Add to ORKGWe determined concentration profiles of Ne-21, Ne-22, and Ar-38 produced by solar protons as a function of depth in oriented lunar rock 68815. A comparison with model predictions indicate a solar proton flux J(4(pi)(r); E greater than 10 MeV) of 100-125 p/sq. cm/s and a rigidity, R sub 0, of 85-100 MV, assuming an erosion rate of 1-2 mm/Myr. These results for 68815 and similar results on 61016 define the integrated solar proton energy spectrum at the moon over the past approximately 2 Myr
High energy cosmic rays constantly bombard the lunar regolith, producing (via nuclear evaporation) s...
Aims. Lunar soil and rocks are not protected by a magnetic field or an atmosphere and are continuous...
Abstract Aims: Lunar soil and rocks are not protected by a magnetic field or an atmosphere and are c...
Recent results on cosmic ray interactions in lunar samples and meteorites resulting in productio...
Abstract Direct measurements of solar energetic particles (SEP) cover the space era of several deca...
[1] Neutrons emitted from the Moon are produced by the impact of galactic cosmic rays (GCRs) within ...
Abstract Direct measurements of solar energetic particles (SEP) became possible only in the space e...
The authors have measured the concentrations of 26Al in lunar rock samples 15555,859 and 60025,28 wi...
Methods were developed earlier to deduce the composition of solar flare neon and to determine the so...
In three sets of irradiations at Texas A and M's Variable Energy Cyclotron, stacks of thin Mg, Al, S...
High-resolution stepped heating has been used to extract light noble gases implanted in a suite of 1...
Cosmic rays penetrate the lunar surface and interact with the lunar rocks to produce both radionucli...
Solar proton fluxes have been deduced from Al-26 depth profile resulting mainly from their interacti...
The authors have measured the concentrations of Al-26 in lunar rock samples 15555,859 and 60025,28 w...
Cosmic-ray produced C-14 (t(sub 1/2) = 5730 years), 36Cl (3.01 x 10(exp 5 years), Al-26 (7.05 x 10(e...
High energy cosmic rays constantly bombard the lunar regolith, producing (via nuclear evaporation) s...
Aims. Lunar soil and rocks are not protected by a magnetic field or an atmosphere and are continuous...
Abstract Aims: Lunar soil and rocks are not protected by a magnetic field or an atmosphere and are c...
Recent results on cosmic ray interactions in lunar samples and meteorites resulting in productio...
Abstract Direct measurements of solar energetic particles (SEP) cover the space era of several deca...
[1] Neutrons emitted from the Moon are produced by the impact of galactic cosmic rays (GCRs) within ...
Abstract Direct measurements of solar energetic particles (SEP) became possible only in the space e...
The authors have measured the concentrations of 26Al in lunar rock samples 15555,859 and 60025,28 wi...
Methods were developed earlier to deduce the composition of solar flare neon and to determine the so...
In three sets of irradiations at Texas A and M's Variable Energy Cyclotron, stacks of thin Mg, Al, S...
High-resolution stepped heating has been used to extract light noble gases implanted in a suite of 1...
Cosmic rays penetrate the lunar surface and interact with the lunar rocks to produce both radionucli...
Solar proton fluxes have been deduced from Al-26 depth profile resulting mainly from their interacti...
The authors have measured the concentrations of Al-26 in lunar rock samples 15555,859 and 60025,28 w...
Cosmic-ray produced C-14 (t(sub 1/2) = 5730 years), 36Cl (3.01 x 10(exp 5 years), Al-26 (7.05 x 10(e...
High energy cosmic rays constantly bombard the lunar regolith, producing (via nuclear evaporation) s...
Aims. Lunar soil and rocks are not protected by a magnetic field or an atmosphere and are continuous...
Abstract Aims: Lunar soil and rocks are not protected by a magnetic field or an atmosphere and are c...