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Electromagnetic interactions of cosmic rays with nuclei (1989)

Norbury, John W.

In: CASI

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Publication Date: 2013-08-31

Description: Parameterizations of single nucleon emission from the electromagnetic interactions of cosmic rays with nuclei are presented. These parameterizations are based upon the most accurate theoretical calculations available today. When coupled with Strong interaction parameterizations, they should be very suitable for use in cosmic ray propagation through intersteller space, the Earth's atmosphere, lunar samples, meteorites and spacecraft walls.

Keywords: SPACE RADIATION

Type: Photonuclear Absorption Cross Sections 22 p(SEE N89-29159 23-72); Photonuclear Absorpt

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2

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Transport methods and interactions for space radiations (1993)

Townsend, Lawrence W. ; Simonsen, Lisa C. ; Schimmerling, Walter ; [et al.]

In: Other Sources

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Publication Date: 2019-01-25

Description: This report presents a brief history leading to the involvement of the Langley Research Center of the National Aeronautics and Space Administration (NASA) in space-radiation physics and protection. Indeed, a relatively complete summary of technical capability as of the summer of 1990 is given. The Boltzmann equations for coupled ionic and neutronic fields are presented and inversion techniques for the Boltzmann operator are discussed. Errors generated by the straight ahead approximation are derived and are shown to be negligible for most problems of space-radiation protection. A decoupling of projectile propagation from the target fields greatly simplifies the Boltzmann equations and allows an analytic solution of the target fragment transport. Analytic and numerical methods of solving the projectile transport equations are discussed. The nuclear physics underlying the coefficients in the Boltzmann equation is discussed. A coupled-channel optical model is found as a consequence of the loose binding of nuclear matter and closure of the nuclear states in high-energy reactions. Transport solutions with the developed data base are used with laboratory experiments to validate both the transport code and the data base. Numerical benchmarks and comparison with Monte Carlo calculations are also used for code validation.

Keywords: SPACE RADIATION

Type: ; : Spaceflight mechan

Format: text

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3

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Cross section parameterizations for cosmic ray nuclei. 1: Single nucleon removal (1992)

Townsend, Lawrence W. ; Norbury, John W.

In: CASI

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Publication Date: 2019-06-28

Description: Parameterizations of single nucleon removal from electromagnetic and strong interactions of cosmic rays with nuclei are presented. These parameterizations are based upon the most accurate theoretical calculations available to date. They should be very suitable for use in cosmic ray propagation through interstellar space, the Earth's atmosphere, lunar samples, meteorites, spacecraft walls and lunar and martian habitats.

Keywords: SPACE RADIATION

Type: Electromagnetic Processes in Nucleus-Nucleus Collisions Relating to Space Radiation Research; 24 p

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Transport methods and interactions for space radiations (1991)

Wilson, John W. ; Simonsen, Lisa C. ; Nealy, John E. ; [et al.]

In: CASI

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Publication Date: 2019-06-28

Description: A review of the program in space radiation protection at the Langley Research Center is given. The relevant Boltzmann equations are given with a discussion of approximation procedures for space applications. The interaction coefficients are related to solution of the many-body Schroedinger equation with nuclear and electromagnetic forces. Various solution techniques are discussed to obtain relevant interaction cross sections with extensive comparison with experiments. Solution techniques for the Boltzmann equations are discussed in detail. Transport computer code validation is discussed through analytical benchmarking, comparison with other codes, comparison with laboratory experiments and measurements in space. Applications to lunar and Mars missions are discussed.

Keywords: SPACE RADIATION

Type: NASA-RP-1257 , L-16882 , NAS 1.61:1257

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Fully energy-dependent HZETRN (a galactic cosmic-ray transport code) (1992)

Shinn, Judy L. ; John, Sarah ; Norbury, John W. ; [et al.]

In: CASI

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Publication Date: 2019-06-28

Description: For extended manned space missions, the radiation shielding design requires efficient and accurate cosmic-ray transport codes that can handle the physics processes in detail. The Langley Research Center galactic cosmic-ray transport code (HZETRN) is currently under development for such design use. The cross sections for the production of secondary nucleons in the existing HZETRN code are energy dependent only for nucleon collisions. The approximation of energy-independent, heavy-ion fragmentation cross section is now removed by implementing a mathematically simplified energy-dependent stepping formalism for heavy ions. The cross section at each computational grid is obtained by linear interpolation from a few tabulated data to minimize computing time. Test runs were made for galactic cosmic-ray transport through a liquid hydrogen shield and a water shield at solar minimum. The results show no appreciable change in total fluxes or computing time compared with energy-independent calculations. Differences in high LET (linear energy transfer) spectra are noted, however, because of the large variation in cross sections at the low-energy region. The high LET components are significantly higher in the new code and have important implications on biological risk estimates for heavy-ion exposure.

Keywords: SPACE RADIATION

Type: NASA-TP-3243 , L-17103 , NAS 1.61:3243

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Cross section parameterizations for cosmic ray nuclei. I - Single nucleon removal (1993)

Townsend, Lawrence W. ; Norbury, John W.

In: Other Sources

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Publication Date: 2019-07-13

Description: Parameterizations of single nucleon removal from electromagnetic and strong interactions of cosmic rays with nuclei are presented. These parameterizations are based upon the most accurate theoretical calculations available to date. They should be very suitable for use in cosmic ray propagation through interstellar space, the Earth's atmosphere, lunar samples, meteorites, spacecraft walls and lunar and Martian habitats.

Keywords: SPACE RADIATION

Type: Astrophysical Journal Supplement Series (ISSN 0067-0049); 86; 1; p. 307-312.

Format: text

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GCR Simulator Reference Field and a Spectral Approach for Laboratory Simulation (2015)

Blattnig, Steve R. ; Walker, Steven A. ; Slaba, Tony C. ; [et al.]

In: CASI

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Publication Date: 2019-07-12

Description: The galactic cosmic ray (GCR) simulator at the NASA Space Radiation Laboratory (NSRL) is intended to deliver the broad spectrum of particles and energies encountered in deep space to biological targets in a controlled laboratory setting. In this work, certain aspects of simulating the GCR environment in the laboratory are discussed. Reference field specification and beam selection strategies at NSRL are the main focus, but the analysis presented herein may be modified for other facilities. First, comparisons are made between direct simulation of the external, free space GCR field and simulation of the induced tissue field behind shielding. It is found that upper energy constraints at NSRL limit the ability to simulate the external, free space field directly (i.e. shielding placed in the beam line in front of a biological target and exposed to a free space spectrum). Second, variation in the induced tissue field associated with shielding configuration and solar activity is addressed. It is found that the observed variation is likely within the uncertainty associated with representing any GCR reference field with discrete ion beams in the laboratory, given current facility constraints. A single reference field for deep space missions is subsequently identified. Third, an approach for selecting beams at NSRL to simulate the designated reference field is presented. Drawbacks of the proposed methodology are discussed and weighed against alternative simulation strategies. The neutron component and track structure characteristics of the simulated field are discussed in this context.

Keywords: Space Radiation; Aerospace Medicine

Type: NASA/TP-2015-218698 , L-20550 , NF1676L-20124

Format: application/pdf

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