SemOpenAlex |

SemOpenAlex

Matches in SemOpenAlex for { <https://semopenalex.org/work/W2119263843> ?p ?o ?g. }

Showing items 1 to 100 of ±165 with 100 items per page.

W2119263843 endingPage "1654" @default.
W2119263843 startingPage "1639" @default.
W2119263843 abstract "Since the 1960s, Nb-Ti (superconducting transition temperature T/sub c/=9 K) and Nb/sub 3/Sn (T/sub c/=18 K) have been the materials of choice for virtually all superconducting magnets. However, the prospects for the future changed dramatically in 1987 with the discovery of layered cuprate superconductors with T/sub c/ values that now extend up to about 135 K. Fabrication of useful conductors out of the cuprates has been difficult, but a first generation of silver-sheathed composite conductors based on (Bi,Pb)/sub 2/Sr/sub 2/Ca/sub 2/Cu/sub 3/O/sub 10/ (T/sub c//spl sim/110 K) has already been commercialized. Recent progress on a second generation of biaxially aligned coated conductors using the less anisotropic YBa/sub 2/Cu/sub 3/O/sub 7/ structure has been rapid, suggesting that it too might enter service in the near future. The discovery of superconductivity in MgB/sub 2/ below 39 K in 2001 has brought yet another candidate material to the large-scale applications mix. Two distinct markets for superconductor wires exist-the more classical low-temperature magnet applications such as particle accelerators, nuclear magnetic resonance and magnetic resonance imaging magnets, and plasma-containment magnets for fusion power, and the newer and potentially much larger market for electric power equipment, such as motors, generators, synchronous condensers, power transmission cables, transformers, and fault-current limiters for the electric utility grid. We review key properties and recent progress in these materials and assess their prospects for further development and application." @default.
W2119263843 created "2016-06-24" @default.
W2119263843 creator A5062293316 @default.
W2119263843 creator A5070741258 @default.
W2119263843 creator A5081100592 @default.
W2119263843 date "2004-10-01" @default.
W2119263843 modified "2023-10-18" @default.
W2119263843 title "Superconducting materials for large scale applications" @default.
W2119263843 cites W1513161583 @default.
W2119263843 cites W1546655939 @default.
W2119263843 cites W1552313002 @default.
W2119263843 cites W1595474181 @default.
W2119263843 cites W1599009290 @default.
W2119263843 cites W1649389686 @default.
W2119263843 cites W1699504718 @default.
W2119263843 cites W1890676547 @default.
W2119263843 cites W1964319154 @default.
W2119263843 cites W1969086734 @default.
W2119263843 cites W1971812548 @default.
W2119263843 cites W1972684426 @default.
W2119263843 cites W1974159650 @default.
W2119263843 cites W1979428769 @default.
W2119263843 cites W1982359821 @default.
W2119263843 cites W1983652121 @default.
W2119263843 cites W1985515646 @default.
W2119263843 cites W1986274376 @default.
W2119263843 cites W1986655228 @default.
W2119263843 cites W1990252560 @default.
W2119263843 cites W1994994475 @default.
W2119263843 cites W2001647921 @default.
W2119263843 cites W2007594966 @default.
W2119263843 cites W2007780478 @default.
W2119263843 cites W2012645919 @default.
W2119263843 cites W2019077272 @default.
W2119263843 cites W2019376018 @default.
W2119263843 cites W2021556111 @default.
W2119263843 cites W2022711968 @default.
W2119263843 cites W2026644401 @default.
W2119263843 cites W2031834865 @default.
W2119263843 cites W2037891010 @default.
W2119263843 cites W2039123153 @default.
W2119263843 cites W2043366262 @default.
W2119263843 cites W2047088514 @default.
W2119263843 cites W2048137467 @default.
W2119263843 cites W2049113715 @default.
W2119263843 cites W2051321744 @default.
W2119263843 cites W2052891881 @default.
W2119263843 cites W2065291459 @default.
W2119263843 cites W2072177960 @default.
W2119263843 cites W2073427212 @default.
W2119263843 cites W2076136997 @default.
W2119263843 cites W2078710135 @default.
W2119263843 cites W2083406107 @default.
W2119263843 cites W2083824208 @default.
W2119263843 cites W2085709753 @default.
W2119263843 cites W2086113798 @default.
W2119263843 cites W2087525087 @default.
W2119263843 cites W2089215584 @default.
W2119263843 cites W2095302878 @default.
W2119263843 cites W2098046631 @default.
W2119263843 cites W2101919813 @default.
W2119263843 cites W2102517292 @default.
W2119263843 cites W2108731995 @default.
W2119263843 cites W2111769364 @default.
W2119263843 cites W2114694506 @default.
W2119263843 cites W2116593492 @default.
W2119263843 cites W2117196059 @default.
W2119263843 cites W2118182446 @default.
W2119263843 cites W2120681324 @default.
W2119263843 cites W2121314568 @default.
W2119263843 cites W2133164637 @default.
W2119263843 cites W2137492247 @default.
W2119263843 cites W2142119590 @default.
W2119263843 cites W2143029374 @default.
W2119263843 cites W2148211448 @default.
W2119263843 cites W2153065726 @default.
W2119263843 cites W2153081734 @default.
W2119263843 cites W2157649526 @default.
W2119263843 cites W2158587816 @default.
W2119263843 cites W2262490403 @default.
W2119263843 cites W2295459557 @default.
W2119263843 cites W2490001507 @default.
W2119263843 cites W2494963481 @default.
W2119263843 cites W2620895888 @default.
W2119263843 cites W3021248143 @default.
W2119263843 cites W3099878759 @default.
W2119263843 cites W3100888198 @default.
W2119263843 cites W3102601611 @default.
W2119263843 cites W3102825961 @default.
W2119263843 cites W411017374 @default.
W2119263843 cites W4214823782 @default.
W2119263843 cites W4236949229 @default.
W2119263843 cites W4376043533 @default.
W2119263843 cites W809308405 @default.
W2119263843 doi "https://doi.org/10.1109/jproc.2004.833673" @default.
W2119263843 hasPublicationYear "2004" @default.
W2119263843 type Work @default.
W2119263843 sameAs 2119263843 @default.