Light-triggered thermal conductivity switching in azobenzene polymers

Shin, Jungwoo; Sung, Jaeuk; Kang, Minjee; Xie, Xu; Lee, Byeongdu; Lee, Kyung Min; White, Timothy J.; Sottos, Nancy R.; Braun, Paul V.; Cahill, David G.

doi:10.1073/pnas.1817082116

Cited by 107 publications

(112 citation statements)

References 43 publications

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“…The associated references are as follows. nCB ( 31 ); VO 2 ( 26 ); K, Zn, Cd, and Hg ( 32 ); c-Se ( 33 ); Ni-Mn-In alloy ( 13 ); C 6 H 14 ( 34 ); Sn, In, and LiNO 3 ( 15 ); C/C 16 H 34 composite ( 17 ); Ge 2 Sb 2 Te 5 ( 27 ); azobenzene polymers ( 14 ). ( D ) Multiple on/off thermal cycles of nanofiber #2 around the phase transition temperature of 440 K.…”

Section: Resultsmentioning

confidence: 99%

“…Through thermally induced martensitic transition, a ~1.5× thermal switching ratio was observed in Ni-Mn-In alloys ( 13 ). Recently, a 3.5× thermal switching ratio has been achieved in light-responsive azobenzene polymers by modulation of chain alignment, which results from the conformational transition between nonplanar (cis) and planar (trans) azobenzene groups under green and ultraviolet light illumination ( 14 ).…”

Section: Introductionmentioning

confidence: 99%

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High-contrast and reversible polymer thermal regulator by structural phase transition

et al. 2019

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In comparison with the advancement of switchable, nonlinear, and active components in electronics, solid-state thermal components for actively controlling heat flow have been extremely rare. We demonstrate a high-contrast and reversible polymer thermal regulator based on the structural phase transition in crystalline polyethylene nanofibers. This structural phase transition represents a dramatic change in morphology from a highly ordered all-trans conformation to a combined trans and gauche conformation with rotational disorder, leading to an abrupt change in phonon transport along the molecular chains. For five nanofiber samples measured here, we observe an average thermal switching ratio of ~8× and maximum switching ratio of ~10×, which occurs in a narrow temperature range of 10 K across the structural phase transition. To the best of our knowledge, the ~10× switching ratio exceeds any reported experimental values for solid-solid and solid-liquid phase transitions of materials. There is no thermal hysteresis observed upon heating/cooling cycles.

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Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

High-contrast and reversible polymer thermal regulator by structural phase transition

et al. 2019

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“…As an example, Shin et al. [ 162 ] reported for azobenzene polymer a change of structure from a planar ( trans ) to a nonplanar ( cis ) in response to UV light stimuli. The whole switching process is illustrated in Figure .…”

Section: Thermal Switchesmentioning

confidence: 99%

Solid‐State Thermal Control Devices

Swoboda

Klinar

Yalamarthy

et al. 2020

Adv Elect Materials

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Over the past decade, solid‐state thermal control devices have emerged as potential candidates for enhanced thermal management and storage. They distinguish themselves from traditional passive thermal management devices in that their thermal properties have sharp, nonlinear dependencies on direction and operating temperature, and can lead to more efficient circuits and energy conversion systems than what is possible today. They also distinguish themselves from traditional active thermal management devices (e.g., fans) in that they have no moving parts and are compact and reliable. In this article, the recent progress in the four broad categories of solid‐state thermal control devices that are under active research is reviewed: diodes, switches, regulators, and transistors. For each class of device, the operation principle, material choices, as well as metrics to compare and contrast performance are discussed. New architectures that are explored theoretically, but not experimentally demonstrated, are also discussed.

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“…Various types of molecular photoswitches, such as stilbene, [8] azobenzene, [9] spiropyran, [10] diarylethene, [2d, 11] coumarin [12] or fulgide, [12] have been incorporated into the main or side chain of the polymer to achieve reversible photoresponsive polymers [13] . Due to the light‐induced molecular changes, these molecular switches can cause a structural reconfiguration or change in the properties of polymer chains, which leads to fast, precise and remote control of various macroscopic properties, such as shape, [2d] wettability, [10b] optical properties, [14] adhesion, [15] solubility, [16] conductivity, [14, 17] and so on. Compared to the side chain polymer, the main‐chain polymer made up of photoswitchable repeating units has improved thermal and mechanical properties that provide better photomechanical response [18] .…”

Section: Figurementioning

confidence: 99%

Photoinduced Strain‐Assisted Synthesis of a Stiff‐Stilbene Polymer by Ring‐Opening Metathesis Polymerization

Krishnan

Xue

Xiong

et al. 2020

Chemistry A European J

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Developing an ovel strategyt os ynthesize photoresponsive polymers is of significance owing to their potential applications.W er eport ap hotoinduced strain-assisted synthesis of main-chainstiff-stilbene polymersb y using ring-opening metathesis polymerization (ROMP), activatingam acrocyclic p-bond connected to as tiff-stilbene photoswitch through al inker.S ince the linker acts as an external constraint, the photoisomerization to the E-form leads to the stiff-stilbene being strained and thus reactive to ROMP.T he photoisomerization of Z-form to E-form was investigated using time-dependent NMRs tudies and UV/ Vis spectroscopy.T he DFT calculation showedt hat the Eform was less stable due to al ack of planarity.B yt he internal strain developed due to the linker constraint throughp hotoisomerization, the E-formu nderwent ROMP by as econd generation Grubbs catalyst. In contrast, Zform did not undergo polymerization under similar conditions. The MALDI-TOF spectrumo fE-form after polymerization showedt he presence of oligomers of > 5.2 kDa.

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Light-triggered thermal conductivity switching in azobenzene polymers

Cited by 107 publications

References 43 publications

High-contrast and reversible polymer thermal regulator by structural phase transition

High-contrast and reversible polymer thermal regulator by structural phase transition

Solid‐State Thermal Control Devices

Photoinduced Strain‐Assisted Synthesis of a Stiff‐Stilbene Polymer by Ring‐Opening Metathesis Polymerization

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