Thermoelectric Properties of Nanowires with a Graphitic Shell

被引:4
作者
Lee, Jong Woon [1 ,6 ]
Lee, Eun Kyung [3 ]
Kim, Byung Sung [5 ]
Lee, Jae Hyun [1 ,6 ]
Kim, Hee Goo [7 ]
Jang, Hyeon Sik [2 ,6 ]
Hwang, Sung Woo [6 ]
Choi, Byoung Lyong [4 ]
Whang, Dongmok [1 ,2 ,6 ]
机构
[1] Sungkyunkwan Univ, SKKU Adv Inst Nanotechnol, Suwon 440746, South Korea
[2] Sungkyunkwan Univ, Sch Adv Mat Sci & Engn, Suwon 440746, South Korea
[3] Samsung Elect, Samsung Adv Inst Technol, Comp Aided Engn Grp, Suwon 443803, South Korea
[4] Samsung Elect, Samsung Adv Inst Technol, Nano Elect Lab, Suwon 443803, South Korea
[5] Univ Oxford, Dept Engn Sci, Oxford OX1 2JD, England
[6] Samsung Adv Inst Technol, Res Ctr Time Domain Nanofunct Devices, Suwon 443803, South Korea
[7] Samsung Elect, Samsung Adv Inst Technol, Analyt Engn Grp, Suwon 443803, South Korea
来源
CHEMSUSCHEM | 2015年 / 8卷 / 14期
基金
新加坡国家研究基金会;
关键词
conducting materials; core-shell structure; graphitic layer; nanostructures; thermal conductivity; THERMAL-CONDUCTIVITY; GERMANIUM NANOWIRES; TRANSPORT; GRAPHENE; CONTACT; GE;
D O I
10.1002/cssc.201403492
中图分类号
O6 [化学];
学科分类号
0703 ;
摘要
A thermoelectric device that can generate electricity from waste heat can play an important role in a global energy solution. However, the strongly correlated thermoelectric properties have remained a major hurdle for the highly efficient conversion of thermoelectric energy. Herein, the electrical and thermal properties of Si and SiO2 nanowires with few-layer graphitic shells are demonstrated; these structures exhibit enhanced electrical properties but no increase in thermal conductivity. The main path of the phonons through the structures is the core nanowire, which has a large cross-sectional area relative to that of the graphitic shell layer. However, the electrical conductivities of the nanowires with shell structures are high because of the good electrical conductivity of the graphitic shell, despite its small cross-sectional area.
引用
收藏
页码:2372 / 2377
页数:6
相关论文
共 43 条
[1]  
[Anonymous], 2002, ANGEW CHEM, V114, P4977
[2]   Superior thermal conductivity of single-layer graphene [J].
Balandin, Alexander A. ;
Ghosh, Suchismita ;
Bao, Wenzhong ;
Calizo, Irene ;
Teweldebrhan, Desalegne ;
Miao, Feng ;
Lau, Chun Ning .
NANO LETTERS, 2008, 8 (03) :902-907
[3]   Direct growth of few-layer graphene films on SiO2 substrates and their photovoltaic applications [J].
Bi, Hui ;
Sun, Shengrui ;
Huang, Fuqiang ;
Xie, Xiaoming ;
Jiang, Mianheng .
JOURNAL OF MATERIALS CHEMISTRY, 2012, 22 (02) :411-416
[4]   Ultrahigh electron mobility in suspended graphene [J].
Bolotin, K. I. ;
Sikes, K. J. ;
Jiang, Z. ;
Klima, M. ;
Fudenberg, G. ;
Hone, J. ;
Kim, P. ;
Stormer, H. L. .
SOLID STATE COMMUNICATIONS, 2008, 146 (9-10) :351-355
[5]   Silicon nanowires as efficient thermoelectric materials [J].
Boukai, Akram I. ;
Bunimovich, Yuri ;
Tahir-Kheli, Jamil ;
Yu, Jen-Kan ;
Goddard, William A., III ;
Heath, James R. .
NATURE, 2008, 451 (7175) :168-171
[6]  
Byun KE, 2013, NANO LETT, V13, P4001, DOI [10.1021/nl3047305, 10.1021/nl402367y]
[7]   Thermal Transport in Suspended and Supported Monolayer Graphene Grown by Chemical Vapor Deposition [J].
Cai, Weiwei ;
Moore, Arden L. ;
Zhu, Yanwu ;
Li, Xuesong ;
Chen, Shanshan ;
Shi, Li ;
Ruoff, Rodney S. .
NANO LETTERS, 2010, 10 (05) :1645-1651
[8]   Theoretical phonon thermal conductivity of Si/Ge superlattice nanowires [J].
Dames, C ;
Chen, G .
JOURNAL OF APPLIED PHYSICS, 2004, 95 (02) :682-693
[9]   New directions for low-dimensional thermoelectric materials [J].
Dresselhaus, Mildred S. ;
Chen, Gang ;
Tang, Ming Y. ;
Yang, Ronggui ;
Lee, Hohyun ;
Wang, Dezhi ;
Ren, Zhifeng ;
Fleurial, Jean-Pierre ;
Gogna, Pawan .
ADVANCED MATERIALS, 2007, 19 (08) :1043-1053
[10]   The rise of graphene [J].
Geim, A. K. ;
Novoselov, K. S. .
NATURE MATERIALS, 2007, 6 (03) :183-191
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