D.B. Larson scite author profile

D.B. Larson

5Publications

135Citation Statements Received

7Citation Statements Given

How they've been cited

199

123

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Affiliations

Lawrence Livermore National Laboratory, Louisiana State University

Publications

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Shock-Wave Studies Of Ice Under Uniaxial Strain Conditions

Larson

1984

J. Glaciol.

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Shock-wave studies of ice under uniaxial strain conditions have been conducted at stress levels up to 3.6 GPa. A light-gas gun accelerated the flat-faced projectile used to impact the ice-containing targets. The ice samples were initially at ambient pressure and at temperatures of –10 ± 2° C. Gages were implaced at different distances in the ice along the path of the shock wave to measure particle velocity time histories inside the ice samples. The recorded time histories of particle velocity show a precursor wave with an average wave velocity of 3.7 km/s and an average particle velocity amplitude of 0.06 km/s. This wave is travelling at a wave velocity approximately 10% greater than longitudinal sound speed and is believed to originate because of the onset of melting of ice I.The particle velocity data from these experiments were converted to stresses and volumes using Lagrangian gage analysis and the assumption of a simple non-steady wave. This conversion provides a complete compression cycle (which includes both loading and unloading paths) for comparison with static measurements. All experiments show the onset of melting at 0.15 to 0.2 GPa. Experiments with maximum stress states between 0.2 and 0.5 GPa yield results which suggest that a mixed phase of ice I and liquid water exists at these conditions. For maximum loading stresses between 0.6 and 1.7 GPa the experimental results suggest that the final state is predominately ice VI. In these experiments the specific volume upon compression is changed from 1.09 m3/Mg to approximately 0.76 m3/Mg, which represents compaction of approximately 30%. The unloading paths determined from these experiments indicate that ice VI remains in a “frozen” or metastable state during most of the unloading process. This hysteresis in the compression cycle gives rise to a large “loss” of shock-wave energy to the transformation process. At stress levels above 2.2 GPa, ice VII should be the stable form for water according to static compression measurements. Experimental data at 2.4 and 3.6 GPa suggest that ice VII may be formed but these results indicate a mixed phase of ice VI and ice VII rather than complete transformation to ice VII.

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Electronic spectra of ruthenium and osmium tetroxides

Foster¹,

Felps²,

Johnson³

et al. 1973

J. Am. Chem. Soc.

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Plane shock wave studies of porous geologic media

Larson¹,

Anderson²

1979

J. Geophys. Res.

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Plane shock wave experiments have been conducted on two highly porous rocks, Mount Helen tuff and Indiana limestone, in both dry and water-saturated states up to stress levels of about 4 GPa. A light-gas gun was used to load the sample in uniaxial strain, and the subsequent wave motion was monitored with particle-velocity gages. All four materials studied show evidence of time-dependent behavior. The timedependent behavior in the highly porous dry rocks is associated with the closing of pores. The strong time dependence observed in these materials would seem to preclude the use of quasi-static data in constitutive models that are used to describe dynamic processes. In the water-saturated rocks the time dependence is associated with the water, which shows no indication of transformation to the high-pressure ice phases in the time frame of these shock wave experiments. This suggests the possibility of a metastable form of water existing under dynamic conditions.

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Very High Pressure Effects upon the EPR Spectrum of Ruby

Nelson

Larson

Gardner

1967

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The variation in the electron paramagnetic resonance (EPR) spectrum of ruby as a function of pressure has been observed to beyond 70 kbar for a magnetic field orientation parallel to the crystalline c axis. The data can be interpreted in terms of the usual spin Hamiltonian: H=g||βHzSz−12δ(Sz2−13S2), where the spectroscopic splitting factor g‖ has the same value as at ambient pressures, but where the zero-field splitting δ increases in a linear fashion from ∼0.38 to ∼0.43 cm−1. The experimental apparatus has been described previously, although important improvements in the pressure seal and in the pressure calibration have been made and are described in an Appendix.

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A Shock-Induced Phase Transformation in Bismuth

Larson¹

1967

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A study was made of the shock-induced phase transformation in bismuth at 25 kbar. A quartz pressure-gauge technique was used to obtain the experimental data. A previously reported disagreement between the dynamic and the static transition pressure is due in part to a strength-of-material correction. The remaining discrepancy is probably due to a systematic error in the earlier dynamic study. The observed dynamic transition pressures corrected for strength-of-material effects and corrected to 25°C were 25.4 kbar for isotropic bismuth, and 25.9 kbar for cast bismuth. These values agree nicely with the value 25.4 kbar obtained by static compression. Hugoniot elastic limits of 2.4 to 3.1 kbar were observed for the different types of samples.

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D.B. Larson

Shock-Wave Studies Of Ice Under Uniaxial Strain Conditions

Electronic spectra of ruthenium and osmium tetroxides

Plane shock wave studies of porous geologic media

Very High Pressure Effects upon the EPR Spectrum of Ruby

A Shock-Induced Phase Transformation in Bismuth

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