FRINK Linked Data Fragments server

Matches in SemOpenAlex for { <https://semopenalex.org/work/W2243356213> ?p ?o ?g. }

• W2243356213 endingPage "54" @default.
• W2243356213 startingPage "16" @default.
• W2243356213 abstract "Passive Solid State Nuclear Track Detectors (SSNTDs) have been employed successfully during the past two decades in space radiation studies due to their excellent physico-chemical properties. They are useful for charged particle detection in the linear energy transfer (LET) range above the threshold value of ~10 keV μm -1 . It was applicable for measurement of cosmic ray primary and secondary particles, including recoil nuclei, projectile and target fragments and secondary neutrons in past projects such as DOSMAP, BRADOS, ALTCRISS, Matroshka or recently in progress as SPD, DOSIS, as well as, in ground based experiment as Icchiban. The continuous development in the understanding of the track formation mechanism and improvement of detection techniques have resulted in the determination of the cosmic ray LET spectrum with less uncertainties and provided improved assessment of the dose burden of astronauts and helped to increase the effectiveness of radiation shielding of spaceships. Space dosimetry by nuclear track methodology stresses the advantages of passive systems for cosmic radiation field studies due to their robustness, compact dimensions, and complete independence from external power supply. SSNTDs cope also with requirement imposed by portable area monitoring or personal dose integrator to assess radiation risk of astronauts during intra or extra-vehicular activity. This review tries to provide a short summary about fundamentals and applications of space radiation studies using SSNTDs.Contents of Paper" @default.
• W2243356213 created "2016-06-24" @default.
• W2243356213 creator A5077238859 @default.
• W2243356213 creator A5089228491 @default.
• W2243356213 date "2015-08-01" @default.
• W2243356213 modified "2023-10-17" @default.
• W2243356213 title "Cosmic Radiation Detection by Solid State Nuclear Track Detector Technique" @default.
• W2243356213 cites W1966928085 @default.
• W2243356213 cites W1969433684 @default.
• W2243356213 cites W1974195611 @default.
• W2243356213 cites W1977222713 @default.
• W2243356213 cites W1977360126 @default.
• W2243356213 cites W1978884294 @default.
• W2243356213 cites W1979335128 @default.
• W2243356213 cites W1980101259 @default.
• W2243356213 cites W1980693040 @default.
• W2243356213 cites W1984892922 @default.
• W2243356213 cites W1985357141 @default.
• W2243356213 cites W1985929968 @default.
• W2243356213 cites W1986211591 @default.
• W2243356213 cites W1989565502 @default.
• W2243356213 cites W1995390999 @default.
• W2243356213 cites W2001329724 @default.
• W2243356213 cites W2003255983 @default.
• W2243356213 cites W2005731813 @default.
• W2243356213 cites W2006756291 @default.
• W2243356213 cites W2009003843 @default.
• W2243356213 cites W2009279410 @default.
• W2243356213 cites W2010779398 @default.
• W2243356213 cites W2012276727 @default.
• W2243356213 cites W2013762791 @default.
• W2243356213 cites W2014223120 @default.
• W2243356213 cites W2014295103 @default.
• W2243356213 cites W2014498039 @default.
• W2243356213 cites W2014819395 @default.
• W2243356213 cites W2018419408 @default.
• W2243356213 cites W2019509600 @default.
• W2243356213 cites W2022571952 @default.
• W2243356213 cites W2023690743 @default.
• W2243356213 cites W2026315665 @default.
• W2243356213 cites W2026539097 @default.
• W2243356213 cites W2029239779 @default.
• W2243356213 cites W2030383639 @default.
• W2243356213 cites W2032720526 @default.
• W2243356213 cites W2033747061 @default.
• W2243356213 cites W2034085771 @default.
• W2243356213 cites W2035154869 @default.
• W2243356213 cites W2036273480 @default.
• W2243356213 cites W2037772064 @default.
• W2243356213 cites W2039188463 @default.
• W2243356213 cites W2040677360 @default.
• W2243356213 cites W2043491939 @default.
• W2243356213 cites W2046145202 @default.
• W2243356213 cites W2051962521 @default.
• W2243356213 cites W2053944530 @default.
• W2243356213 cites W2054557693 @default.
• W2243356213 cites W2054564355 @default.
• W2243356213 cites W2057531996 @default.
• W2243356213 cites W2057601825 @default.
• W2243356213 cites W2059085722 @default.
• W2243356213 cites W2061139399 @default.
• W2243356213 cites W2062625750 @default.
• W2243356213 cites W2064558867 @default.
• W2243356213 cites W2064835429 @default.
• W2243356213 cites W2064918028 @default.
• W2243356213 cites W2065147392 @default.
• W2243356213 cites W2065160795 @default.
• W2243356213 cites W2066363534 @default.
• W2243356213 cites W2068075820 @default.
• W2243356213 cites W2073662795 @default.
• W2243356213 cites W2078121107 @default.
• W2243356213 cites W2080828761 @default.
• W2243356213 cites W2090277218 @default.
• W2243356213 cites W2092865167 @default.
• W2243356213 cites W2094333219 @default.
• W2243356213 cites W2094630249 @default.
• W2243356213 cites W2096801777 @default.
• W2243356213 cites W2101564240 @default.
• W2243356213 cites W2104821311 @default.
• W2243356213 cites W2105772189 @default.
• W2243356213 cites W2111598698 @default.
• W2243356213 cites W2116290390 @default.
• W2243356213 cites W2123979817 @default.
• W2243356213 cites W2124593125 @default.
• W2243356213 cites W2136029576 @default.
• W2243356213 cites W2138996966 @default.
• W2243356213 cites W2145613089 @default.
• W2243356213 cites W2155251159 @default.
• W2243356213 cites W2164272468 @default.
• W2243356213 cites W2167899630 @default.
• W2243356213 cites W2205206171 @default.
• W2243356213 cites W2313323869 @default.
• W2243356213 cites W2326078957 @default.
• W2243356213 cites W4230485732 @default.
• W2243356213 cites W4253056353 @default.
• W2243356213 doi "https://doi.org/10.4028/www.scientific.net/ssp.238.16" @default.
• W2243356213 hasPublicationYear "2015" @default.
• W2243356213 type Work @default.

• next