Engineering of the thermodynamic properties of bilayer graphene by atomic plane rotations: the role of the out-of-plane phonons

Cocemasov, Alexandr I.; Nika, Denis L.; Balandin, Alexander A.

doi:10.1039/c5nr03579a

Cited by 57 publications

(78 citation statements)

References 57 publications

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“…Substituting the group velocity of three acoustic phonon branches v l =21.04 km/s, v t =14.9 km/s and v z =2.5 km/s [49] into above equations, we get the Debye temperature is 1035 K, close to the data in literature [45][46][47][48], and also the relationship of correction factor / In figure 2, the correction factor decreases rapidly with the increasing temperature and finally converges to 1 in high temperature region. Thus, in this paper, it is necessary, especially in low temperature region, to correct the simulation results related to temperature by taking the quantum effects into account.…”

Section: Quantum Correctionsupporting

confidence: 65%

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Networked nanoconstrictions: An effective route to tuning the thermal transport properties of graphene

Cao

Yao

2016

Carbon

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Section: Quantum Correctionsupporting

confidence: 65%

“…Since the Debye temperature of graphene is above 1000 K [45][46][47][48], when discussing the temperature properties of thermal resistance in low temperature region, it is necessary to add…”

Section: Quantum Correctionmentioning

confidence: 99%

Networked nanoconstrictions: An effective route to tuning the thermal transport properties of graphene

Cao

Yao

2016

Carbon

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“…The rapid progress of nanotechnology achieved in last two decades shows that phonon thermal conduction in nanoscale, such as thin films and nanowires, dramatically differ from that in their bulk counterparts and are strongly suppressed due to the increase of phonon-boundary scatterings, changes in phonon group dispersion and phonon density of states [17][18][19]. These phenomena lead to the possibility of phonon control and heat management in nanoscale, and trigger the recent applications of nanomaterials in thermoelectrics and thermal insulator materials.…”

Section: Introductionmentioning

confidence: 99%

Phonon thermal conduction in novel 2D materials

Chen

2016

J. Phys.: Condens. Matter

101

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Recently, there have been increasing interests in phonon thermal transport in low dimensional materials, due to the crucial importance for dissipating and managing heat in micro and nano electronic devices. Significant progresses have been achieved for one-dimensional (1D) systems both theoretically and experimentally. However, the study of heat conduction in two-dimensional (2D) systems is still in its infancy due to the limited availability of 2D materials and the technical challenges in fabricating suspended samples suitable for thermal measurements. In this review, we outline different experimental techniques and theoretical approaches for phonon thermal transport in 2D materials, discuss the problems and challenges in phonon thermal transport measurements and provide comparison between existing experimental data. Special focus will be given to the effects of the size, dimensionality, anisotropy and mode contributions in the novel 2D systems including graphene, boron nitride, MoS 2 , black phosphorous, silicene etc.

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“…Starting from a two-temperature model [41] adapted to the present situation by introducing the electronic [42,43] as well as the phonon density of states [44] of bilayer graphene, we find that the measured enhancement of λ e-ph is sufficient to reproduce both the reduction in peak electronic temperature and the observed decrease in cooling time (green lines in Fig. 4c and d, respectively).…”

Section: Tr-arpes Datamentioning

confidence: 93%

Enhanced electron-phonon coupling in graphene with periodically distorted lattice

et al. 2017

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Electron-phonon coupling directly determines the stability of cooperative order in solids, including superconductivity, charge and spin density waves. Therefore, the ability to enhance or reduce electron-phonon coupling by optical driving may open up new possibilities to steer materials' functionalities, potentially at high speeds. Here we explore the response of bilayer graphene to dynamical modulation of the lattice, achieved by driving optically-active in-plane bond stretching vibrations with femtosecond mid-infrared pulses. The driven state is studied by two different ultrafast spectroscopic techniques. Firstly, TeraHertz time-domain spectroscopy reveals that the Drude scattering rate decreases upon driving. Secondly, the relaxation rate of hot quasi-particles, as measured by time-and angle-resolved photoemission spectroscopy, increases. These two independent observations are quantitatively consistent with one another and can be explained by a transient three-fold enhancement of the electron-phonon coupling constant. The findings reported here provide useful perspective for related experiments, which reported the enhancement of superconductivity in alkali-doped fullerites when a similar phonon mode was driven.

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Engineering of the thermodynamic properties of bilayer graphene by atomic plane rotations: the role of the out-of-plane phonons

Cited by 57 publications

References 57 publications

Networked nanoconstrictions: An effective route to tuning the thermal transport properties of graphene

Networked nanoconstrictions: An effective route to tuning the thermal transport properties of graphene

Phonon thermal conduction in novel 2D materials

Enhanced electron-phonon coupling in graphene with periodically distorted lattice

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