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Thermoelectric effects in quantum systems
S. Volosheniuk
QN/van der Zant Lab
Research output
:
Thesis
›
Dissertation (TU Delft)
Overview
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Dive into the research topics of 'Thermoelectric effects in quantum systems'. Together they form a unique fingerprint.
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Keyphrases
Thermoelectric
100%
Thermoelectric Effect
100%
Thermometry
100%
Quantum System
100%
Superconductor
100%
Thermocurrent
100%
Power Factor
100%
Magnetic Field
100%
Nanoscale Devices
50%
Low Temperature
50%
Heat Engine
50%
Organic Molecules
50%
Optimal Load
50%
Maximum Power Output
50%
Spin Entropy
50%
Physical Phenomena
50%
General Introduction
50%
Normal Metal
50%
Fold Increase
50%
Seebeck Coefficient
50%
Particle Exchange
50%
Interlocking Mechanism
50%
Load Value
50%
Phase Transition Point
50%
Differential Conductance
50%
CrSBr
50%
Flakes
50%
All-organic
50%
Heat Waste
50%
Quantum Effects
50%
Concise Description
50%
Break Junction
50%
Kondo
50%
Superconducting Junction
50%
Waste Problem
50%
Follow-up Experiment
50%
Single Molecule
50%
Thermoelectric Properties
50%
INIS
quantum systems
100%
devices
100%
magnetic fields
66%
superconductors
66%
power factor
66%
molecules
66%
exchange (heat)
33%
power
33%
nanostructures
33%
applications
33%
junctions
33%
values
33%
particles
33%
heat engines
33%
waste heat
33%
processing
33%
metals
33%
superconducting junctions
33%
optimization
33%
implementation
33%
output
33%
entropy
33%
spin
33%
architecture
33%
thermoelectric properties
33%
investigations
33%
tuning
33%
phase transformations
33%
data
33%
Material Science
Devices
100%
Thermoelectrics
100%
Superconducting Material
66%
Temperature
66%
Metal
33%
Particle
33%
Biochemistry, Genetics and Molecular Biology
Heat Exchange
50%
Spin
50%