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Temperature-dependent thermal inertia of homogeneous Martian regolith
Sylvain Piqueux,
Philip Christensen
Earth and Space Exploration, School of (SESE)
Physics
Research output
:
Contribution to journal
›
Article
›
peer-review
48
Scopus citations
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Physics & Astronomy
regolith
97%
inertia
67%
conductivity
45%
soils
23%
solid phases
21%
temperature
20%
mars
18%
specific heat
17%
Mars exploration
13%
thermal conductivity
11%
grain size
11%
atmospheric temperature
10%
thermophysical properties
8%
cements
8%
gases
7%
surface temperature
7%
atmospheric pressure
6%
surface layers
6%
porosity
5%
room temperature
4%
curves
4%
predictions
4%
Earth & Environmental Sciences
regolith
77%
inertia
71%
conductivity
50%
temperature
25%
Mars
19%
material
16%
thermal conductivity
14%
grain size
10%
soil
8%
gas
7%
atmospheric pressure
6%
surface layer
6%
surface temperature
5%
air temperature
5%
cement (construction material)
5%
in situ
4%
prediction
3%
modeling
2%
Chemical Compounds
Inertia
100%
Conductivity
45%
Soil
19%
Heat
17%
Thermal Conductivity
14%
Grain Size
14%
Gas
12%
Surface Temperature
9%
Specific Density
9%
Thermodynamic Property
6%
Shape
5%
Pressure
4%
Ambient Reaction Temperature
4%
Time
2%
Surface
2%