Nanomaterials for energy conversion and energy harvesting · 2015-09-14 · Nanomaterials for...
Transcript of Nanomaterials for energy conversion and energy harvesting · 2015-09-14 · Nanomaterials for...
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Centrum für Angewandte Nanotechnologie (CAN) GmbH
Nanomaterials for energy
conversion and energy harvesting
Dr. Jan Dorn
CAN GmbH, Hamburg
NCCR MUST Workshop
13.06.2012
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Outline
Centrum für Angewandte Nanotechnologie (CAN) GmbH
1. Company Profile
2. CAN GmbH activities in the field of nanotechnology
a) Synthetic aspects
b) Particle Systems
3. Application of nanoparticles in 3rd generation photovoltaics
4. Summary
5. Outlook
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CAN GmbH
Centrum für Angewandte Nanotechnologie (CAN) GmbH
Business Model: Public Private Partnership (PPP)
Founded: November 2005
Location: Hamburg
Staff: 30 (today)
Vol. of Sales: 1.5Mio €
Associates: Verein zur Förderung der Nanotechnologie e.V. (65,2 %)
City of Hamburg (24,8 %)
University of Hamburg (10 %)
Chairman of the board: Prof. Dr. Klaus-Peter Wittern
CTO: Prof. Dr. Horst Weller
COO/CFO : Dr. Frank Schröder-Oeynhausen
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CAN GmbH: Overview
Centrum für Angewandte Nanotechnologie (CAN) GmbH
Business Model:
• „Technology Transfer in the Lab“
– Standardization
– Upscaling
• Contract Research for Industry
• Third party funded research
• Sale of selected nanoparticle species (side offs)
• Technology: Nanoparticle systems
• Target Market: Life Science, Optoelectronics, …
University
Research CAN GmbH
Industry
Developement
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CAN GmbH: Fields of expertise
Centrum für Angewandte Nanotechnologie (CAN) GmbH
Home & Personal Care
Nanoparticle Synthesis
Life Science Energy
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Centrum für Angewandte Nanotechnologie (CAN) GmbH Centrum für Angewandte Nanotechnologie (CAN) GmbH 6
Nanoparticles @ CAN: CANdot® Series
Inorganic Nanoparticles
• Nanoparticles consists of an inorganic core (metal, semiconductor, insulator,
magnetic)
• Particle synthesis in colloidal solution (2-150 nm)
• In a 5 nm particle ~ 20% of the atoms are at the surface!
• (Post-synthetic) surface modification allows various applications
5 nm
TEM-Aufnahme
eines Nanokristalls
5 nm
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• Universal applicability
• Well established
• Wide temperature range
• flexible reaction time
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CANdot® Batch Synthesis
Advantages
Disadvantages
• Limited reproducibility
• Small batch size (typically 100 mg)
• Time and cost consuming
• High chemical consumption
• “feeling” needed
Centrum für Angewandte Nanotechnologie (CAN) GmbH
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• Higher production capacity 10 g/day
• High reproducibility
• Efficient use of chemicals
• Increased lab safety!
• Lower costs through automatization
• Screening and optimization
• Parallelization
• expensive equipment
• development of suitable synthetic route
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CANdot® Continuos Flow Synthesis
Advantages
Disadvantages
Centrum für Angewandte Nanotechnologie (CAN) GmbH
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• II-VI-Semiconductors
• Emission maxima 500 to 625 nm
• High quantum yield > 40%
• High significance (0,1%)
• Polar and non-polar dispersions
• Improved shell structure
• Sale
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CANdot® Series A: Core/Shell Quantum Dots
Properties
Applications
• Biomedical markers
• QD LED and White light-LEDs
• Absorber in Solar Cells
Centrum für Angewandte Nanotechnologie (CAN) GmbH
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CANdot® Series Outlook CdSe/CdS dot-rods
Centrum für Angewandte Nanotechnologie (CAN) GmbH
• Advanced morphologies in continuous
flow
• Dot-in-Rod,
• Rod-in-Rod,
• Emission maxima 500 to 625 nm
• High quantum yield > 80%
• Long fluorescence lifetime
• Polar and non-polar dispersions
• Improved shell structure
• Biomarkers
Applications
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• Bulk bandgap 0,37eV
• Band gap tunability up to 1,4 eV
• IR absorption max: 900 to ~1600 nm
• No passivation shell needed
• High reproducibility due to
continuous flow synthesis
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CANdot® Series C: PbS
Properties
Applications
• Absorber in solar cells
• IR Photodiodes
• IR LED
Centrum für Angewandte Nanotechnologie (CAN) GmbH
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Center for Applied Nanotechnology (CAN) GmbH 12
Morphological diversity of PbS
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• Size 10 to 120 nm
• Plasmonic resonance tuning (515-
620nm)
• Spheres or rodlike morphologies
• Dispersable in polar and non-
polar solvents
• Upscaling in progress
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CANdot® Series G: Gold nanoparticles
Properties
Applications
• Biomarker
• Light management in solar cells
Centrum für Angewandte Nanotechnologie (CAN) GmbH
Plasmonic
Structures
Active Layer
Metal electrode
TCO-Electrode
v
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CANdot® Series X: Rare earth doped nanoparticles
Properties
Applications
• green: LaPO4:X, yellow: BaSO4:X,
red: YVO4:X
• Rare earth metals
(X = Eu, Ce, Dy,…)
• Excitation with UV light
• Colorless and transparent under
visible light
• Chemical and temperature stability
(Up to 600°C)
• UV-Converter
• Security label
Centrum für Angewandte Nanotechnologie (CAN) GmbH
Active Layer
Window electrode v
UV
light
Visible light
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CAN GmbH: Fields of expertise
Centrum für Angewandte Nanotechnologie (CAN) GmbH
Home & Personal Care
Synthesis
Life Science Energy
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Basic PV Preparation and Characterization
• Glovebox system
• Preparation and
characterization under
inert gas
• SEM incl. Focused Ion
Beam
• HR-TEM
• X-ray characterization
(incl. synchrotron
radiation @ DESY)
• Optical spectroscopy
Centrum für Angewandte Nanotechnologie (CAN) GmbH
“Record cell”
ITO/ZnO/PbS:EDT/Au
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Nanocrystal-Polymer Hybrid Solar Cells
Advantages
• Active layer via self-assembly
Disadvantages
• Morphology control
• HTL-Polymer
• High exciton binding energies
Quantum Dot-Sensitized Cells
Advantage:
• Increased IR-sensitivity (PbS-QDs)
Disadvantage:
• High QD-coverage of TiO2 difficult
• Surface passivation of NP against
reactive electrolyte
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Semiconductor Nanocrystals in Photovoltaics
Centrum für Angewandte Nanotechnologie (CAN) GmbH
2002: 1,7% CdSe Nanorod
Science 2002, 295, 5564, 2425-2427
20 10: 3,1% CdSe Tetrapods
Nano Lett. 2010, 10, 1, 239–242
Metal
Electrode
Polymer
TCO-Electrode
Metal Electrolyte
2011: 12,3% Co II/III electrolyte
Science 2011,334, 6056, 629-634
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Semiconductor Nanocrystal Photovoltaics
Centrum für Angewandte Nanotechnologie (CAN) GmbH
Semiconductor
Nanocrystals
TCO
Electrode
Oxide Semiconductor
TCO
Electrode
Oxide Semiconductor
Solution
• Thin film solar cells
• Compact µ-crystalline film
• CuInGa(S,Se)4 –NP as Precursor
• ηrec = 7-8%
„All-Nanocrystal“ Solar Cells
• Nanoparticular film
• Chalcogenides (PbS, PbSe)
Absorber Layer
+ Additives
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Third Generation Nanocrystal Photovoltaics
Centrum für Angewandte Nanotechnologie (CAN) GmbH
TCO
Electrode
Oxide Semiconductor
• Solution processing
• Band gap tuning by nanoparticle
size (PbS-nanocrystals)
• Good charge separation (high εeff)
• p-n-Junction with distinct layers
• High carrier mobility
• Reduce trap states
• Direct film morphology
• Surface chemistry control!!!
• Screening with continuous
flow synthesis
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Multiple Exciton Generation (MEG)
Centrum für Angewandte Nanotechnologie (CAN) GmbH
• Two excitons from one photon
• Enhanced in quantified systems
• need for nanoparticles
• Dependent on DOS (less “cooling”
channels)
• Single Junction Limit: η=33%
• Multiple Exciton Generation
(MEG) theoretically allows
η=44%
hν hν
Thermal
Cooling
MEG
M. Beard, A. Nozik, Science (2011)
334, 6062 ,1530-1533
External Quantum Efficiency
114 %
in a PV device (ITO/ZnO/PbSe/Au)
CB
VB
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Enhancing MEG
Centrum für Angewandte Nanotechnologie (CAN) GmbH
• MEG-Threshold at > 3Eg for PbSe
nanocrystals (dots)
• MEG-Threshold at ~ 2,2 Eg for
PbSe nanorods
• Morphology screening via
continuous flow synthesis
• Various MEG-mechanisms
• Strong coupling with inter-NP-
distance <1 nm
• Surface chemistry control
Trinh et al. Nature Photonics 2012, 6, 316-321
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Center for Applied Nanotechnology (CAN) GmbH 22
Morphological diversity of PbS
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Summary
Centrum für Angewandte Nanotechnologie (CAN) GmbH
• Size matters!!!
• Nanomaterials can have a significant impact on photovoltaics
• If size matters SURFACE MATTERS!!
• For 3rd generation photovoltaic systems based on nanotechnology it
surface chemistry control is of greatest importance!
• Continuous flow synthesis is a promising tool for nanomaterials synthesis
2008 ηrec = 1,1 % ACS Nano 2008, 2, 5, 833–840
2011 ηrec = 6,0% Nature Materials 2011, 10, 765–771
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Outlook
Centrum für Angewandte Nanotechnologie (CAN) GmbH
• New ligand systems
• New material systems (e.g. PbTe or
Semiconductor Alloys)
• Improved material morphologies like
plateletts/sheets
• Improved device concepts
Talapin, et al., Science, 324, 1417 (2009).
Weller, et al. Science, 329, 550 (2010)
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Center for Applied Nanotechnology (CAN) GmbH 25
Thank you for your attention!
www.can-hamburg.de