Out-of-plane heat transfer in van der Waals stacks through electron–hyperbolic phonon coupling

Tielrooij, Klaas‐Jan; Hesp, Niels C. H.; Principi, Alessandro; Lundeberg, Mark B.; Pogna, Eva A. A.; Banszerus, Luca; Mics, Zoltán; Massicotte, Mathieu; Schmidt, Peter; Davydovskaya, Diana; Purdie, David G.; Goykhman, Ilya; Soavi, Giancarlo; Lombardo, Antonio; Watanabe, Kenji; Taniguchi, Takashi; Bonn, Mischa; Turchinovich, Dmitry; Stampfer, Christoph; Ferrari, Andrea C.; Cerullo, Giulio; Polini, Marco; Koppens, Frank H. L.

doi:10.1038/s41565-017-0008-8

Cited by 143 publications

(160 citation statements)

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“…Faster relaxation of carriers in graphene-hBN heterostructures has also recently been observed through photoconductivity measurements and attributed to hyperbolic phonon coupling. 39 See supplementary material for the following sections: S1-Lateral heat transport, S2-hBN thickness dependence and baseline of ∆R(t)/R 0 curves, S3-Details of the two temperature model and reflectivity calculation, and S4-Evolution of the electronic and phonon temperature. …”

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confidence: 99%

Ultrafast relaxation of hot phonons in graphene-hBN heterostructures

et al. 2017

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Fast carrier cooling is important for high power graphene based devices. Strongly Coupled Optical Phonons (SCOPs) play a major role in the relaxation of photoexcited carriers in graphene. Heterostructures of graphene and hexagonal boron nitride (hBN) have shown exceptional mobility and high saturation current, which makes them ideal for applications, but the effect of the hBN substrate on carrier cooling mechanisms is not understood.We track the cooling of hot photo-excited carriers in graphene-hBN heterostructures using ultrafast pump-probe spectroscopy. We find that the carriers cool down four times faster in the case of graphene on hBN than on a silicon oxide substrate thus overcoming the hot phonon (HP) bottleneck that plagues cooling in graphene devices.Graphene heterostructures have garnered a lot of interest in the last decade 1 . Recently developed fabrication techniques have made it possible to engineer devices with better transport, optical and thermal properties 2,3 . Hexagonal boron nitride (hBN) is a layered material with a hexagonal lattice similar to graphene with a lattice constant that is about 1.8% larger 3 . It is an insulator with a wide band gap and high dielectric constant making it a good candidate as a substrate for graphene devices. Heterostructures of graphene and hBN show much higher mobility compared to those using SiO2 as a substrate 2-4 . This improvement is a result of the hBN substrate being free of charged impurities and displacing the graphene away from the impurities in the SiO2 substrate 4 .As electronic devices continue to scale down in size and push power capabilities, heat management has become a critical issue. Relaxation dynamics of photoexcited (PE) carriers has been studied extensively by many groups using variety of techniques such as photocurrent measurement, Raman time resolved Raman spectroscopy, transport measurements and ultrafast pump-probe spectroscopy 5-7 etc. Upon photoexcitation (with an ultrafast pulse for example), electrons and holes are excited, into a highly non-thermal system. This bath of carriers exchanges energy among themselves through coulombic interactions and thermalize into a hot (~1000's K) Fermi-Dirac population

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Ultrafast relaxation of hot phonons in graphene-hBN heterostructures

et al. 2017

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“…In contrast to this well‐known configuration, graphene has no bandgap, however, the threshold energy is now the RS band energy μ c − μ v ≲ ℏΩ II . For unbiased graphene, out‐of‐equilibrium electronic distribution can be transiently created by optical pumping and have been observed to relax on sub‐ps timescales by optical pump–probe techniques . In the next section, we show that electrical pumping of charges occurs similarly in high mobility graphene under large bias and leads to a favorable situation for HPhP electroluminescence cooling.…”

Section: Coupling Between Graphene and Hyperbolic Materialsmentioning

confidence: 81%

“…From a microscopic point of view, this mismatch is related to the small density of electromagnetic modes within the light cone as compared to that of the electron gas at high temperature. This issue has been overcame in recent studies, by using a so‐called hyperbolic substrate. Within the Reststrahlen (RS) bands (which roughly corresponds to the optical phonon modes) hyperbolic materials sustain long‐distance propagating hyperbolic phonon‐polariton (HPhP) modes that can carry a large momentum .…”

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confidence: 99%

Hyperbolic Phonon Polariton Electroluminescence as an Electronic Cooling Pathway

Baudin

Voisin

Plaçais

2019

Adv Funct Materials

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Engineering of the cooling mechanism is of primary importance for the development of nanoelectronics. While radiation cooling is rather inefficient in current electronic devices, the strong anisotropy of 2D materials allows for enhanced efficiency because their hyperbolic electromagnetic dispersion near phonon resonances allows them to sustain much larger (≈105) number of radiating channels. In this review, radiation cooling in 2D materials is addressed. The hyperbolic dispersion of electromagnetic waves is presented, and how the spontaneous fluctuations in current in a 2D electronic channel can radiate thermal energy in its hyperbolic surrounding medium is described. Both the regime of thermal current fluctuations and out‐of‐equilibrium current fluctuations can be described within the same framework leading to superPlanckian thermal emission and electroluminescent cooling. A recent experimental investigation on graphene‐on‐hBN transistors using electronic noise thermometry is discussed. In high mobility semimetal‐like graphene at large bias, a steady‐state out‐of‐equilibrium situation is caused by Zener tunneling of electrons, opening a route for electroluminescence of hyperbolic electromagnetic modes. Electroluminescent cooling is particularly prominent once the Zener tunneling regime is reached: observed cooling powers are nine orders of magnitude larger than in conventional LEDs.

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“…Thus, the hBN/graphene heterostructure provides a perfect research platform for nanoscale heat transfer of van der Waals heterostructures. Recently, Koppens et al [6] and Placais et al [7] independently verified highly surprisingly fast heat flow within van der Waals heterojunctions through different solid experiments, which made great progress in the study of nanoscale thermal transport.…”

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confidence: 99%

“…Koppens et al [6] identified the picosecond relaxation times and dynamics of the hyperbolic cooling process in graphene heterostructures. In order to measure the ultrafast carrier dynamics of hBN-encapsulated graphene (illustrated in Fig.…”

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confidence: 99%