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|a Lenert, Andrej
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|a Massachusetts Institute of Technology. Department of Mechanical Engineering
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|a Bierman, David Matthew
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|a De La Ossa, Matthew F.
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|a Wang, Evelyn
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|a Kats, Mikhail A.
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|a Zhou, You
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|a Zhang, Shuyan
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|a Ramanathan, Shriram
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|a Capasso, Federico
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|a Bierman, David Matthew
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|a De La Ossa, Matthew F.
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|a Wang, Evelyn
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|a Radiative Thermal Runaway Due to Negative-Differential Thermal Emission Across a Solid-Solid Phase Transition
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|b American Physical Society,
|c 2018-08-13T19:06:02Z.
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|z Get fulltext
|u http://hdl.handle.net/1721.1/117341
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|a Thermal runaway occurs when a rise in system temperature results in heat-generation rates exceeding dissipation rates. Here, we demonstrate that thermal runaway occurs in radiative (photon) systems given a sufficient level of negative-differential thermal emission. By exploiting the insulator-to-metal phase transition of vanadium dioxide, we show that a small increase in heat generation (e.g., 10nW/mm[superscript 2]) results in a large change in surface temperature (e.g., ∼35 K), as the thermal emitter switches from high emittance to low emittance. While thermal runaway is typically associated with catastrophic failure mechanisms, detailed understanding and control of this phenomenon may give rise to new opportunities in infrared sensing, camouflage, and rectification.
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|a Article
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|t Physical Review Applied
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