Hot carriers in epitaxial graphene sheets with and without hydrogen intercalation: role of substrate coupling

Liu, Fan Hung; Lo, Shun‐Tsung; Chuang, Chiashain; Woo, Tak Pong; Lee, Hsin Yen; Liu, Chieh Wen; Liu, Chieh I.; Huang, Lung I.; Liu, Cheng-Hua; Yang, Yue; Chang, Chih Yuan S.; Li, Lain‐Jong; Mende, Patrick; Feenstra, R. M.; Elmquist, Randolph E.; Liang, Chi‐Te

doi:10.1039/c4nr02980a

Cited by 4 publications

(2 citation statements)

References 52 publications

(60 reference statements)

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“…Indeed the calculations show that in comparison to EMLG, QFMLG is a very flat graphene layer with a very homogeneous electronic density at the interface. This significant difference translates into a dramatic improvement of transistors after hydrogen intercalation [46,47]. It suggests that the adsorption distance is a valid parameter to assess the ideality of graphene.…”

Section: 50å) and Thus Indicates The Absence Of Interactions Besidmentioning

confidence: 99%

Approaching Truly Freestanding Graphene: The Structure of Hydrogen-Intercalated Graphene on6H−SiC(0001)

et al. 2015

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We measure the adsorption height of hydrogen-intercalated quasifreestanding monolayer graphene on the (0001) face of 6H silicon carbide by the normal incidence x-ray standing wave technique. A density functional calculation for the full (6√3×6√3)-R30° unit cell, based on a van der Waals corrected exchange correlation functional, finds a purely physisorptive adsorption height in excellent agreement with experiments, a very low buckling of the graphene layer, a very homogeneous electron density at the interface, and the lowest known adsorption energy per atom for graphene on any substrate. A structural comparison to other graphenes suggests that hydrogen-intercalated graphene on 6H-SiC(0001) approaches ideal graphene.

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Section: 50å) and Thus Indicates The Absence Of Interactions Besidmentioning

confidence: 99%

Approaching Truly Freestanding Graphene: The Structure of Hydrogen-Intercalated Graphene on6H−SiC(0001)

et al. 2015

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“…In general graphene systems, ≈ 3 suggests the supercollision cooling mechanism in disordered systems [13,18,33] and ≈ 4 suggests the two-dimensional acoustic phonon cooling processes in clean systems [34,35]. Particularly, ≈ 2, the heat diffusion described by the Wiedemann-Franz law, was found in graphene on bottom h-BN substrate systems, where bottom h-BN substrate acts as a thermal conduction layer, effectively reducing the electron-phonon coupling [14][15][16].…”

Section: Resultsmentioning

confidence: 99%

Hot Carriers in CVD-Grown Graphene Device with a Top h-BN Layer

Chuang

Mineharu

Matsumoto

et al. 2018

Journal of Nanomaterials

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We investigate the energy relaxation of hot carriers in a CVD-grown graphene device with a top h-BN layer by driving the devices into the nonequilibrium regime. By using the magnetic field dependent conductance fluctuations of our graphene device as a self-thermometer, we can determine the effective carrier temperature e at various driving currents while keeping the lattice temperature L fixed. Interestingly, it is found that e is proportional to I, indicating little electron-phonon scattering in our device. Furthermore the average rate of energy loss per carrier e is proportional to ( e 2 − L 2 ), suggesting the heat diffusion rather than acoustic phonon processes in our system. The long energy relaxation times due to the weak electron-phonon coupling in CVD graphene capped with h-BN layer as well as in exfoliated multilayer graphene can find applications in hot carrier graphene-based devices.

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The impact of partial H intercalation on the quasi-free-standing properties of graphene on SiC(0001)

Szary

El-Ahmar

Ciuk

2021

Applied Surface Science

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Hot carriers in epitaxial graphene sheets with and without hydrogen intercalation: role of substrate coupling

Cited by 4 publications

References 52 publications

Approaching Truly Freestanding Graphene: The Structure of Hydrogen-Intercalated Graphene on6H−SiC(0001)

Approaching Truly Freestanding Graphene: The Structure of Hydrogen-Intercalated Graphene on6H−SiC(0001)

Hot Carriers in CVD-Grown Graphene Device with a Top h-BN Layer

The impact of partial H intercalation on the quasi-free-standing properties of graphene on SiC(0001)

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