Thermal conductivities of different period Si/Ge superlattices

华北电力大学,

doi:10.7498/aps.70.20201789

Cited by 3 publications

(2 citation statements)

References 30 publications

Supporting

Mentioning

Contrasting

Unclassified

Order By: Relevance

“…MVs are important rain-producing systems in summer (May-September) in China (Zhang and Tan 2009;Xu et al 2011). Some studies have suggested that during the mei-yu season in eastern China, a series of MV activities are often seen on the mei-yu front (Fu et al 2012;Liu et al 2012;Zhang et al 2018;Fu et al 2019). Zhang et al (2018) pointed out that the long-lived MV on the mei-yu front propagating eastward is a crucial weather system that causes rainstorms in eastern China.…”

Section: Introductionmentioning

confidence: 99%

A 10-Year Climatology of Midlevel Mesoscale Vortices in China

Shu,

Sun,

Chenlu

2022

Journal of Applied Meteorology and Climatology

View full text Add to dashboard Cite

The mesoscale vortex (MV) is an important rain-producing system. In this study, the reanalysis data and satellite precipitation products are used to classify MVs into three categories: mesoscale convective vortex (MCV), mesoscale stratiform vortex (MSV) and mesoscale dry vortex (MDV). Then, these three categories of mid-level MVs in China from 2007 to 2016 are investigated. A total of 21,053 MVs are obtained. Most MVs form in the northwest of parent convection, and 45% of MVs generate secondary convection. The Tibetan Plateau is the main MV source-region. Steered by the westerlies, MVs mainly move eastward. MCV is active in summer, MDV in winter, and MSV in spring and autumn. MCV diurnal variations are closely related to local topography, and MDVs mainly form around midnight. Composite analyses show that MCVs form near the high-value center of convective available potential energy at the development stage of parent convection. The composite MCV forms near the low-pressure trough and the thermal ridge at 500 hPa, and a low-level jet exists to the south of the MCV center. At the initiation and maturity stages of MCV, strong convergence and divergence respectively exist at low levels and 400 hPa. The vortex circulation mainly locates near 500hPa. Above the vortex is a warm core associated with the latent heat release, and below is a cold anomaly related to the cold pool. In the downshear region, there is strong low-level convergence and ascending motion, higher humidity and greater latent-heat release, which favor the formation of secondary convection.

show abstract

Section: Introductionmentioning

confidence: 99%

A 10-Year Climatology of Midlevel Mesoscale Vortices in China

Shu,

Sun,

Chenlu

2022

Journal of Applied Meteorology and Climatology

View full text Add to dashboard Cite

show abstract

“…界面声子频谱热流可以对不同结构热导率的变化有更进一步的解释, 通过Si/Ge界面的单向光谱热流定义为 [27,28] q(ω) 结果保持一致 [22,30] , 同时验证了模拟结果的准确性. 随着温度的持续升高, 声子-声子散射(umklapp 过程)逐渐增强, 散射作用的增强降低了热传输效率.…”

Section: (ω)unclassified

Thermal conductivity of materials based on interfacial atomic mixing

刘英光¹,

薛新强²,

张静文³

et al. 2022

Acta Phys. Sin.

Self Cite

View full text Add to dashboard Cite

The Si/Ge single interface and superlattice structure with atom mixing interfaces are constructed. The effects of interfacial atomic mixing on thermal conductivity of single interface and superlattice structures are studied by non-equilibrium molecular dynamics simulation (NEMD). The effects of the number of atomic mixing layers, temperature, total length of the system and period length on the thermal conductivity of different lattice structures are studied. The results show that the mixing of two and four layers of atoms can improve the thermal conductivity of Si/Ge lattice with single interface and the superlattice with small total length due to the "bridge" mechanism. When the total length of the system is large, the thermal conductivity of the superlattice with atomic mixing interfaces decreases significantly compared with the perfect interfaces. The interfacial atom mixing will destroy the phonon coherent transport in the superlattice and decrease the thermal conductivity to some extent. The superlattice with perfect interfaces have obvious temperature effect, while the thermal conductivity of the superlattices with atomic mixing is less sensitive to temperature.

show abstract

Effect of interfacial atomic mixing on the thermal conductivity of multi-layered stacking structure

Liu

Xue

Ren

et al. 2022

Journal of Applied Physics

View full text Add to dashboard Cite

Multi-layered stacking structures and atomic mixing interfaces were constructed. The effects of various factors on the thermal conductivity of different lattice structures were studied by non-equilibrium molecular dynamics simulations, including the number of atomic mixing layers, temperature, total length of the system, and period length. The results showed that the mixing of two and four layers of atoms can improve the thermal conductivities of the multi-layer structure with a small total length due to a phonon “bridge” mechanism. When the total length of the system is large, the thermal conductivity of the multi-layer structure with atomic mixing interfaces decreases significantly compared with that of the perfect interfaces. The interfacial atom mixing destroys the phonon coherent transport in the multi-layer structure and decreases the thermal conductivity to some extent. The thermal conductivity of the multi-layer structure with perfect interfaces is significantly affected by temperature, whereas the thermal conductivity of the multi-layer structures with atomic mixing is less sensitive to temperature.

show abstract

Thermal conductivities of different period Si/Ge superlattices

Cited by 3 publications

References 30 publications

A 10-Year Climatology of Midlevel Mesoscale Vortices in China

A 10-Year Climatology of Midlevel Mesoscale Vortices in China

Thermal conductivity of materials based on interfacial atomic mixing

Effect of interfacial atomic mixing on the thermal conductivity of multi-layered stacking structure

Contact Info

Product

Resources

About