
Thesis Project Office
TN-building, Room A.208 [email protected]
Ms. Suzanne Karssen Internship Officer
Ms. Linda van der Elst Thesis Project Officer
Program for today 16.00 - 17.45 Simultaneous PPT presentations by research groups: Beijerinckzaal: 16:10 Organic Materials & Interfaces (OMI) 16:30 Materials for Energy Conversion and Storage (MECS) 16:50 Product & Process Engineering (PPE) 17:10 Optoelectronic Materials (OM) 17:30 Catalysis Engineering (CE) Korvezeezaal: 16:10 Intensified Reaction and Separation Systems (IRS) 16:30 Biocatalysis (department of Biotechnology) 16:50 Advanced Soft Matter (ASM) 17:10 Transport Phenomena (TP) Atrium: 17.30 - 19.00 Poster presentations and free drinks! 12 – 19 December: Labtours to research groups
Thank you for your attention!
Schedule Time Beijerinckzaal Korvezeezaal
15:45 Start Start
15:50-16:00 MEP – Jan van Esch BEP – Erik Kelder
16:00-16:10 Break Break
16:10-16:20 OMI IRS
16:20-16:30 Break Break
16:30-16:40 MECS BOC
16:40-16:50 Break Break
16:50-17:00 PPE ASM
17:00-17:10 Break Break
17:10-17:20 OM TP
17:20-17:30 Break Break
17:30-17:40 CE BT
17:40-17:50
17:50-18:00 Poster market & drinks (atrium) 18:00-18:10
18:10-18:20
18:20-18:30
Prof. Ernst Sudholter Section leader
2 (+ 1 guest) associate professor 3 assistant professor 7 PhD students 4 Postdocs 4 Research Assistants
Dr. Rajeev K. Dubey Thesis Orientation Day
30th November 2016
Sensors
Membranes Colloids and Interface
Energy Conversion and Storage
Energy Conversion and storage
Chemistry of colours. Design and Synthesis of Systems
based on Perylene Dyes Dr. Rajeev K. Dubey Dr. Wolter F. Jager
R.K. Dubey et al. Organic Letters 2016, DOI: 10.1021/acs.orglett.6b02887. R.K. Dubey et al. Organic Chemistry Frontiers 2016 3, 1481–1492. R.K. Dubey et al. Chemical Science 2016 7, 3517–3532.
Silicon anodes for Li ion batteries
Pierre Ranque Dr. Erik Kelder
Problem: Silicon expansion and deterioration during cycling!
Solution: Synthesis of polymers that will accomodate silicon expansion during Li uptake. Self-healing
polymers Shape shifting
polymers
Membranes
Membranes for Phosphate Removal and Solvent Nanofiltration
Laura Paltrinieri
Dr. Louis de Smet
Mohammad Amirilargani
Polymer grafting Pore size adjustment
Increasing hydrophobicity
Surface polarity Applications: Petrochemical and pharmaceutical industries.
Sensors
Silicone nanowires and MOF for sensing
Cao, A. et al; Sensors 2014, 14, 245-271. Cao, A. et al; Analytical Chemistry 2015, 87, 1173–1179. Cao, A. et al; Nano letters, accepted.
Anping Cao
Look out for explosives!!!
Dr. Louis de Smet Sumit Sachdeva
MOF – polyimide composite for impedimetric detection of methanol.
Biomimetic soft interface
Dr. Lukasz Poltorak Electrified liquid – liquid interface (LLI)
L.Poltorak et al; Langmuir 2014, 30, 11453-11463 L. Poltorak et al; Electrochemistry Communications 2013, 37, 76-79 L. Poltorak et al; Electrochimica Acta 2016, 188, 71-77
Forensic Chemistry
Dr. Marcel de Puit
Analytical Methods, 7 (24), 10121-10124 Nature Sci. Rep., 5, 2015, 11716
1. Smart materials for fingerprint visualization (e.g. Fluorescent polyelectrolyte). 2. Detection and sensing of illict drugs. 3. Illicit drugs in fingerprints. 4. Analitical chemistry for Forensics (MALDI MS, UPLC MS, Surface MS...)
(in collaboration with National Forensic Institute)
Colloids and Interface
Enhanced Oil recovery Dr. Naveen Kumar
(Project in collaboration with Shell)
Atomic force microscopy: adhesion force measurements
Dr. Klaas Besseling
Interested in MSc thesis? https://chemeomi.wordpress.com/
MSC/BSC projects
Membranes for organic solvent nanofiltration
• Applications: – Oil, chemical and petrochemical industries – Pharmaceutical industries – Food industries
Polymer grafting Pore size adjustment
Increasing hydrophobicity
Surface polarity
Mohammad Amirilargani
Dr. Louis C. P. M. de Smet
Membranes for Phosphate Removal
Laura Paltrinieri
Dr. Louis C. P. M. de Smet
Commercial membranes modified with:
Functionalized Polyelectrolytes P-attractive nanomaterials
Silicone nanowires (SiNW) for sensing
Cao, A. et al; Sensors 2014, 14, 245-271. Cao, A. et al; Analytical Chemistry 2015, 87, 1173–1179. Cao, A. et al; Nano letters, accepted.
SiNW chip Silicone nanowires
Anping Cao Dr. Louis C. P. M. de Smet
Gas sensing – MOF
S. Sachdeva et al. CrystEngComm, 2016,18, 4018-4022 S. Sachdeva et al. ACS Sens., 2016, 1 (10), pp 1188–1192
Sumit Sachdeva Dr. Louis C. P. M. de Smet
Schedule Time Beijerinckzaal Korvezeezaal
15:45 Start Start
15:50-16:00 MEP – Jan van Esch BEP – Erik Kelder
16:00-16:10 Break Break
16:10-16:20 OMI IRS
16:20-16:30 Break Break
16:30-16:40 MECS BOC
16:40-16:50 Break Break
16:50-17:00 PPE ASM
17:00-17:10 Break Break
17:10-17:20 OM TP
17:20-17:30 Break Break
17:30-17:40 CE BT
17:40-17:50
17:50-18:00 Poster market & drinks (atrium) 18:00-18:10
18:10-18:20
18:20-18:30
Materials for Energy Conversion and
Storage
Research projects - Artificial fuel synthesis like H2, CH4, CH3OH, NH3 (Wilson Smith) - Direct light to hydrogen conversion (Wilson Smith) - Novel low cost electrolysis (Fokko Mulder) - H-based batteries (with start-up) (Fokko Mulder) - Nanoparticle production for sensors, catalysis, etc. (with start-up) (Andreas Schmidt-Ott) - Metal hydrides for sensors (with industry) (Bernard Dam) - Photochromic materials (Bernard Dam) -Li ion batteries and electrolytes (Fokko Mulder)
A high capacity rechargeable metal hydride based battery
These Ni-MH batteries are in current hybrid cars and contain costly, heavy metal, LaNi5. We work on novel low cost, light metal hydride, electrode materials. Contact: [email protected]
STONE A long life, low cost, environmentally friendly battery
Storing electricity from solar and wind power takes batteries that live as long as solar cells (20-30 years). Together with a TUD spin-off we work on a proton based battery that can be placed in e.g. houses. Contact: [email protected]
Next generation Li ion batteries Lithium ion batteries provide large energy density. We work on new electrodes based on nanostructured conductive carbon materials with Li storing materials in between. Collaboration with industries. Contact: [email protected]
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combinatorial
R. Gremaud et al. Adv Mat 19 (2007) 2813
Hydrogenation cell
3 CCD Camera
Combinatorial approach MH-based hydrogen sensor materials [email protected]
Ngene et al., Advanced Functional Materials 24 (2014) 2374
38
Photochromic YOyHx The mysterious role of hydrogen in metal oxides
Mongstad et al.: Solar Energy Materials & Solar Cells 95 (2011) 3596–3599
400 600 800 10000
20
40
60
80
100
Tr
ansm
ittanc
e %
Wavelength (nm)
before illumination 10 min 20 min 90 min 380 min
Photodarkening of a thin YOH film: • What is the mechanism • Can we tune the excitation wavelength • Can we speed up the darkening/bleaching
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Natural Photosynthesis Artificial Photosynthesis
Sustainable Production of Solar Fuels [email protected]
Using sunlight and water to create a clean, renewable, and sustainable fuel We focus on only using cheap and earth abundant materials to make a fuel that is technically,
economically, and environmentally able to replace fossil fuels
Challenge the future
Delft University of Technology
Artificial Photosynthesis [email protected]
Solar water splitting to make H2 Electrochemical reduction of CO2 to synthetic fuels
Two ways to make CO2-neutral fuels
Producing Nanoparticles from the Gas Phase [email protected] Feng, Biskos, Schmidt-Ott, www.nature.com/scientificreports
Applications of Nanoparticles from the gas phase being studied [email protected]
Sharpen AFM or STM tip by nanoparticle impaction
(together with PPE)
Particulate porous layers of controllable and variable composition
Extremely sensitive Chemical Sensors
Catalysis CO CH4 H2 O H2
Well-defined (mixed) nanoparticles
Efficiency enhancement for thin-film solar cells and solar water splitting
Nanoparticles from spark generator
Water decontamination by demobilized nano-particles
(with Univ. Capetown)
(with ETH Zurich)
Immobilizing nanoparticles for different purposes [email protected]
Water decontamination by demobilized nanoparticles
(Together with University of Cape Town, South Africa)
Sharpen AFM or STM tip by nanoparticle impaction
(together with PPE)
1) Immobilization by diffusion to fibres of filter
2) Immobilization by impaction
Schedule Time Beijerinckzaal Korvezeezaal
15:45 Start Start
15:50-16:00 MEP – Jan van Esch BEP – Erik Kelder
16:00-16:10 Break Break
16:10-16:20 OMI IRS
16:20-16:30 Break Break
16:30-16:40 MECS BOC
16:40-16:50 Break Break
16:50-17:00 PPE ASM
17:00-17:10 Break Break
17:10-17:20 OM TP
17:20-17:30 Break Break
17:30-17:40 CE BT
17:40-17:50
17:50-18:00 Poster market & drinks (atrium) 18:00-18:10
18:10-18:20
18:20-18:30
Life at the Product & Process Engineering Group cheme.nl/ppe
Do you like: • Reaction Engineering • Transport phenomena • Working on relevant applications
and are you interested in: • Lab-on-a-Chip / Organ-on-a-chip technology • Behavior of biofluids, bubbles, droplets or biological cells on the
micro/nanoscale • Transport phenomena in health applications • Interaction between and flow of nanoparticles • Scalable production of nanostructured materials
Product & Process Engineering Group
Lab-on-a-chip: each droplet is a test tube
van Steijn et al., Phys. Rev. Lett. (2009)
Create Mix
Song et al., Angew. Chem. Int. Ed. (2006)
Connects to FTV/MTP/ATP. Ideal if you want to make a career in medicine/health/pharma
Product & Process Engineering Group
Extract
van Steijn et al.
Time lapse of yeast growth
Numerical simulation (with TP group)
Multidisciplinary health projects
Blood
Extracellular fluid
Blood vessel-on-a-chip
Nice transport phenomena problem for physicist
Drug release from a drug eluting stent
Product & Process Engineering Group
Rheology of DNA and Complex Fluids Macromolecules P
Q
Die lip
Extr
usio
n
Product Processing
50 um
From Molecule to
Phys. Rev. Lett. (2010) Soft Matter, (2010) Macromolecules, (2011) Macromolecules, (2014)
Product & Process Engineering Group
Engineering of DNA Transfer into Cells
Nature Nanotech., (2011)
Adv. Healthcare Mat., (2014)
Product & Process Engineering Group
1. Precise 2. Scalable 2. Versatile 4. Efficient
Scalable production of nanostructured materials Al2O3 on TiO2 Pt on TiO2
Self-healing materials Catalysts
Atomic layer deposition in a fluidized bed
Product & Process Engineering Group 2D materials
Controlled release medicines
Novel approaches for Chem. Reaction Eng.
I0 IL x
(1-ω)I I
ωI Photoreactor design & modelling
Product & Process Engineering Group
Atomic-level understanding for
nanoscale engineering
Production of novel materials for LED lighting
Novel methods for making medical isotopes
Overview of BEP/MEP projects
Product & Process Engineering Group
cheme.nl/ppe
Schedule Time Beijerinckzaal Korvezeezaal
15:45 Start Start
15:50-16:00 MEP – Jan van Esch BEP – Erik Kelder
16:00-16:10 Break Break
16:10-16:20 OMI IRS
16:20-16:30 Break Break
16:30-16:40 MECS BOC
16:40-16:50 Break Break
16:50-17:00 PPE ASM
17:00-17:10 Break Break
17:10-17:20 OM TP
17:20-17:30 Break Break
17:30-17:40 CE BT
17:40-17:50
17:50-18:00 Poster market & drinks (atrium) 18:00-18:10
18:10-18:20
18:20-18:30
1-12-2016
Challenge the future
Delft University of Technology
Opto-electronic Materials Ferdinand Grozema
14.12a14.12a
56
Section Opto-electronic Materials
Prof. dr. L. D.A. Siebbeles Dr. F. C. Grozema Dr. ir. T. J. Savenije Dr. A. J. Houtepen
Interactions between light and matter: Exploiting the power of light !
Applications: • Solar cells • Quantum dots for lighting applications • Displays • Medical applications • New materials for electronics • Fundamental understand of material properties
57
Novel nanostructured materials for: cheap solution processable, mechanically flexible, highly efficient solar cells and other molecular devices
Organics Quantum Dots Solar Cell
LED
Section Opto-electronic Materials
Perovskites Laser
58
59
Perovskites • Hybrid organic inorganic materials
• Currently the most promising new materials in
solar cells
• Next big thing in photovoltaics!!
60
Quantum dots
Aerts, M., et al., Nature Communications 2014, 5, 3789 Suchand Sandeep et al., Nature Communications 2013, 4, 2360 Gao. Y. et al. Nature Communications 2013, 4, 2329 Talgorn, E., et al. Nature Nanotechnology 2011, 6, (11), 733-739. Trinh, M. T., et al. Nano Letters 2011, 11, (4), 1623-1629.
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Quantum dots
• Tunable color by variations in size, composition • Light absorber/emitter • Display: ultra-HD TVs: Samsung • Quantum dot solar cells
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Molecular/organic electronics
Charge transfer through single molecules: -Fundamental studies of charge transfer: elementary process in many applications, for instance solar cells
-Clear link with single molecule electronics
Charge transport in molecular solids -Charge carrier mobility measured by microwave conductivity
-Mobility strongly depends of mutual orientation of molecules in solid
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Lots of possibilities • Synthesis/processing
• Organic molecules for electronics • New quantum dot materials
• Characterize opto-electronic properties
• Laser spectroscopy: fluorescence, transient absorption measurements • Follow processes on very short time-scale • Conductivity experiments
• Simulate/predict properties
• Computational chemistry: quantum chemical calculations
• Make devices • Quantum dot or perovskite solar cells
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Collaborations
Universities all over the world Industrial:
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We are nice!
Schedule Time Beijerinckzaal Korvezeezaal
15:45 Start Start
15:50-16:00 MEP – Jan van Esch BEP – Erik Kelder
16:00-16:10 Break Break
16:10-16:20 OMI IRS
16:20-16:30 Break Break
16:30-16:40 MECS BOC
16:40-16:50 Break Break
16:50-17:00 PPE ASM
17:00-17:10 Break Break
17:10-17:20 OM TP
17:20-17:30 Break Break
17:30-17:40 CE BT
17:40-17:50
17:50-18:00 Poster market & drinks (atrium) 18:00-18:10
18:10-18:20
18:20-18:30
Challenge the future
atalysis E ngineering
C http://cheme.nl/ce/
Jorge Gascon and Freek Kapteijn
C atalysis E ngineering
Ina Vollmer Maria Jose Valero
Martijn de Lange
Irina Prokopyeva
Maxim Navisalevich
Sumit Sachdeva
Alla Dikhtiarenko
Filipe Lopes
Alma Olivos
Rupali Bhardwaj
Beba Seoane
Eduardo Andres
Nastya Bavykina
Dmitrii Osadchii Anahid Sabetghadam
Xiaohui Sun
Tim Wezendonk Francesc Sastre
Elena Rozhko
Meixia Shan
Sonia Castellanos Lide Oar-Arteta
Vijay M. Shinde
Jara Garcia
Ágnes Szécsényi Yixiao Wang
Key challenge of today’s society: Supply energy and chemicals in a sustainable manner
The answer is not one unique solution, but many…
The energy challenge: roadmap
The energy challenge: roadmap
New ‘smart’ materials and reactors are needed: • Multifuntional • Based on abundant elements
The energy challenge: roadmap Our philosophy
C1 Catalysis
Direct activation of CH4 Fischer Tropsch Synthesis
Syngas to Methanol Hydroformylation
CatalysisE ngineeringCatalysisE ngineering
Methanol to olefins CO2 Hydrogenation
Methane Dehydroaromatization
CatalysisE ngineeringCatalysisE ngineering
Water Gas Shift
C1 Catalysis
CatalysisE ngineeringCatalysisE ngineering
Spectroscopy / Microscopy
In situ IR-Spectroscopy In situ EXAFS
0 1 2 3 4 5 60.0
0.1
0.2
0.3
0.4
0.5
|x(R
)| A-2
R (A)
CoS CoSK CoMoSK
In situ SAXS-WAXS Ultrafast spectroscopy
Photocatalysis Biomass valorization
Electro-Catalysis
CatalysisE ngineeringCatalysisE ngineering
FCC
New and old processes
Ethylene Oligomerization
Mixed Matrix Membranes Zeolite Membranes
Adsorptive based separations
CatalysisE ngineeringCatalysisE ngineering
Chiral Separations
Separation & Membrane development
Challenge the future
atalysis E ngineering
C http://cheme.nl/ce/
Jorge Gascon and Freek Kapteijn
C atalysis E ngineering
Schedule Time Beijerinckzaal Korvezeezaal
15:45 Start Start
15:50-16:00 MEP – Jan van Esch BEP – Erik Kelder
16:00-16:10 Break Break
16:10-16:20 OMI IRS
16:20-16:30 Break Break
16:30-16:40 MECS BOC
16:40-16:50 Break Break
16:50-17:00 PPE ASM
17:00-17:10 Break Break
17:10-17:20 OM TP
17:20-17:30 Break Break
17:30-17:40 CE BT
17:40-17:50
17:50-18:00 Poster market & drinks (atrium) 18:00-18:10
18:10-18:20
18:20-18:30