TY - JOUR
T1 - Applications of remanent supermirror polarizers
AU - Böni, P.
AU - Clemens, D.
AU - Senthil Kumar, M.
AU - Pappas, C.
N1 - Funding Information:
We would like to thank W. Hahn for the Monte Carlo simulations for the benders, and M. Horisberger for producing supermirror coatings at PSI. Financial support by the Swiss National Science Foundation and the Swiss Federal Office for Education and Science within the XENNI project (EC TMR–Access to Large Scale Facilities 950005) is gratefully acknowledged.
PY - 1999/6
Y1 - 1999/6
N2 - Recent developments in sputtering techniques allow the fabrication of multilayers with a high degree of perfection over large areas. We show, that using reactive sputtering, it is possible to adjust the index of refraction for neutrons, ni, of the individual layers. This property is particularly important for polarizing mirrors, where nnm for the non-magnetic layers can be matched to nm of the magnetic layers such that neutrons for one spin-eigenstate are not reflected by the coating, whereas the reflectivity is high for the other spin-eigenstate. In addition, by using anisotropic sputtering conditions it is possible to orient the easy axis of magnetization within the plane of the mirrors in any particular direction resulting in a simultaneous appearance of a pronounced remanence and coercivity. Remanent polarizers can be used as broad band spin selectors at continuous and in particular at pulsed neutron sources thus eliminating the need of spin flippers, whose performance depends on the wavelength of the neutrons and is often strongly influenced by stray magnetic fields from the sample environment. The possibility to operate remanent supermirrors in arbitrary small fields leads to attractive applications of polarizing devices in low field environments such as they occur in neutron-spin-echo or in spin selective neutron guides. We present applications, where several tasks like polarizing, focusing and spin selection are performed in one single device thus reducing the problem of phase space matching between different neutron optical components.
AB - Recent developments in sputtering techniques allow the fabrication of multilayers with a high degree of perfection over large areas. We show, that using reactive sputtering, it is possible to adjust the index of refraction for neutrons, ni, of the individual layers. This property is particularly important for polarizing mirrors, where nnm for the non-magnetic layers can be matched to nm of the magnetic layers such that neutrons for one spin-eigenstate are not reflected by the coating, whereas the reflectivity is high for the other spin-eigenstate. In addition, by using anisotropic sputtering conditions it is possible to orient the easy axis of magnetization within the plane of the mirrors in any particular direction resulting in a simultaneous appearance of a pronounced remanence and coercivity. Remanent polarizers can be used as broad band spin selectors at continuous and in particular at pulsed neutron sources thus eliminating the need of spin flippers, whose performance depends on the wavelength of the neutrons and is often strongly influenced by stray magnetic fields from the sample environment. The possibility to operate remanent supermirrors in arbitrary small fields leads to attractive applications of polarizing devices in low field environments such as they occur in neutron-spin-echo or in spin selective neutron guides. We present applications, where several tasks like polarizing, focusing and spin selection are performed in one single device thus reducing the problem of phase space matching between different neutron optical components.
UR - http://www.scopus.com/inward/record.url?scp=0344718534&partnerID=8YFLogxK
U2 - 10.1016/S0921-4526(99)00087-3
DO - 10.1016/S0921-4526(99)00087-3
M3 - Conference article
AN - SCOPUS:0344718534
SN - 0921-4526
VL - 267-268
SP - 320
EP - 327
JO - Physica B: Condensed Matter
JF - Physica B: Condensed Matter
T2 - Proceedings of the 1998 2nd International Workshop on Polarised Neutrons for Condensed Matter Investigations, PNCMI '98
Y2 - 21 September 1998 through 23 September 1998
ER -