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(2010)
High - performance nanostructured thermoelectric materials NPG
E. Pop, V. Varshney, A. Roy (2012)
Thermal properties of graphene: Fundamentals and applicationsMRS Bulletin, 37
Gil‐Ho Kim, Deok-hyun Hwang, S. Woo (2012)
Thermoelectric properties of nanocomposite thin films prepared with poly(3,4-ethylenedioxythiophene) poly(styrenesulfonate) and graphene.Physical chemistry chemical physics : PCCP, 14 10
X. Sun, M. Dresselhaus, Kang Wang, M. Tanner (1993)
Effect of quantum-well structures on the thermoelectric figure of merit.Physical review. B, Condensed matter, 47 19
T. Harman, P. Taylor, Michael Walsh, B. laforge (2002)
Quantum Dot Superlattice Thermoelectric Materials and DevicesScience, 297
Fitriani, R. Ovik, B. Long, B. Long, M. Barma, M. Riaz, M. Sabri, S. Said, R. Saidur (2016)
A review on nanostructures of high-temperature thermoelectric materials for waste heat recoveryRenewable & Sustainable Energy Reviews, 64
K. Parvez, Rongjin Li, S. Puniredd, Y. Hernández, F. Hinkel, Suhao Wang, Xinliang Feng, K. Müllen (2013)
Electrochemically exfoliated graphene as solution-processable, highly conductive electrodes for organic electronics.ACS nano, 7 4
(2017)
Cross-plane enhanced thermoelectricity and phonon suppression in graphene/MoS 2 van der Waals heterostructures 2D Mater
Chun-Chung Chen, Zhen Li, Li Shi, S. Cronin (2017)
Thermoelectric transport across graphene/hexagonal boron nitride/graphene heterostructuresNano Research, 8
Q. Yao, Lidong Chen, Wenqing Zhang, Shengcong Liufu, Xi-hong Chen (2010)
Enhanced thermoelectric performance of single-walled carbon nanotubes/polyaniline hybrid nanocomposites.ACS nano, 4 4
R. Singh, Z. Bian, A. Shakouri, G. Zeng, J. Bahk, J. Bowers, J. Zide, A. Gossard (2009)
Direct measurement of thin-film thermoelectric figure of meritApplied Physics Letters, 94
Zhiyong Wei, Z. Ni, Kedong Bi, Minhua Chen, Yunfei Chen (2011)
Interfacial thermal resistance in multilayer graphene structuresPhysics Letters A, 375
(2011)
Thermal Properties of Graphene, Carbon Nanotubes and Nanostructured Carbon Materials
D. Chung, T. Hogan, P. Brazis, M. Rocci-Lane, C. Kannewurf, M. Bastea, C. Uher, M. Kanatzidis (2000)
CsBi(4)Te(6): A high-performance thermoelectric material for low-temperature applicationsScience, 287 5455
H. Sadeghi, S. Sangtarash, C. Lambert (2016)
Cross-plane enhanced thermoelectricity and phonon suppression in graphene/MoS2 van der Waals heterostructures2D Materials, 4
J. García-Cañadas, G. Min (2014)
Low Frequency Impedance Spectroscopy Analysis of Thermoelectric ModulesJournal of Electronic Materials, 43
Jin-cheng Zheng (2008)
Recent advances on thermoelectric materialsFrontiers of Physics in China, 3
(2016)
A review on nanostructures of hightemperature thermoelectric materials for waste heat recovery
L. Hicks, M. Dresselhaus (1993)
Thermoelectric figure of merit of a one-dimensional conductor.Physical review. B, Condensed matter, 47 24
(2010)
Highperformance nanostructured thermoelectric materials NPG Asia Mater
Shih‐Yang Lin, Shen-Lin Chang, F. Shyu, Jianxin Lu, Ming-Fa Lin (2014)
Feature-rich electronic properties in graphene ripplesCarbon, 86
H. Sevinçli, G. Cuniberti (2009)
Enhanced thermoelectric figure of merit in edge-disordered zigzag graphene nanoribbonsPhysical Review B, 81
Limin Wang, Q. Yao, H. Bi, Fuqiang Huang, Qun Wang, Lidong Chen (2015)
PANI/graphene nanocomposite films with high thermoelectric properties by enhanced molecular orderingJournal of Materials Chemistry, 3
D. Dragoman, M. Dragoman (2007)
Giant thermoelectric effect in grapheneApplied Physics Letters, 91
M. Dresselhaus, Gang Chen, M. Tang, Ronggui Yang, Hohyun Lee, Dezhi Wang, Zhifeng Ren, J. Fleurial, P. Gogna (2007)
New Directions for Low‐Dimensional Thermoelectric MaterialsAdvanced Materials, 19
Jingfeng Li, Weishu Liu, Li-dong Zhao, Min Zhou (2010)
High-performance nanostructured thermoelectric materialsNpg Asia Materials, 2
M. Hurtado-Morales, M. Ortiz, C. Acuña, H. Nerl, V. Nicolosi, Y. Hernández (2016)
Efficient fluorescence quenching in electrochemically exfoliated graphene decorated with gold nanoparticlesNanotechnology, 27
T. Tritt, M. Subramanian
Introduction Thermoelectric Phenomena: Background and Applications Thermoelectric Materials, Phenomena, and Applications: a Bird's Eye View Thermoelectric Materials, Phenomena, and Applications: a Bird's Eye View Seebeck and Peltier Effects Definition and Description of the Figure of Merit and Therm
Z. Juang, Chien-Chih Tseng, Yumeng Shi, W. Hsieh, Soh Ryuzaki, N. Saito, Chia-En Hsiung, Wen‐Hao Chang, Y. Hernández, Yu Han, K. Tamada, Lain‐Jong Li (2017)
Graphene-Au nanoparticle based vertical heterostructures: A novel route towards high- ZT Thermoelectric devicesNano Energy, 38
Y. Hernández, V. Nicolosi, M. Lotya, F. Blighe, Zhenyu Sun, S. De, I. Mcgovern, B. Holland, Michelle Byrne, Y. Gun’ko, John Boland, Peter Niraj, G. Duesberg, Satheesh Krishnamurti, R. Goodhue, J. Hutchison, V. Scardaci, A. Ferrari, J. Coleman (2008)
High-yield production of graphene by liquid-phase exfoliation of graphite.Nature nanotechnology, 3 9
Yong Du, S. Shen, K. Cai, P. Casey (2012)
Research progress on polymer–inorganic thermoelectric nanocomposite materialsProgress in Polymer Science, 37
A. Balandin (2011)
Thermal properties of graphene and nanostructured carbon materials.Nature materials, 10 8
Y. Nakai, K. Honda, K. Yanagi, H. Kataura, T. Kato, Takahiro Yamamoto, Y. Maniwa (2014)
Giant Seebeck coefficient in semiconducting single-wall carbon nanotube filmApplied Physics Express, 7
Nanostructured materials have emerged as an alternative to enhance the figure of merit (ZT) of thermoelectric (TE) devices. Graphene exhibits a high electrical conductivity (in-plane) that is necessary for a high ZT; however, this effect is countered by its impressive thermal conductivity. In this work TE layered devices composed of electrochemically exfoliated graphene (EEG) and a phonon blocking material such as poly (3,4-ethylenedioxythiophene) polystyrene sulfonate (PEDOT:PSS), polyaniline (PANI) and gold nanoparticles (AuNPs) at the interface were prepared. The figure of merit, ZT, of each device was measured in the cross-plane direction using the Transient Harman Method (THM) and complemented with AFM-based measurements. The results show remarkable high ZT values (0.81 < ZT < 2.45) that are directly related with the topography, surface potential, capacitance gradient and resistance of the devices at the nanoscale.
2D Materials – IOP Publishing
Published: Jan 1, 2018
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