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Moisture and density (MAD) measured on IODP Hole 320-U1332B
Geocode = Depth CSF-A (m) -
Moisture and density (MAD) measured on IODP Hole 320-U1332A
Geocode = Depth CSF-A (m) -
Moisture and density (MAD) measured on IODP Hole 320-U1331A
Geocode = Depth CSF-A (m) -
Moisture and density (MAD) measured on IODP Hole 317-U1354C
Geocode = Depth CSF-A (m).MAD data are acquired on ~10 mL sediment or rock subsamples by measuring three out of four material parameters: wet (saturated) mass and/or volume, and... -
Moisture and density (MAD) measured on IODP Hole 317-U1354B
Geocode = Depth CSF-A (m).MAD data are acquired on ~10 mL sediment or rock subsamples by measuring three out of four material parameters: wet (saturated) mass and/or volume, and... -
Moisture and density (MAD) measured on IODP Hole 317-U1353B
Geocode = Depth CSF-A (m). MAD data are acquired on ~10 mL sediment or rock subsamples by measuring three out of four material parameters: wet (saturated) mass and/or volume,... -
Moisture and density (MAD) measured on IODP Hole 317-U1353A
Geocode = Depth CSF-A (m). MAD data are acquired on ~10 mL sediment or rock subsamples by measuring three out of four material parameters: wet (saturated) mass and/or volume,... -
Moisture and density (MAD) measured on IODP Hole 317-U1352C
Geocode = Depth CSF-A (m). MAD data are acquired on ~10 mL sediment or rock subsamples by measuring three out of four material parameters: wet (saturated) mass and/or volume,... -
Moisture and density (MAD) measured on IODP Hole 317-U1352B
Geocode = Depth CSF-A (m). MAD data are acquired on ~10 mL sediment or rock subsamples by measuring three out of four material parameters: wet (saturated) mass and/or volume,... -
Moisture and density (MAD) measured on IODP Hole 317-U1351B
Geocode = Depth CSF-A (m).MAD data are acquired on ~10 mL sediment or rock subsamples by measuring three out of four material parameters: wet (saturated) mass and/or volume, and... -
Moisture and density (MAD) measured on IODP Hole 317-U1351A
Geocode = Depth CSF-A (m).MAD data are acquired on ~10 mL sediment or rock subsamples by measuring three out of four material parameters: wet (saturated) mass and/or volume, and... -
Structural insights into crude oil asphaltenes II: Correlating molecular desc...
Asphaltenes are a complex and problematic fraction of crude oil that can precipitate, block pipeline and foul refineryequipment. Asphaltenes have a high proportion of aromatic... -
How molecular solids prepare for phase transitions: The phase transition in o...
Oxalyl chloride (mpt. 260 K), forms an ordered phase at low temperature, but a disordered phase between 250 K and the melting point. In previous beamtime we aimed to carry out... -
Towards a validated standard method for performing DFT calculations of muoniu...
In this proposal we want to address the issue of the identification of the different muonium adducts that are possible in Alq3 without any crystallographic constraints, and... -
How molecular solids prepare for phase transitions: The phase transition in o...
Oxalyl chloride, which is a liquid at RT, forms a disordered phase (I) on cooling to 260 K. This phase is unstable with respect to an ordered phase (II) below 250 K, but in... -
Lattice vibrations of hydrogen impurities in a solid neon matrix
In recent incoherent inelastic neutron scattering experiments we have shown that the anharmonic single-particle dynamics of H2 can be measured with high precision in quantum... -
Copy of: The Effect of Pressure on the Crystal Structure Titanium Tetrachloride
At ambient pressure and temperature TiCl4 is a fuming yellow liquid. On cooling it forma a solid composed of essentially isolated tetrahedral molecules; the same structure is...
