部分期刊论文Journal Paper (*通讯作者Corresponding Author)

2017

[41]

D. Liao, W. Chen, J. Zhang, Y. Yue*, 2017 "Tuning Thermal Conductance of CNT Interface Junction via Stretching and Atomic Bonding," Journal of Physics D: Applied Physics, DOI: https://doi.org/10.1088/1361-6463/aa8ff8. [PDF]

[40]

M. Han, P. Yuan, J. Liu, S. Si, X. Zhao, Y. Yue, X. Wang*,. X. Xiao*, 2017 "Interface Energy Coupling between β-tungsten Nanofilm and Few-layered Graphene,"Scientific Reports, DOI: 10.1038/s41598-017-12389-1.[PDF]

[39]

J. Zhang*, Y. Hong, X. Wang, Y. Yue*, D. Xie, J. Jiang, Y. Xiong, P. Li, 2017 "Phonon Thermal Properties of Transition-Metal Dichalcogenides MoS2 and MoSe2 Heterostructure," The Journal of Physical Chemistry C, Vol. 121, pp 10336–10344 [PDF]

[38]

Y. Yue*', J. Zhang', Y. Xie, W. Chen, X. Wang*, 2017 "Energy Coupling across Low-dimensional Contact Interfaces at the Atomic Scale," International Journal of Heat and Mass Transfer, Vol. 110, pp. 827–844. (A comprehensive review article) [PDF]

[37]

陈文,岳亚楠*, 2017 "拉曼热扫描技术同步测量一维导热和对流换热," 工程热物理学报, In Print.

[36]

J. Zhang, Y. Hong, M. Liu, Y. Yue, Q. Xiong*, G. Lorenzini*, 2017 "Molecular Dynamics Simulation of The Interfacial Thermal Resistance between Phosphorene and Silicon Substrate,"International Journal of Heat and Mass Transfer, Vol. 104, pp. 871-877. [PDF]

[35]

C. Shao, X. Yu, N. Yang, Y. Yue, H. Bao*, 2017 "A Review of Thermal Transport in Low-dimensional Materials under External Perturbation: Effect of Strain, Substrate, and Clustering," Nanoscale and Microscale Thermophysical Engineering, DOI:http://dx.doi.org/10.1080/15567265.2017.1286421. [PDF]

2016

[34]

J. Zhang*, X. Wang, Y. Hong, Q. Xiong, J. Jiang, Y. Yue*, 2017, "Understanding Thermal Transport in Layer-Asymmetric Hexagonal Boron-Nitride Heterostructure," Nanotechnology, Vol. 28 p. 035404. [PDF]

[33]

W. Zhao', W. Chen', Y. Yue*, S. Wu*, 2017, "In-situ Two-Step Raman Thermometry for Thermal Characterization of Monolayer Graphene Interface Material," Applied Thermal Engineering,Vol. 113, pp.481–489.[PDF].

[32]

C. Li, J. Zhang, Q. Xiong, G. Lorenzini, Y. Yue*, 2016 "pH Effect on Thermal Response of Fluorescence Spectroscopy of Graphene Quantum Dots for Nanoscale Thermal Characterization," Journal of Engineering Thermophysics, In Print.

[31]

S. Si, W. Li, X. Zhao, M. Han, Y. Yue, X. Zheng, W. Qin, X. Zhang, W. Wu, X. Wang*, X. Xiao*, and C. Jiang, 2017, "Significant radiation tolerance and moderate reduction in thermal transport of tungsten nanofilm by inserting monolayer graphene," Advanced Materials, Vol. 29, p. 1604623.[PDF]

[30]

[29]
W. Chen, J. Zhang*, and Y. Yue*, 2016 "Molecular Dynamics Study on Thermal Transport at Carbon Nanotube Interface Junctions: Effects of Mechanical Force and Chemical Functionalization," International Journal of Heat and Mass Transfer, Vol. 103, pp. 1058-1064. [PDF]

 

Highlight: Interface thermal transport at carbon nanotube junction can be modulated by changing contact mode: crossing angle, contact area, or bonding strength. The relationship of LJ scaling parameter, applied force and final separation distance between CNTs is established. Interface thermal conductance between CNTs does not increase monotonically with number of CH2, i.e., there is an optimal value of CH2 linker density.

 

[28]
C. Li, S. Xu, Y. Yue*, B. Yang, X. Wang, 2016 "Thermal Characterization of Carbon Nanotube Fiber by Time-Domain Differential Raman," Carbon, Vol.103, pp. 101-108. [PDF]
 

Highlight: In this work, we used both transient and steady-state measurement to characterize heat conduction property of CNT fiber material. This is the first time for using time-domain differential Raman on thermal characterization of composite materials. This technique can be applied on other one-dimensional materials as well.

[27]

李满, 赵晓龙, 肖湘衡, 岳亚楠* 2016 "基于拉曼散射的石墨烯/氧化硅界面传热研究,"工程热物理学报, 37卷, 第9期, 页码:1945-1951. [PDF]

[26]

T. Wang, S. Xu, D. Hurley*, Y. Yue, X. Wang*, 2016 "Frequency-resolved Raman for Transient Thermal Probing and Thermal Diffusivity Measurement," Optics Letters, Vol. 41, pp. 80-83. [PDF]

2015

[25]
J. Zhang, Y. Hong, Z. Tong, Z. Xiao*, H. Bao, Y. Yue*, 2015 "Molecular Dynamics Study of Interfacial Thermal Transport between Silicene and Substrate," Physical Chemistry Chemical Physics, Vol. 17, pp. 23704-23710. [PDF] Selected as the Back Cover Article (封面文章).

Highlight: The interfacial thermal transport between silicene and multiple substrates is firstly calculated by using a transient heating molecular dynamics technique. Interesting findings include the interfacial conductance can be greatly improved with increasing temperature and amorphous structure of substrate could facilitate interfacial thermal transport. This paper is selected as the back cover article in PCCP.

[24]

M. Li, Z. Dai, J. Ying, X. Xiao, Y. Yue*, 2015 "Thermal Characterization of Carbon Nanotube Fibers based on Steady-state Electro-Raman-thermal Technique," Acta Physica Sinica (物理学报, in Chinese),Vol. 64, p. 126501. [PDF]

[23]
M. Li, C. Li, J. Wang, X. Xiao, Y. Yue*, 2015 "Parallel Measurement of Conductive and Convective Thermal Transport of Micro/Nanowires Based on Raman Mapping," Applied Physics Letters, Vol. 106, p. 253108. [PDF]

Highlight: This paper reports a novel method to measure thermal conductivity and convection coefficient of micro/nanowires simultaneously by using Raman spectroscopy.

[22]

S. Xu, T. Wang, D. Hurley*, Y. Yue, X. Wang*, 2015 "Development of Time-Domain Differential Raman for Transient Thermal Probing of Materials," Optics Express, Vol. 23, pp. 10040-10056. [PDF]

[21]

J. Zhang*, Y. Hong, Y. Yue*, 2015 "Thermal Transport across Graphene and Single Layer Hexagonal Boron Nitride," Journal of Applied Physics, Vol. 117, p. 134307. [PDF]

[20]

M. Li, Y. Sun, H. Xiao, X. Hu, Y. Yue*, 2015 "High Temperature Dependence of Thermal Transport in Graphene Foam," Nanotechnology, Vol. 26, p. 105703. [PDF]

[19]

M. Li, J. Zhang, X. Hu*, Y. Yue*, 2015 "Thermal Transport across Graphene/SiC Interface: Effects of Atomic Bond and Crystallinity of Substrate," Applied Physics A, Rapid Communications, Vol. 119, pp. 415-424. [PDF]

[18]

Y. Yue', J. Zhang', X. Tang, S. Xu, X. Wang*, 2015 "Thermal Transport across Atomic-Layer Material Interfaces," Nanotechnology Reviews, Vol. 4, pp. 533-555, ('Equally Contributed). [PDF] Invited Review.

[17]

M. Li, Y. Yue*, 2015 "Raman-Based Steady-State Thermal Characterization of Multiwall Carbon Nanotube Bundle and Buckypaper," Journal of Nanoscience and Nanotechnology, Vol. 15, pp. 3004-3010. [PDF]

2014

[16]

Y. Yue*, K. Liu, M. Li, X. Hu, 2014 "Thermal Manipulation of Carbon Nanotube Fiber by Mechanical Stretching," Carbon, Vol. 77, pp. 973–979. [PDF]

[15]

Highlight: We found high temperature dependence of fluorescence spectroscopy of graphene quantum dots (more than 50% for temperature range less than 80K), which provide us a new way for nanoscale thermal probing. This work has been featured as the labtalk news report from the journal of "Nanotechnology" and the website of "Nanotechweb".

[14]

M. Li, Y. Yue*, 2014 "Molecular Dynamics Study of Thermal Transport in Amorphous Silicon Carbide Thin Film," RSC Advances, Vol. 4, pp. 23010-23016. [PDF]

2013

[13]

S. Xu, X. Tang, Y. Yue, X. Wang, 2013 "Sub-micron Imaging of Sub-surface Nanocrystalline Structure in Silicon," Journal of Raman Spectroscopy, Vol. 44, pp. 1523-1528. [PDF]

2012

[12]

Y. Yue, X. Wang, 2012 "Nanoscale Thermal Probing," Nano Reviews, Vol. 3, p. 11586. [PDF] Invited Review.

[11]

X. Tang, Y. Yue, X. Chen, X. Wang, 2012 "Sub-wavelength Temerature Probing in Near-field Laser Heating by Particles," Optics Express, Vol. 20, pp. 14152-14167. [PDF]

[10]

P. Li, Q. Wang, Q. Xu, W. Yu, Y. Yue, Z. Liang, X. Dong, S. Hu, 2012 "Combustion Reaction Mechanism of Four Typical Chinese Biomass by TG and DTG," Asia-Pacific Journal of Chemical Engineering, Vol.7, S209-S215. [PDF]

2011

[9]
 
Highlight: By using Raman thermometry, we can study interface thermal transport between graphene and substrate. This technology has achieved sub nanometer scale for temperature probing and this work features the first thermal resistance measurement of bare graphene interface.

[8]

J. Zhang, X. Huang, Y. Yue, J. Wang, X. Wang, 2011 "Dynamic Response of Graphene to Thermal Impulse," Physical Review B, Vol. 84, p. 235416. [PDF]

[7]

Y. Yue, X. Wang, 2011 "Review on Raman-based Thermal Characterization and Analysis," Journal of Shanghai Second Polytechnical University, Vol. 28, pp. 183-191. (In Chinese) [PDF] Invited Review.

[6]
Y. Yue, X. Chen, X. Wang, 2011 "Noncontact Sub-10 nm Temperature Measurement in Near-field Laser Heating," ACS Nano, Vol. 5, pp. 4466-4475. [PDF]
 
Highlight: Sub 10 nm spatial resolution for thermal probing has been achieved in this work by combining near field effect and Raman thermometry. This paper also reports an experimental evidence of ballistic thermal transport inside silicon within extremely small heating space.

[5]

X. Feng, X. Wang, X. Chen, Y. Yue, 2011 "Thermophysical Properties of Thin Films Composed of Anatase TiO2 Nanofibers," Acta Materialia, Vol. 59, pp. 1934-1944. [PDF]

2010

[4]

Y. Yue, X. Huang, X. Wang, 2010 "Thermal Transport in Multiwall Carbon Nanotube Buckypapers," Physics Letters A, Vol. 374, pp. 4144-4151. [PDF]

[3]

L. Jauregui, Y. Yue, A. Sidorov, J. Hu, Q. Yu, G. Lopez, R. Jalilian, D. Benjamin, D. Delkd, W. Wu, Z. Liu, X. Wang, Z. Jiang, X. Ruan, J. Bao, S. Pei, Y. Chen, 2010 "Thermal Transport in Graphene Nanostructures: Experiments and Simulations," ECS Transactions, Vol. 28, pp. 73-83. [PDF]

2009

[2]

Y. Yue, G. Eres, X. Wang, L. Guo, 2009 "Characterization of Thermal Transport in Micro/Nanoscale Wires by Steady-state Electro-Raman-thermal Technique," Applied Physics A, Rapid Communications, Vol. 97, pp. 19-23. [PDF]

[1]

P. Li, Y. Hu, W. Yu, Y. Yue, Q. Xu, S. Hu, N. Hu, J. Yang, 2009 "Investigation of Sulfur Forms and Transformation during the Co-combustion of Sewage Sludge and Coal using X-ray Photoelectron Spectroscopy," Journal of Hazardous Materials, Vol.167, pp. 1126-1132. [PDF]

 

书籍章节Book Chapter

[3]

S. Xu, L. Zhang, Y. Yue, X. Wang, "Physics in Laser Near-field Nanomanufacturing Fundamental Understanding and Novel Probing," Encyclopedia of Nanotechnology, Springer, DOI: 10.1007/978-94-007-6178-0_100915-1.

[2]

X. Wang, Y. Yue, 2014 "Stresses in Laser Surface Nanostructuring," Encyclopedia of Thermal Stresses, Springer, pp. 4613-4640.

[1]
X. Wang, Y. Yue, X. Xu, 2014 "Thermoelastic Waves Induced by Pulsed Laser Heating," Encyclopedia of Thermal Stresses, Springer, pp. 5808-5826.