Factors affecting production rates of cosmogenic nuclides in extraterrestrial matter
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[1] R. Reedy,et al. Exposure history of the Sutter's Mill carbonaceous chondrite , 2014 .
[2] W. Kutschera. Applications of accelerator mass spectrometry , 2013 .
[3] Ingo Leya,et al. The Galactic Cosmic Ray Intensity over the Past 106–109 Years as Recorded by Cosmogenic Nuclides in Meteorites and Terrestrial Samples , 2011, Space Science Reviews.
[4] I. Leya,et al. Cosmogenic production rates and recoil loss effects in micrometeorites and interplanetary dust particles , 2013 .
[5] J. Ullmann,et al. Cross section measurements at neutron energies 71 and 112 MeV and energy integrated cross section measurements (0.1 < En < 750 MeV) for the neutron induced reactions O(n,x)10Be, Si(n,x)10Be, and Si(n,x)26Al , 2013 .
[6] R. Reedy,et al. Cosmic‐ray exposure history of the Norton County enstatite achondrite , 2011 .
[7] K. Nishiizumi,et al. Cosmogenic radionuclides in L5 and LL5 chondrites from Queen Alexandra Range, Antarctica: Identification of a large L/LL5 chondrite shower with a preatmospheric mass of approximately 50,000 kg , 2011 .
[8] R. Reedy,et al. Numerical simulations of production rates for 10Be, 26Al and 14C in extraterrestrial matter using the MCNPX code , 2010 .
[9] R. Reedy,et al. Solar cosmic ray records in lunar rock 64455 , 2009 .
[10] R. Reedy. Recent advances in studies of meteorites using cosmogenic radionuclides , 2004 .
[11] F. Phillips,et al. Terrestrial in situ cosmogenic nuclides: theory and application , 2001 .
[12] M. Suter,et al. Simulation of the interaction of galactic cosmic‐ray protons with meteoroids: On the production of radionuclides in thick gabbro and iron targets irradiated isotropically with 1.6 GeV protons , 2000 .
[13] K. Nishiizumi,et al. The 36Cl–36Ar–40K–41K records and cosmic ray production rates in iron meteorites , 1999 .
[14] D. Fink,et al. Complex exposure histories for meteorites with “short” exposure ages , 1997 .
[15] R. Reedy,et al. Depth profile of41Ca in an Apollo 15 drill core and the low-energy neutron flux in the Moon , 1997 .
[16] H. Matsuzaki,et al. New interpretation of the 10Be and 26Al content in cosmic spherules , 1997 .
[17] P. A. J. Englert,et al. MEASUREMENT OF PROTON PRODUCTION CROSS SECTIONS OF 10BE AND 26AL FROM ELEMENTS FOUND IN LUNAR ROCKS , 1997 .
[18] R. Reedy,et al. Exposure history of lunar meteorites Queen Alexandra Range 93069 and 94269 , 1996 .
[19] G. Heusser,et al. Aluminum‐26, sodium‐22 and cobalt‐60 in two drill cores and some other samples of the Jilin chondrite , 1996 .
[20] R. Reedy,et al. Cosmogenic 53Mn in the main fragment of the Norton County aubrite , 1995 .
[21] Robert C. Reedy,et al. Effects of bulk composition on nuclide production processes in meteorites , 1994 .
[22] R. Reedy,et al. Exposure histories of lunar meteorites: ALHA81005, MAC88104, MAC88105, and Y791197 , 1991 .
[23] D. Brownlee,et al. Exposure history of individual cosmic particles , 1991 .
[24] R. Reedy,et al. Cosmogenic nuclides in extraterrestrial materials , 1990 .
[25] R. Reedy. Nuclide production by primary cosmic‐ray protons , 1987 .
[26] R. Reedy,et al. Cosmogenic neutron-capture-produced nuclides in stony meteorites , 1986 .
[27] P. Englert,et al. Conditions of the cosmic ray exposure of the Jilin chondrite , 1985 .
[28] R. Reedy,et al. Beryllium-10 contents of core samples from the St. Severin meteorite , 1984 .
[29] H. P. Rickman,et al. Asteroids comets meteors , 1984 .
[30] K. Nishiizumi. Measurement of53Mn in deep-sea iron and stony spherules , 1983 .
[31] R. Reedy,et al. Cosmic-Ray Record in Solar System Matter , 1983, Science.
[32] R. Reedy,et al. Alpha Particles in Solar Cosmic Rays over the Last 80,000 Years , 1973, Science.
[33] R. Reedy,et al. Interaction of solar and galactic cosmic-ray particles with the Moon , 1972 .
[34] M. Honda. Spallation products distributed in a thick iron target bombarded by 3-Bev protons , 1962 .
[35] D. Lal,et al. Record of cosmic-ray intensity in the meteorites , 1961 .