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Light-triggered thermal conductivity switching in azobenzene polymers
Jungwoo Shin
, Jaeuk Sung
, Minjee Kang
, Xu Xie
, Byeongdu Lee
, Kyung Min Lee
, Timothy J. White
,
Cecilia Leal
,
Nancy R. Sottos
,
Paul V. Braun
,
David G. Cahill
Materials Science and Engineering
Beckman Institute for Advanced Science and Technology
Materials Research Lab
Mechanical Science and Engineering
Aerospace Engineering
Chemistry
Micro and Nanotechnology Lab
Physics
Biomedical and Translational Sciences
Center for Advanced Study
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Keyphrases
Thermal Conductivity
100%
K(I)
100%
Low Thermal Conductivity
100%
Conformational Transition
100%
Light-triggered
100%
Conductivity Switching
100%
Azobenzene Polymer
100%
Synchrotron X-ray Scattering
50%
Time-domain Thermoreflectance
50%
In Situ
50%
High Thermal Conductivity
50%
Room Temperature
50%
UV Light
50%
Non-planar
50%
Light Illumination
50%
Polymer Properties
50%
Chain Alignment
50%
Thermal Energy
50%
Thermophysical Properties
50%
Light-responsive
50%
Green Light
50%
Effective Control
50%
In-situ Synchrotron
50%
Stacking Geometries
50%
Azobenzene Group
50%
Engineering
Thermal Conductivity
100%
Low Thermal Conductivity
100%
Time Domain
50%
High Thermal Conductivity
50%
Room Temperature
50%
Liquid Transition
50%
Thermal Energy
50%
Chemistry
Thermal Conductivity
100%
Azobenzene
100%
Conformational Transition
50%
Ambient Reaction Temperature
25%
X-Ray Scattering
25%
Illumination
25%
Light Green
25%
Physics
Thermal Conductivity
100%
Room Temperature
25%
X Ray Scattering
25%
Stacking
25%
Synchrotron
25%
Material Science
Thermal Conductivity
100%
Thermophysical Property
25%