Tuning Thermal Transport in Ultrathin Silicon Membranes by Surface Nanoscale Engineering

Neogi, Sanghamitra; Reparaz, J. S.; Pereira, Luiz Felipe C.; Graczykowski, Bartłomiej; Wagner, Markus R.; Sledzinska, Marianna; Shchepetov, A.; Prunnila, Mika; Ahopelto, Jouni; Torres, C. M. Sotomayor; Donadio, Davide

doi:10.1021/nn506792d

Cited by 115 publications

(175 citation statements)

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“…We observe, expectedly, k Memb to drop significantly with decreasing d due to dispersion modification as well as the reduction of phonon mean free paths (MFP) caused by diffuse boundary scattering at the surfaces as a result of their reconstruction at the equilibrium state [23]. These effects been studied experimentally in the literature in the context of a thin silicon layer on a substrate [24], freestanding silicon membranes [12,25], and also silicon nanowires [26]. The k NPM curves are observed to similarly increase with increasing unit-cell size (due to increasing thickness) until gradual saturation.…”

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confidence: 82%

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confidence: 99%

“…A recent molecular dynamics study examined a wider range of geometric dimensions on the same pillared silicon membrane configuration and demonstrated a reduction in the thermal conductivity by roughly a factor of 3 [11]. The resonance-hybridization mechanism described above may be used in conjunction with boundary scattering from rough surfaces to lower k [12,13].For the concept of an NPM to be realized in practice, the nanostructured material's characteristic length scales, such as the membrane thickness and the nanopillar height and cross-sectional area, need to be at least on the order of a few tens of nanometers−which is substantially larger than the length scales considered in the previous studies mentioned above. In this Letter, we study the effect of increasing size, in different ways, on the performance of an NPM.…”

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Thermal transport size effects in silicon membranes featuring nanopillars as local resonators

Honarvar

Yang

Hussein

2016

Applied Physics Letters

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Silicon membranes patterned by nanometer-scale pillars standing on the surface provide a practical platform for thermal conductivity reduction by resonance hybridization. Using molecular simulations, we investigate the effect of nanopillar size, unit-cell size, and finite-structure size on the net capacity of the local resonators in reducing the thermal conductivity of the base membrane. The results indicate that the thermal conductivity reduction increases as the ratio of the volumetric size of a unit nanopillar to that of the base membrane is increased, and the intensity of this reduction varies with unit-cell size at a rate dependent on the volumetric ratio. Considering sample size, the resonance-induced thermal conductivity drop is shown to increase slightly with the number of unit cells until it would eventually level off.In semiconducting materials, heat is carried mostly by phonons which are quanta of lattice vibrations [1]. This provides an opportunity to introduce significant changes to the thermal transport properties by direct engineering of the phonon characteristics−which are shaped primarily by the phonon band structure and the nature of the underlying scattering mechanisms [2]. Recent reviews survey developments in theory, computation, and experiment pertaining to nanoscale thermal transport in a variety of materials and point to the remarkable possibilities for using nanostructuring as a means for phonon engineering [3].Thermoelectric energy conversion stands to benefit profoundly from the ability to alter the phonon properties by nanostructuring [4], as well as by reducing the material dimensionality [5]. Thermoelectric materials, which generate electricity from heat and vice versa, are characterized by a figure of merit defined as ZT = σT S 2 /k, where S is the Seebeck coefficient, σ is the electrical conductivity, k is the thermal conductivity (consisting of a lattice component and an electrical component), and T is absolute temperature [6]. One strategy to improve the value of ZT , particularly in semiconductors, is to reduce the lattice thermal conductivity and attempt to do so without negatively affecting S and σ. A promising approach for achieving this goal is to introduce nanoscale local resonators as intrinsic substructures within, or attached to, a host crystalline material [7,8]. The emerging system, called nanophononic metamaterial (NPM), exhibits unique properties that are not attainable in conventional nanostructured media such as nanocomposites [9] or nanophononic crystals [10]. The substructure resonances, which could be numerous for relatively large substructures, may be tuned to couple with all or most of the heat-carrying phonon modes of the underlying host medium. This atomic-scale coupling mechanism is essentially a resonance hybridization between the wavenumberdependent wave modes of the host medium (phonons) and the wavenumber-independent vibration modes of the local substructure (vibrons). The outcome is significant reductions in the phonon group velocities across roughly ...

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confidence: 82%

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confidence: 99%

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Thermal transport size effects in silicon membranes featuring nanopillars as local resonators

Honarvar

Yang

Hussein

2016

Applied Physics Letters

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“…Xiong et al [32] demonstrated that nanopillars not only generate local resonances but also scatter the phonons and reduce their mean free path by one order of magnitude. Similarly, Neogi et al [61] concluded that the reduction in thermal conductivity is mainly caused by the diffuse scattering of phonons on nanopillars whereas local resonances play only a minor role. Recently, Honarvar and Hussein [34] too found that nanopillars shorten both phonon mean free path and lifetimes by the diffuse scattering, but argued that local resonances still play the leading role in the thermal conductivity reduction.…”

Section: Simulations Of Heat Conductionmentioning

confidence: 98%

“…Thus, the observed reduction in thermal conductivity was attributed to the surface roughness and the amorphous layer under the pillars. Indeed, amorphous layers at the surfaces are known to reduce the thermal conductivity of nanostructures [61,64–66] and can diffusely scatter phonons stronger than just surface roughness [67]. …”

Section: Experimental Measurements Of the Thermal Propertiesmentioning

confidence: 99%

Phonon and heat transport control using pillar-based phononic crystals

Anufriev

Nomura

2018

Science and Technology of Advanced Materials

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Phononic crystals have been studied for the past decades as a tool to control the propagation of acoustic and mechanical waves. Recently, researchers proposed that nanosized phononic crystals can also control heat conduction and improve the thermoelectric efficiency of silicon by phonon dispersion engineering. In this review, we focus on recent theoretical and experimental advances in phonon and thermal transport engineering using pillar-based phononic crystals. First, we explain the principles of the phonon dispersion engineering and summarize early proof-of-concept experiments. Next, we review recent simulations of thermal transport in pillar-based phononic crystals and seek to uncover the origin of the observed reduction in the thermal conductivity. Finally, we discuss first experimental attempts to observe the predicted thermal conductivity reduction and suggest the directions for future research.

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