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A finite-temperature continuum theory based on interatomic potentials
H. Jiang, Y. Huang, K. C. Hwang
Research output
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Contribution to journal
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Article
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peer-review
87
Scopus citations
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Dive into the research topics of 'A finite-temperature continuum theory based on interatomic potentials'. Together they form a unique fingerprint.
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Chemical Compounds
Interatomic Potential
100%
Thermal Expansion
24%
Young's Modulus
23%
Diamond
21%
Single Walled Nanotube
20%
Entropy
18%
Heat
16%
Graphene
16%
Strain
15%
Physics & Astronomy
continuums
49%
temperature dependence
21%
temperature
20%
thermal expansion
14%
carbon nanotubes
14%
graphene
13%
modulus of elasticity
13%
diamonds
13%
specific heat
13%
entropy
12%
harmonics
11%
vibration
11%
coefficients
9%
approximation
8%
Engineering & Materials Science
Temperature
27%
Graphene
13%
Carbon nanotubes
11%
Specific heat
11%
Thermal expansion
11%
Constitutive models
11%
Diamonds
11%
Elastic moduli
9%
Entropy
9%