Cited Article: Ghosh, S. Carbon nanotube flow sensors
Alert Expires: 09 NOV 2010
Number of Citing Articles: 3 new records this week (3 in this e-mail)
Organization ID: 3b97d1bbc1878baed0ab183d8b03130b
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Title:
Molecular Dynamics Simulation of Composite Nanochannels as Nanopumps Driven by Symmetric Temperature Gradients
Authors:
Liu, C; Li, ZG
Author Full Names:
Liu, Chong; Li, Zhigang
Source:
PHYSICAL REVIEW LETTERS 105 (17): Art. No. 174501 OCT 18 2010
Language:
English
Document Type:
Article
KeyWords Plus:
BOUNDARY-CONDITIONS; FLOW; SLIP
Abstract:
In this Letter, we propose a composite nanochannel system, where half of the channel is of low surface energy, while the other half has a relatively high surface energy. Molecular dynamics simulations show that fluids in such channels can be continuously driven by a symmetric temperature gradient. In the low surface energy part, the fluid moves from high to low temperature, while the fluid migrates from low to high temperature in the high surface energy part. The mechanisms that govern the flow are explained and the conditions required to guarantee the flow and the possible applications are discussed.
Reprint Address:
Liu, C, Hong Kong Univ Sci & Technol, Dept Mech Engn, Kowloon, Hong Kong, Peoples R China.
Research Institution addresses:
[Liu, Chong; Li, Zhigang] Hong Kong Univ Sci & Technol, Dept Mech Engn, Kowloon, Hong Kong, Peoples R China
E-mail Address:
mezli@ust.hk
Cited References:
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RAUSCHER M, 2007, PHYS REV LETT, V98, ARTN 224504.
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Cited Reference Count:
22
Times Cited:
0
Publisher:
AMER PHYSICAL SOC; ONE PHYSICS ELLIPSE, COLLEGE PK, MD 20740-3844 USA
Subject Category:
Physics, Multidisciplinary
ISSN:
0031-9007
DOI:
10.1103/PhysRevLett.105.174501
IDS Number:
665SB
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Title:
Molecular Dynamics Simulation of Composite Nanochannels as Nanopumps Driven by Symmetric Temperature Gradients
Authors:
Liu, C; Li, ZG
Author Full Names:
Liu, Chong; Li, Zhigang
Source:
PHYSICAL REVIEW LETTERS 105 (17): - OCT 18 2010
Language:
English
Document Type:
Article
KeyWords Plus:
BOUNDARY-CONDITIONS; FLOW; SLIP
Abstract:
In this Letter, we propose a composite nanochannel system, where half of the channel is of low surface energy, while the other half has a relatively high surface energy. Molecular dynamics simulations show that fluids in such channels can be continuously driven by a symmetric temperature gradient. In the low surface energy part, the fluid moves from high to low temperature, while the fluid migrates from low to high temperature in the high surface energy part. The mechanisms that govern the flow are explained and the conditions required to guarantee the flow and the possible applications are discussed.
Reprint Address:
Liu, C, Hong Kong Univ Sci & Technol, Dept Mech Engn, Kowloon, Hong Kong, Peoples R China.
Research Institution addresses:
[Liu, Chong; Li, Zhigang] Hong Kong Univ Sci & Technol, Dept Mech Engn, Kowloon, Hong Kong, Peoples R China
E-mail Address:
mezli@ust.hk
Cited References:
ALLEN MP, 1987, COMPUTER SIMULATION.
BRZOSKA JB, 1993, LANGMUIR, V9, P2220.
CHAUDHURY MK, 1992, SCIENCE, V256, P1539.
CIEPLAK M, 2001, PHYS REV LETT, V86, P803.
DARHUBER AA, 2005, ANNU REV FLUID MECH, V37, P425, DOI 10.1146/annurev.fluid.36.050802.122052.
DUKE TAJ, 1998, PHYS REV LETT, V80, P1552.
GARIMELLA SV, 2006, MICROELECTRON J, V37, P1165, DOI 10.1016/j.mejo.2005.07.017.
GHOSH S, 2003, SCIENCE, V299, P1042, DOI 10.1126/science.1079080.
GONG XJ, 2007, NAT NANOTECHNOL, V2, P709, DOI 10.1038/nnano.2007.320.
GUTTENBERG Z, 2004, PHYS REV E 2, V70, ARTN 056311.
HEINBUCH U, 1989, PHYS REV A, V40, P1144.
LI ZG, 2005, PHYS REV LETT, V95, ARTN 014502.
LI ZG, 2007, J CHEM PHYS, V127, P74706, ARTN 074706.
LI ZG, 2009, PHYS REV E 1, V80, ARTN 061204.
LIU C, 2009, PHYS REV E 2, V80, ARTN 036302.
PENNATHUR S, 2005, ANAL CHEM, V77, P6782, DOI 10.1021/ac0508346.
RAUSCHER M, 2007, PHYS REV LETT, V98, ARTN 224504.
SQUIRES TM, 2005, REV MOD PHYS, V77, P977.
THOMPSON PA, 1990, PHYS REV A, V41, P6830.
TODD BD, 1995, PHYS REV E, V52, P1627.
TRAVIS KP, 1997, PHYS REV E, V55, P4288.
VORONOV RS, 2006, J CHEM PHYS, V124, ARTN 204701.
Cited Reference Count:
22
Times Cited:
0
Publisher:
AMER PHYSICAL SOC; ONE PHYSICS ELLIPSE, COLLEGE PK, MD 20740-3844 USA
Subject Category:
Physics, Multidisciplinary
ISSN:
0031-9007
IDS Number:
665SB
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Title:
Carbon nanotube-guided thermopower waves
Authors:
Choi, W; Abrahamson, JT; Strano, JM; Strano, MS
Author Full Names:
Choi, Wonjoon; Abrahamson, Joel T.; Strano, Jennifer M.; Strano, Michael S.
Source:
MATERIALS TODAY 13 (10): 22-33 OCT 2010
Language:
English
Document Type:
Review
KeyWords Plus:
DIMENSIONAL THERMOELECTRIC-MATERIALS; RDX FLAME STRUCTURE; TRANSPORT-PROPERTIES; TELLURIDE NANOWIRES; HYDROGEN GENERATOR; SILICON NANOWIRES; POWER-GENERATION; BI NANOWIRES; COMBUSTION; IGNITION
Abstract:
Thermopower waves are a new concept for the direct conversion of chemical to electrical energy. A nanowire with large axial thermal diffusivity can accelerate a self-propagating reaction wave using a fuel coated along its length. The reaction wave drives electrical carriers in a thermopower wave, creating a high-power pulse of as much as 7 kW/kg in experiments using carbon nanotubes. We review nanomaterials designed to overcome limitations of thermoelectricity and explore the emerging scientific and practical outlook for devices using thermopower waves.
Reprint Address:
Strano, MS, MIT, Dept Chem Engn, Cambridge, MA 02139 USA.
Research Institution addresses:
[Choi, Wonjoon; Abrahamson, Joel T.; Strano, Jennifer M.; Strano, Michael S.] MIT, Dept Chem Engn, Cambridge, MA 02139 USA; [Choi, Wonjoon] MIT, Dept Mech Engn, Cambridge, MA 02139 USA
E-mail Address:
strano@mit.edu
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Cited Reference Count:
76
Times Cited:
0
Publisher:
ELSEVIER SCI LTD; THE BOULEVARD, LANGFORD LANE, KIDLINGTON, OXFORD OX5 1GB, OXON, ENGLAND
Subject Category:
Materials Science, Multidisciplinary
ISSN:
1369-7021
IDS Number:
665QB
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