First-Principles Study of the Phonon Lifetime and Low Lattice Thermal Conductivity of Monolayer γ-GeSe: A Comparative Study

Wang, Bowen; Yan, Xing; Cui, Xiangyue; Cai, Yongqing

doi:10.1021/acsanm.2c03476

Cited by 10 publications

(9 citation statements)

References 59 publications

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“…The phonon dispersion, thermal transport coefficients, and lattice thermal conductivity are calculated using the Hiphive 41 , BoltzTraP2 42 , and the ShengBTE 43 codes, respectively. This sophisticated method has been used to analyze the transport characteristics of numerous materials 44 – 46 . As inputs to ShengBTE, the 2nd and 3rd-order force constants are computed using a 3 × 3 × 1 supercell.…”

Section: Computational Detailsmentioning

confidence: 99%

Colossal figure of merit and compelling HER catalytic activity of holey graphyne

Sajjad

Nair

Samad

et al. 2023

Sci Rep

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Herein, we have conducted a comprehensive study to uncover the thermal transport properties and hydrogen evolution reaction catalytic activity of recently synthesized holey graphyne. Our findings disclose that holey graphyne has a direct bandgap of 1.00 eV using the HSE06 exchange–correlation functional. The absence of imaginary phonon frequencies in the phonon dispersion ensures its dynamic stability. The formation energy of holey graphyne turns out to be − 8.46 eV/atom, comparable to graphene (− 9.22 eV/atom) and h-BN (− 8.80 eV/atom). At 300 K, the Seebeck coefficient is as high as 700 μV/K at a carrier concentration of 1 × 1010 cm-2. The predicted room temperature lattice thermal conductivity (κl) of 29.3 W/mK is substantially lower than graphene (3000 W/mK) and fourfold smaller than C3N (128 W/mK). At around 335 nm thickness, the room temperature κl suppresses by 25%. The calculated p-type figure of merit (ZT) reaches a maximum of 1.50 at 300 K, higher than that of holey graphene (ZT = 1.13), γ-graphyne (ZT = 0.48), and pristine graphene (ZT = 0.55 × 10–3). It further scales up to 3.36 at 600 K. Such colossal ZT values make holey graphyne an appealing p-type thermoelectric material. Besides that, holey graphyne is a potential HER catalyst with a low overpotential of 0.20 eV, which further reduces to 0.03 eV at 2% compressive strain.

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Section: Computational Detailsmentioning

confidence: 99%

Colossal figure of merit and compelling HER catalytic activity of holey graphyne

Sajjad

Nair

Samad

et al. 2023

Sci Rep

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show abstract

“…Conversely, is proportional to when the optical phonon contribution to the thermal conduction is minimal. [33,62] Owing to these constraints, E and show a positive correlation across a broad spectrum of materials. This relationship follows the proportionality as depicted in Fig.…”

Section: Resultsmentioning

confidence: 99%

“…[27,29] Recent theoretical calculations have disclosed the low thermal conductivity ( ) of γ-GeSe, underscoring the crucial in uence of its unique bonding con guration on this aspect of the material. [30][31][32][33] However, a comprehensive experimental investigation into the mechanical and thermal properties linked to this distinctive bonding con guration in γ-GeSe is essential but remains unreported. The experimental con rmation of γ-GeSe's mechanical and thermal properties could pave the way for enhanced design and synthesis strategies, crucial for advancing thermoelectric and phase change memory technologies.…”

Section: Introductionmentioning

confidence: 99%

Unveiling the Distinctive Mechanical and Thermal Properties of γ-GeSe

Park,

Je,

Kim

et al. 2024

Preprint

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γ-GeSe is a newly identified polymorph among group-IV monochalcogenides, characterized by a distinctive interatomic bonding configuration. Despite its promising applications in electrical and thermal domains, the experimental verification of its mechanical and thermal properties remains unreported. Here, we experimentally characterize the in-plane Young’s modulus (E) and thermal conductivity (\(\kappa\)) of γ-GeSe. The mechanical vibrational modes of freestanding γ-GeSe flakes are measured using optical interferometry. Nano-indentation via atomic force microscopy is also conducted to induce mechanical deformation and to extract the E. Comparison with finite-element simulations reveals that the E is 97.3\(\pm\)7.5 GPa as determined by optical interferometry and 109.4\(\pm\)13.5 GPa as established through the nano-indentation method. Additionally, optothermal Raman spectroscopy reveals that γ-GeSe has a lattice thermal conductivity of 2.3\(\pm\)0.4 Wm−1K−1 and a total thermal conductivity of 7.5\(\pm\)0.4 Wm−1K−1 in the in-plane direction at room temperature. The notably high \(E/\kappa\) ratio in γ-GeSe, compared to other layered materials, underscores its distinctive structural and dynamic characteristics.

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“…CsCl, CsBr, CsI), low-temperature anharmonicity has been observed, characterized by anharmonic displacements of the cesium ions and short phonon lifetimes [9,10]. For γ-GeSe, the cumulative thermal conductivity is isotropic and the phononic representative mean free path is the shortest (17.07 nm) among the three polymorphs, indicating that the thermal conductivity of the γ-phase is less likely to be affected by the size of the sample [11]. Pierre-François Lory et al achieved the direct quantitative measurement of phonon lifetimes in a single crystal of the clathrate Ba 7.81 Ge 40.67 Au 5.33 , renowned for its puzzling 'glasslike' thermal conductivity.…”

Section: Introductionmentioning

confidence: 99%

Effect of phonon anharmonicity on thermal conductivity of ZnTe Thin films

Ghosh,

Ghorai,

Sahoo

2024

J. Phys.: Condens. Matter

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The ZnTe thin film is a potential material for optoelectronic devices in extreme temperature and radiation environments. In this report, the thermal conductivity of ZnTe films is measured non-invasively using the Micro-Raman method and correlated with the phonon anharmonic effect. The evolution of crystalline ZnTe thin films from Te/ZnO bilayer by thermal annealing at 4500C has been observed above the melting point of Te, which is confirmed from X-ray diffraction and high-resolution transmission electron microscopy. The ZnTe thin films illustrate three longitudinal phonon modes with higher harmonics of nLO (n=3) at room temperature. Temperature-dependent Raman spectra in the range of 93 - 303 K are used to analyze the phonon anharmonicity from Raman shift, FWHM, and Phonon lifetime of the thin films. The Balkanski model is used to fit the anharmonicity-induced phonon frequency shift of nLO modes as a function of temperature, taking into account three- and four-phonon interactions. The intensity ratio of the I2LO/I1LO and I3LO/I2LO provide information about the electron-phonon coupling strength, which is influenced by the anharmonic effect. The laser power-dependant Raman spectra are used to determine the thermal conductivity of the ZnTe films, which is found to be approximately 9.68 Wm-1 K-1, remains relatively constant for all nLO modes, indicating that multi-phonon scattering process. The correlation between thermal conductivity and phonon anharmonicity can pave the way for understanding the phonon scattering process in ZnTe thin films for high-performance optoelectronic device applications in harsh conditions.

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First-Principles Study of the Phonon Lifetime and Low Lattice Thermal Conductivity of Monolayer γ-GeSe: A Comparative Study

Cited by 10 publications

References 59 publications

Colossal figure of merit and compelling HER catalytic activity of holey graphyne

Colossal figure of merit and compelling HER catalytic activity of holey graphyne

Unveiling the Distinctive Mechanical and Thermal Properties of γ-GeSe

Effect of phonon anharmonicity on thermal conductivity of ZnTe Thin films

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