002836180 001__ 2836180
002836180 003__ SzGeCERN
002836180 005__ 20221008235821.0
002836180 0247_ $$2DOI$$9Springer$$a10.3103/S0027134922020710
002836180 0248_ $$aoai:cds.cern.ch:2836180$$pcerncds:CERN
002836180 035__ $$9https://inspirehep.net/api/oai2d$$aoai:inspirehep.net:2149974$$d2022-10-07T14:15:19Z$$h2022-10-08T04:00:04Z$$mmarcxml
002836180 035__ $$9Inspire$$a2149974
002836180 041__ $$aeng
002836180 100__ $$aNguyen, [email protected]$$uENEA, Frascati
002836180 245__ $$9Springer$$aUndulators and Light Production with the XLS-CompactLight Design Study
002836180 260__ $$c2022
002836180 300__ $$a4 p
002836180 520__ $$9Springer$$aFree electron laser (FEL) facilities provide broadly tunable and highly coherent photon beams. These machines still have an unexplored potential and development. The XLS-CompactLight design aims at a flexible hard plus soft X-ray FEL facility exploiting the latest concepts in terms of short period magnetic undulators, paving the road towards more compact photon sources.
002836180 542__ $$3publication$$dAllerton Press$$g2022
002836180 65017 $$2SzGeCERN$$aAccelerators and Storage Rings
002836180 6531_ $$9author$$afree-electron laser; undulator magnet
002836180 690C_ $$aARTICLE
002836180 690C_ $$aCERN
002836180 700__ $$aCarpanese, M$$uENEA, Frascati
002836180 700__ $$aPetralia, A$$uENEA, Frascati
002836180 700__ $$aBernhard, A$$tGRID:grid.7892.4$$uKIT, Karlsruhe
002836180 700__ $$aArnsberg, J$$tGRID:grid.7892.4$$uKIT, Karlsruhe
002836180 700__ $$aFatehi, S$$tGRID:grid.7892.4$$uKIT, Karlsruhe
002836180 700__ $$aGethmann, J$$tGRID:grid.7892.4$$uKIT, Karlsruhe
002836180 700__ $$aGrohmann, S$$tGRID:grid.7892.4$$uKIT, Karlsruhe
002836180 700__ $$aKrasch, B$$tGRID:grid.7892.4$$uKIT, Karlsruhe
002836180 700__ $$aSchmidt, T$$tGRID:grid.5991.4$$uPSI, Villigen
002836180 700__ $$aCalvi, M$$tGRID:grid.5991.4$$uPSI, Villigen
002836180 700__ $$aDanner, S$$tGRID:grid.5991.4$$uPSI, Villigen
002836180 700__ $$aZhang, K$$tGRID:grid.5991.4$$uPSI, Villigen
002836180 700__ $$aThompson, N$$tGRID:grid.482271.a$$uDaresbury
002836180 700__ $$aClarke, J A$$tGRID:grid.482271.a$$uDaresbury
002836180 700__ $$aCastañeda Cortés, H M$$tGRID:grid.482271.a$$uDaresbury
002836180 700__ $$aDunning, D J$$tGRID:grid.482271.a$$uDaresbury
002836180 700__ $$aHinton, A$$tGRID:grid.482271.a$$uDaresbury
002836180 700__ $$aShepherd, B$$tGRID:grid.482271.a$$uDaresbury
002836180 700__ $$aGeometrante, R$$uSincrotrone Trieste
002836180 700__ $$aKokole, M$$uUnlisted, IT
002836180 700__ $$aMilharcic, T$$uUnlisted, IT
002836180 700__ $$aPockar, J$$uUnlisted, IT
002836180 700__ $$aAksoy, A$$tGRID:grid.7256.6$$uAnkara U.
002836180 700__ $$aNergiz, Z$$tGRID:grid.7256.6$$tGRID:grid.412173.2$$uAnkara U.$$uNigde U.$$vNigde Omer Halisdemir University, Nigde, Turkey
002836180 700__ $$aMarcos, J$$tGRID:grid.423639.9$$uCELLS - ALBA, LLS
002836180 700__ $$aPerez, F$$tGRID:grid.423639.9$$uCELLS - ALBA, LLS
002836180 700__ $$aCross, A W$$tGRID:grid.11984.35$$uStrathclyde U.
002836180 700__ $$aZhang, L$$tGRID:grid.11984.35$$uStrathclyde U.
002836180 700__ $$aZhu, D$$tGRID:grid.1089.0$$uOak Ridge
002836180 700__ $$aRichter, S C$$tGRID:grid.9132.9$$uCERN
002836180 700__ $$aLatina, A$$tGRID:grid.9132.9$$uCERN
002836180 700__ $$aCianchi, A$$tGRID:grid.6530.0$$uRome U., Tor Vergata$$uINFN, Rome2
002836180 700__ $$aGoryashko, V$$tGRID:grid.8993.b$$uUppsala U.
002836180 700__ $$aD’Auria, G$$tGRID:grid.5942.a$$uSincrotrone Trieste
002836180 700__ $$aDi Mitri, S$$tGRID:grid.5942.a$$uSincrotrone Trieste
002836180 700__ $$aRochow, R$$tGRID:grid.5942.a$$uSincrotrone Trieste
002836180 773__ $$c241-244$$n2$$pMoscow Univ. Phys. Bull.$$v77$$y2022
002836180 773__ $$wC21-08-19
002836180 960__ $$a13
002836180 962__ $$b2777827$$k241-244$$nmoscow20210819
002836180 980__ $$aARTICLE
002836180 980__ $$aConferencePaper