Experimentalist
- Name
- Antoine Pommerol
Previous
- Name
- Laboratoire de Planétologie de Grenoble (LPG)
- Experimentalist status
- Phd student
- Dates
- From 2005-10-01 to 2009-01-31
- Name
- Space Research & Planetary Sciences Division of the University of Bern (WP Unibe)
- Experimentalist status
- Post-doc
- Dates
- From 2009-02-01 to 2014-09-30
- Name
- Space Research & Planetary Sciences Division of the University of Bern (WP Unibe)
- Experimentalist status
- Researcher
- Dates
- From 2014-10-01
Previous
Current
- antoine.pommerol@space.unibe.ch
- Phone
- +41 31 631 39 98
- Samples
-
- Palagonite JSC Mars-1 with 5.16% adsorbed H2O
- Palagonite JSC Mars-1 with 5.07% adsorbed H2O
- Palagonite JSC Mars-1 with 5.26% adsorbed H2O
- Palagonite JSC Mars-1 with 5.42% adsorbed H2O
- Palagonite JSC Mars-1 with 5.56% adsorbed H2O
- Palagonite JSC Mars-1 with 5.64% adsorbed H2O
- Palagonite JSC Mars-1 with 5.98% adsorbed H2O
- Palagonite JSC Mars-1 with 6.38% adsorbed H2O
- Na-Montmorillonite SWy-2 - 0-25 mic grains
- Na-Montmorillonite SWy-2 - 25-50 mic grains
- Na-Montmorillonite SWy-2 - 50-100 mic grains
- Na-Montmorillonite SWy-2 - 200-280 mic grains
- Na-Montmorillonite SWy-2 - 100-200 mic grains
- Na-Montmorillonite SWy-2 - 280-400 mic grains
- Palagonite JSC Mars-1 with 6.70% adsorbed H2O
- Palagonite JSC Mars-1 with 7.11% adsorbed H2O
- Palagonite JSC Mars-1 with 7.55% adsorbed H2O
- Palagonite JSC Mars-1 with 7.56% adsorbed H2O
- Palagonite JSC Mars-1 with 8.18% adsorbed H2O
- Palagonite JSC Mars-1 with 8.56% adsorbed H2O
- Palagonite JSC Mars-1 with 8.98% adsorbed H2O
- Palagonite JSC Mars-1 with 9.71% adsorbed H2O
- Palagonite JSC Mars-1 with 10.08% adsorbed H2O
- Palagonite JSC Mars-1 with 10.58% adsorbed H2O
- Palagonite JSC Mars-1 with 10.69% adsorbed H2O
- Palagonite JSC Mars-1 with 10.85% adsorbed H2O
- Palagonite JSC Mars-1 with 10.88% adsorbed H2O - desorption
- Palagonite JSC Mars-1 with 10.70% adsorbed H2O - desorption
- Palagonite JSC Mars-1 with 10.14% adsorbed H2O - desorption
- Palagonite JSC Mars-1 with 10.17% adsorbed H2O - desorption
- Palagonite JSC Mars-1 with 9.66% adsorbed H2O - desorption
- Palagonite JSC Mars-1 with 9.14% adsorbed H2O - desorption
- Palagonite JSC Mars-1 with 8.91% adsorbed H2O - desorption
- Palagonite JSC Mars-1 with 8.48% adsorbed H2O - desorption
- Palagonite JSC Mars-1 with 7.83% adsorbed H2O - desorption
- Palagonite JSC Mars-1 with 7.40% adsorbed H2O - desorption
- Palagonite JSC Mars-1 with 7.19% adsorbed H2O - desorption
- Palagonite JSC Mars-1 with 6.36% adsorbed H2O - desorption
- Palagonite JSC Mars-1 with 6.39% adsorbed H2O - desorption
- Palagonite JSC Mars-1 with 6.09% adsorbed H2O - desorption
- Palagonite JSC Mars-1 with 6.17% adsorbed H2O - desorption
- Palagonite JSC Mars-1 with 5.95% adsorbed H2O - desorption
- Smectite SWy-2 with 1.44% adsorbed-interlayer H2O
- Smectite SWy-2 with 1.53% adsorbed-interlayer H2O
- Smectite SWy-2 with 1.61% adsorbed-interlayer H2O
- Smectite SWy-2 with 1.69% adsorbed-interlayer H2O
- Smectite SWy-2 with 1.81% adsorbed-interlayer H2O
- Smectite SWy-2 with 1.94% adsorbed-interlayer H2O
- Smectite SWy-2 with 2.29% adsorbed-interlayer H2O
- Smectite SWy-2 with 2.45% adsorbed-interlayer H2O
- Smectite SWy-2 with 3.00% adsorbed-interlayer H2O
- Smectite SWy-2 with 3.39% adsorbed-interlayer H2O
- Smectite SWy-2 with 3.32% adsorbed-interlayer H2O
- Smectite SWy-2 with 3.72% adsorbed-interlayer H2O
- Smectite SWy-2 with 4.56% adsorbed-interlayer H2O
- Smectite SWy-2 with 6.03% adsorbed-interlayer H2O
- Smectite SWy-2 with 7.76% adsorbed-interlayer H2O
- Smectite SWy-2 with 7.67% adsorbed-interlayer H2O
- Smectite SWy-2 with 5.82% adsorbed-interlayer H2O
- Smectite SWy-2 with 3.85% adsorbed-interlayer H2O
- Smectite SWy-2 with 2.73% adsorbed-interlayer H2O
- Smectite SWy-2 with 1.94% adsorbed-interlayer H2O
- Smectite SWy-2 with 1.74% adsorbed-interlayer H2O
- Volcanic tuff with 0.29% adsorbed H2O
- simulated Montmorillonite SWy-1 - 20 µm grains
- Montmorillonite STx-1 - 2 µm grains
- Volcanic tuff (Corent) 0-25µm
- Volcanic tuff (Corent) 100-200µm
- Volcanic tuff (Corent) 200-280µm
- Volcanic tuff (Corent) 25-50µm
- Volcanic tuff (Corent) 280-400µm
- Volcanic tuff (Corent) 400-560µm
- Volcanic tuff (Corent) 50-100µm
- Volcanic tuff (Corent) 560-800µm
- Volcanic tuff (Corent) 800-1120µm
- Volcanic tuff (Corent) 50-100µm
- Volcanic tuff with 0.77% adsorbed H2O
- Volcanic tuff with 0.79% adsorbed H2O
- Volcanic tuff with 0.79% adsorbed H2O
- Volcanic tuff with 0.82% adsorbed H2O
- Volcanic tuff with 0.86% adsorbed H2O
- Volcanic tuff with 0.90% adsorbed H2O
- Volcanic tuff with 0.96% adsorbed H2O
- Volcanic tuff with 0.98% adsorbed H2O
- Volcanic tuff with 0.99% adsorbed H2O
- Volcanic tuff with 0.89% adsorbed H2O
- Volcanic tuff with 0.72% adsorbed H2O
- Volcanic tuff with 0.56% adsorbed H2O
- Volcanic tuff with 0.43% adsorbed H2O
- Volcanic tuff with 0.52% adsorbed H2O
- Volcanic tuff with 0.58% adsorbed H2O
- Volcanic tuff with 0.63% adsorbed H2O
- Volcanic tuff with 0.67% adsorbed H2O
- Volcanic tuff with 0.70% adsorbed H2O
- Volcanic tuff with 0.72% adsorbed H2O
- Volcanic tuff with 0.74% adsorbed H2O
- JSC Mars-1 Mars soil simulant (Surface preparation type D)
- JSC Mars-1 Mars soil simulant (Surface preparation type A)
- JSC Mars-1 Mars soil simulant (Surface preparation type B)
- JSC Mars-1 Mars soil simulant (Surface preparation type C)
- Dry JSC Mars-1 Mars soil simulant (after wetting and drying experiment).
- Wet JSC Mars-1 Mars soil simulant (Step #2 in the drying sequence)
- Wet JSC Mars-1 Mars soil simulant (Step #3 in the drying sequence)
- Wet JSC Mars-1 Mars soil simulant (Step #4 in the drying sequence)
- Wet JSC Mars-1 Mars soil simulant (Step #5 in the drying sequence)
- Dry JSC Mars-1 soil simulant, before the wetting sequence.
- Wet JSC Mars-1 soil simulant (28 wt.% water, step #2 in the wetting sequence)
- Wet JSC Mars-1 soil simulant (32 wt.% water, step #3 in the wetting sequence)
- Wet JSC Mars-1 soil simulant (34 wt.% water, step #4 in the wetting sequence)
- Wet JSC Mars-1 soil simulant (39 wt.% water, step #5 in the wetting sequence)
- Hawaiian basaltic sand. Fine-grained fraction (less than 109 µm). Texture: smooth.
- Hawaiian basaltic sand. Fine-grained fraction (less than 109 µm). Texture: sprinkled.
- Hawaiian basaltic sand. Fine-grained fraction (less than 109 µm). Texture: smooth.
- Hawaiian basaltic sand. Fine-grained fraction (less than 109 µm). Texture: sprinkled.
- Hawaiian basaltic sand. Coarse-grained fraction (109 - 1000 µm)
- Hawaiian basaltic sand. Fine-grained fraction (less than 109 µm)
- Wet JSC Mars-1 soil simulant (8 wt.% water, step #1 in the wetting sequence)
- Wet JSC Mars-1 Mars soil simulant (Saturated with liquid water - Step #1 in the drying sequence)
- Matters
-
- Na-Montmorillonite SWy-2, 25-50 microns
- Na-Montmorillonite SWy-2, 50-100 microns
- Na-Montmorillonite SWy-2, 200-280 microns
- Na-Montmorillonite SWy-2, 280-400 microns
- Water ice spherical particles 4.5±2.5 μm
- Na-Montmorillonite SWy-2, 100-200 microns
- Na-Montmorillonite SWy-2, 0-25 microns
- Volcanic tuff / Corent - 100-200µm grains
- Volcanic tuff / Corent - 200-280µm grains
- Water ice spherical particles 67±31 μm
- Water ice spherical particles 2 to 100 μm (possibly 35±20 µm, to be confirmed)
- Volcanic tuff / Corent - 50-100µm grains
- Volcanic tuff / Corent - 280-400µm grains
- Volcanic tuff / Corent - 400-560µm grains
- Volcanic tuff / Corent - 560-800µm grains
- Volcanic tuff / Corent - 800-1120µm grains
- Spherical particles (67±31 μm diameter) of salty water ice produced by freezing droplets of a 20 wt.% MgSO4 solution in liquid nitrogen
- Spherical particles (67±31 μm diameter) of salty water ice produced by freezing droplets of a 20 wt.% NaCl solution in liquid nitrogen
- Spherical particles (67±31 μm diameter) of salty water ice produced by freezing droplets of a 30 wt.% MgSO4 solution in liquid nitrogen
- Spherical particles (67±31 μm diameter) of salty water ice produced by freezing droplets of a 10 wt.% NaCl solution in liquid nitrogen
- Spherical particles (67±31 μm diameter) of salty water ice produced by freezing droplets of a 12.5 wt.% MgCl2 solution in liquid nitrogen
- Spherical particles (67±31 μm diameter) of salty water ice produced by freezing droplets of a 3 wt.% Na2SO4 solution in liquid nitrogen
- Basaltic sand from Hawaii (grains smaller than 109 µm)
- Basaltic sand from Hawaii (grains in the range 109 - 1000 µm)
- Spherical particles (67±31 μm diameter) of salty water ice produced by freezing droplets of a 30 wt.% NaCl solution in liquid nitrogen
- Spherical particles (67±31 μm diameter) of salty water ice produced by freezing droplets of a 25 wt.% MgCl2 solution in liquid nitrogen
- Spherical particles (67±31 μm diameter) of salty water ice produced by freezing droplets of a 30 wt.% Na2SO4 solution in liquid nitrogen
- Spherical particles (67±31 μm diameter) of salty water ice produced by freezing droplets of a 33 wt.% MgCl2 solution in liquid nitrogen
- Spherical particles (67±31 μm diameter) of salty water ice produced by freezing droplets of a 10 wt.% NaCl solution in liquid nitrogen
- Spherical particles (67±31 μm diameter) of salty water ice produced by freezing droplets of a 10 wt.% MgSO4 solution in liquid nitrogen
- Spherical particles (67±31 μm diameter) of salty water ice produced by freezing droplets of a 15 wt.% Na2SO4 solution in liquid nitrogen