Confinement effect on the low temperature specific heat for ultrathin silicon nanowires: A first principles study

I. González; M. Calvino; A. Trejo; F. Salazar; M. Cruz-Irisson

doi:10.1088/1361-648X/ab2dd4

Confinement effect on the low temperature specific heat for ultrathin silicon nanowires: A first principles study

I. González, M. Calvino, A. Trejo, F. Salazar, M. Cruz-Irisson

Escuela Superior de Ingeniería Mecánica y Eléctrica (ESIME), Unidad Culhuacán

Research output: Contribution to journal › Article › peer-review

2 Scopus citations

Abstract

This work studied the phonon confinement effects at the low temperature specific heat of Si nanowires from first principles using density functional perturbation theory. The nanowires were modeled in the [0 0 1] direction for three different diameters, with the largest cross section being approximately 10 Å. The results indicate the specific heat can be described at low temperatures using a third-grade polynomial of the form c _v = λT + βT ² + γT³, where the coefficients of quadratic and cubic terms are almost nonexistent for small diameters. These terms begin to have relevance at larger diameters. Further analysis shows λ > β > γ, which shows the phonon confinement (λ) and surface atoms (β) become more important than the volumetric contribution (γ) for ultrathin nanowires at low temperatures.

Original language	English
Article number	425303
Journal	Journal of Physics Condensed Matter
Volume	31
Issue number	42
DOIs	https://doi.org/10.1088/1361-648X/ab2dd4
State	Published - 24 Jul 2019

Keywords

DFPT
silicon nanowires
specific heat

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10.1088/1361-648X/ab2dd4

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title = "Confinement effect on the low temperature specific heat for ultrathin silicon nanowires: A first principles study",

abstract = "This work studied the phonon confinement effects at the low temperature specific heat of Si nanowires from first principles using density functional perturbation theory. The nanowires were modeled in the [0 0 1] direction for three different diameters, with the largest cross section being approximately 10 {\AA}. The results indicate the specific heat can be described at low temperatures using a third-grade polynomial of the form c v = λT + βT 2 + γT3, where the coefficients of quadratic and cubic terms are almost nonexistent for small diameters. These terms begin to have relevance at larger diameters. Further analysis shows λ > β > γ, which shows the phonon confinement (λ) and surface atoms (β) become more important than the volumetric contribution (γ) for ultrathin nanowires at low temperatures.",

keywords = "DFPT, silicon nanowires, specific heat",

author = "I. Gonz{\'a}lez and M. Calvino and A. Trejo and F. Salazar and M. Cruz-Irisson",

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TY - JOUR

T1 - Confinement effect on the low temperature specific heat for ultrathin silicon nanowires

T2 - A first principles study

AU - González, I.

AU - Calvino, M.

AU - Trejo, A.

AU - Salazar, F.

AU - Cruz-Irisson, M.

PY - 2019/7/24

Y1 - 2019/7/24

N2 - This work studied the phonon confinement effects at the low temperature specific heat of Si nanowires from first principles using density functional perturbation theory. The nanowires were modeled in the [0 0 1] direction for three different diameters, with the largest cross section being approximately 10 Å. The results indicate the specific heat can be described at low temperatures using a third-grade polynomial of the form c v = λT + βT 2 + γT3, where the coefficients of quadratic and cubic terms are almost nonexistent for small diameters. These terms begin to have relevance at larger diameters. Further analysis shows λ > β > γ, which shows the phonon confinement (λ) and surface atoms (β) become more important than the volumetric contribution (γ) for ultrathin nanowires at low temperatures.

AB - This work studied the phonon confinement effects at the low temperature specific heat of Si nanowires from first principles using density functional perturbation theory. The nanowires were modeled in the [0 0 1] direction for three different diameters, with the largest cross section being approximately 10 Å. The results indicate the specific heat can be described at low temperatures using a third-grade polynomial of the form c v = λT + βT 2 + γT3, where the coefficients of quadratic and cubic terms are almost nonexistent for small diameters. These terms begin to have relevance at larger diameters. Further analysis shows λ > β > γ, which shows the phonon confinement (λ) and surface atoms (β) become more important than the volumetric contribution (γ) for ultrathin nanowires at low temperatures.

KW - DFPT

KW - silicon nanowires

KW - specific heat

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DO - 10.1088/1361-648X/ab2dd4

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JO - Journal of Physics Condensed Matter

JF - Journal of Physics Condensed Matter

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M1 - 425303

ER -

Confinement effect on the low temperature specific heat for ultrathin silicon nanowires: A first principles study

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