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Photovoltaic performance of ultrasmall PbSe quantum dots
Wanli Ma
,
Sarah L. Swisher
, Trevor Ewers
, Jesse Engel
,
Vivian E. Ferry
, Harry A. Atwater
, A. Paul Alivisatos
Electrical and Computer Engineering
Chemical Engineering and Materials Science
Research output
:
Contribution to journal
›
Article
›
peer-review
225
Scopus citations
Overview
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Keyphrases
Aluminium Structures
33%
Band Gap
33%
Cavity Mode
33%
Coherent Interference
33%
Collection Efficiency
33%
Device Architecture
33%
Device Efficiency
33%
Efficiency Improvement
33%
Exciton Energy
33%
External Quantum Efficiency
33%
Fabry
33%
Growth Temperature
33%
High Open-circuit Voltage
33%
Large Particle
33%
Nanocrystal Size
33%
Nanoparticle Diameter
33%
Nanoparticle Size
33%
Open-circuit Voltage
33%
Optical Model
33%
Overall Efficiency
33%
PbS Nanoparticles
33%
PbS Quantum Dots
100%
PbSe
100%
PbSe Nanocrystals
33%
Peak Performance
33%
PEDOT
33%
Photocurrent
66%
Photovoltaic Performance
100%
Quantum Dots Size
33%
Recombination
33%
Reduced Absorption
33%
Schottky Solar Cell
33%
Simple Device
33%
Synthesis Methods
33%
Ultrasmall
100%
Engineering
Aluminum Structure
50%
Band Gap
50%
Collection Efficiency
50%
External Quantum Efficiency
50%
Growth Temperature
50%
Nanoparticles
100%
Open Circuit Voltage
100%
Photocurrent
100%
Photovoltaic Performance
100%
Quantum Dot
100%
Solar Cell
50%
Synthesis Method
50%
Thin Films
50%
Material Science
Aluminum
50%
Device Efficiency
50%
Electronic Circuit
100%
Indium Tin Oxide
50%
Nanoparticle
100%
Photovoltaic Performance
100%
Quantum Dot
100%
Solar Cell
50%
Thin Films
50%
Physics
Energy Gaps (Solid State)
50%
Exciton
50%
Larger Particle
50%
Nanoparticle
100%
Open Circuit Voltage
100%
Photoelectric Emission
100%
Quantum Dot
100%
Solar Cell
50%
Thin Films
50%
Chemical Engineering
Film
50%
Growth Temperature
50%
Nanoparticle
100%