SemOpenAlex |

SemOpenAlex

Matches in SemOpenAlex for { <https://semopenalex.org/work/W1969318845> ?p ?o ?g. }

Showing items 1 to 100 of ±130 with 100 items per page.

W1969318845 endingPage "A268" @default.
W1969318845 startingPage "A253" @default.
W1969318845 abstract "Crystals of CdTe containing 1 mole% of Mn, Fe, or ZnTe have been grown from the melt. The segregation coefficients of these impurities and of Co can be understood in terms of differences in the covalent, tetrahedral radii of the various metal atoms. The thermal conductivity, $K$, of these crystals and of pure CdTe has been measured from 3 to 300ifmmode^circelsetextdegreefi{}K. A table of $K$ values for pure CdTe is given; its $K=0.075$ W/cm deg at 300ifmmode^circelsetextdegreefi{}K. The heat transport in pure CdTe is due to phonons, and is limited by phonon scattering by crystal boundaries, isotopes, and other phonons. The local lattice distortions, which are nearly the same for Mn, Fe, and Zn, produce an additional nonmagnetic phonon scattering in the doped crystals. There is also a magnetic scattering, particularly pronounced for the Fe with a $3{d}^{6}$ configuration, caused by phonon assisted transitions between various low lying energy levels of the $d$-shell electrons. The nature and spacing of these levels can be predicted by crystal field theory, and there is qualitative agreement between this theory and the experimental results." @default.
W1969318845 created "2016-06-24" @default.
W1969318845 creator A5026481827 @default.
W1969318845 creator A5084008525 @default.
W1969318845 date "1964-01-06" @default.
W1969318845 modified "2023-10-16" @default.
W1969318845 title "Thermal Conductivity and Phonon Scattering by Magnetic Impurities in CdTe" @default.
W1969318845 cites W1964575740 @default.
W1969318845 cites W1973071522 @default.
W1969318845 cites W1974876027 @default.
W1969318845 cites W1976962612 @default.
W1969318845 cites W1977527861 @default.
W1969318845 cites W1977820423 @default.
W1969318845 cites W1980435718 @default.
W1969318845 cites W1984307486 @default.
W1969318845 cites W1984784200 @default.
W1969318845 cites W1992734052 @default.
W1969318845 cites W1996859473 @default.
W1969318845 cites W2000989651 @default.
W1969318845 cites W2002590781 @default.
W1969318845 cites W2007046627 @default.
W1969318845 cites W2009211833 @default.
W1969318845 cites W2009468562 @default.
W1969318845 cites W2010624997 @default.
W1969318845 cites W2011240564 @default.
W1969318845 cites W2013203280 @default.
W1969318845 cites W2020825456 @default.
W1969318845 cites W2023138557 @default.
W1969318845 cites W2028649807 @default.
W1969318845 cites W2029741576 @default.
W1969318845 cites W2030891950 @default.
W1969318845 cites W2032670833 @default.
W1969318845 cites W2035491353 @default.
W1969318845 cites W2036217842 @default.
W1969318845 cites W2038999627 @default.
W1969318845 cites W2041949235 @default.
W1969318845 cites W2045096662 @default.
W1969318845 cites W2047399708 @default.
W1969318845 cites W2048490172 @default.
W1969318845 cites W2055836322 @default.
W1969318845 cites W2057844576 @default.
W1969318845 cites W2065252673 @default.
W1969318845 cites W2065723764 @default.
W1969318845 cites W2067029818 @default.
W1969318845 cites W2073965476 @default.
W1969318845 cites W2074403907 @default.
W1969318845 cites W2080584923 @default.
W1969318845 cites W2092767749 @default.
W1969318845 cites W2117987473 @default.
W1969318845 cites W2118277741 @default.
W1969318845 cites W2119860281 @default.
W1969318845 cites W2136305500 @default.
W1969318845 cites W2157987022 @default.
W1969318845 cites W2161583775 @default.
W1969318845 cites W2315166914 @default.
W1969318845 cites W2469179594 @default.
W1969318845 cites W2484140560 @default.
W1969318845 cites W2808407003 @default.
W1969318845 cites W3015932821 @default.
W1969318845 cites W3123018364 @default.
W1969318845 cites W4242160924 @default.
W1969318845 doi "https://doi.org/10.1103/physrev.133.a253" @default.
W1969318845 hasPublicationYear "1964" @default.
W1969318845 type Work @default.
W1969318845 sameAs 1969318845 @default.
W1969318845 citedByCount "300" @default.
W1969318845 countsByYear W19693188452012 @default.
W1969318845 countsByYear W19693188452013 @default.
W1969318845 countsByYear W19693188452014 @default.
W1969318845 countsByYear W19693188452015 @default.
W1969318845 countsByYear W19693188452016 @default.
W1969318845 countsByYear W19693188452017 @default.
W1969318845 countsByYear W19693188452018 @default.
W1969318845 countsByYear W19693188452019 @default.
W1969318845 countsByYear W19693188452020 @default.
W1969318845 countsByYear W19693188452021 @default.
W1969318845 countsByYear W19693188452022 @default.
W1969318845 countsByYear W19693188452023 @default.
W1969318845 crossrefType "journal-article" @default.
W1969318845 hasAuthorship W1969318845A5026481827 @default.
W1969318845 hasAuthorship W1969318845A5084008525 @default.
W1969318845 hasConcept C120665830 @default.
W1969318845 hasConcept C121332964 @default.
W1969318845 hasConcept C159985019 @default.
W1969318845 hasConcept C191486275 @default.
W1969318845 hasConcept C192562407 @default.
W1969318845 hasConcept C199360897 @default.
W1969318845 hasConcept C24169881 @default.
W1969318845 hasConcept C26873012 @default.
W1969318845 hasConcept C2781285689 @default.
W1969318845 hasConcept C41008148 @default.
W1969318845 hasConcept C62520636 @default.
W1969318845 hasConcept C65053842 @default.
W1969318845 hasConcept C71987851 @default.
W1969318845 hasConcept C97346530 @default.
W1969318845 hasConceptScore W1969318845C120665830 @default.
W1969318845 hasConceptScore W1969318845C121332964 @default.
W1969318845 hasConceptScore W1969318845C159985019 @default.