Journal of large-scale research facilities, 1, A11 (2015) http://dx.doi.org/10.17815/jlsrf-1-34 Published: 19.08.2015 J-NSE: Neutron spin echo spectrometer Heinz Maier-Leibnitz Zentrum Forschungszentrum Jülich, Jülich Centre for Neutron Science Instrument Scientists: - Olaf Holderer, Jülich Centre for Neutron Science (JCNS) at Heinz Maier-Leibnitz Zentrum (MLZ), Forschungszentrum Jülich GmbH, Garching, Germany, phone: +49(0) 89 289 10707, email: o.holderer@fz-juelich.de - Oxana Ivanova, Jülich Centre for Neutron Science (JCNS) at Heinz Maier-Leibnitz Zentrum (MLZ), Forschungszentrum Jülich GmbH, Garching, Germany, phone: +49(0) 89 289 10730, email: o.ivanova@fz-juelich.de Abstract: Neutron Spin-Echo (NSE) spectroscopy is well known as the only neutron scattering tech- nique that achieves energy resolution of several neV. By using the spin precession of polarized neutrons in magnetic �eld one can measure tiny velocity changes of the individual neutron during the scatter- ing process. Contrary to other inelastic neutron scattering techniques, NSE measures the intermediate scattering function S(Q,t) in reciprocal space and time directly. The Neutron Spin-Echo spectrometer J-NSE, operated by JCNS, Forschungszentrum Jülich at the Heinz Maier-Leibnitz Zentrum (MLZ) in Garching, covers a time range (2 ps to 200 ns) on length scales accessible by small angle scattering technique. Along with conventional NSE spectroscopy that allows bulk measurements in transmission mode, J-NSE o�ers a new possibility - gracing incidence spin echo spectroscopy (GINSENS), developed to be used as "push-button" option in order to resolve the depth dependent near surface dynamics. 1 Introduction The neutron spin echo technique NSE uses the neutron spin as an indicator of the individual velocity change the neutron su�ered when scattered by the sample. Due to this trick, the instrument accepts a broad wavelength band and at the same time is sensitive to velocity changes down to 10-5. However the information carried by the spins can only be retrieved as the modulo of any integer number of spin precessions as intensity modulation proportional to the cosine of a precession angle di�erence. The measured signal is the cosine transform S(Q, τ ) of the scattering function S(Q, ω ). All spin manipula- tions only serve to establish this special type of velocity analysis. For details see Mezei (1980). 1 http://jlsrf.org/ http://dx.doi.org/10.17815/jlsrf-1-34 https://creativecommons.org/licenses/by/4.0/ Journal of large-scale research facilities, 1, A11 (2015) http://dx.doi.org/10.17815/jlsrf-1-34 Figure 1: Sample position at the J-NSE instrument, front view (Copyright by W. Schürmann, TUM). Due to the intrinsic Fourier transform property of the NSE instrument it is especially suited for the investigation of relaxation-type motions that contribute at least several percent to the entire scattering intensity at the momentum transfer of interest. In those cases the Fourier transform property yields the desired relaxation function directly without numerical transformation and tedious resolution de- convolution. The resolution of the NSE may be corrected by a simple division. For a given wavelength the Fourier time range is limited to short times (about 2 ps for J-NSE set-up) by spin depolarisation due to vanishing guide �eld and to long times by the maximum achievable �eld integral J. The time is proportional to J x λ 3. The J-NSE may achieve a J = 0.5 Tm corresponding to τ = 48 ns at λ = 8 Å. The J-NSE instrument (see Figure 1 and 2) consists mainly of two large water-cooled copper solenoids that generate the precession �eld. The precession tracks are limited by the π /2-�ippers and the π - �ipper near the sample position. The embedding �elds for the �ippers are generated by Helmholtz- type coil pairs around the �ipper locations. After leaving the last �ipper the neutrons enter an analyzer containing 60 CoTi supermirrors located in a solenoid set. These mirrors re�ect only neutrons of one spin direction into the multidetector. By the addition of compensating loops the main coils and the analyzer coil are designed such that the mutual in�uence of the di�erent spectrometer components is minimised. 2 Typical Applications The spin echo spectrometer J-NSE is especially suited for the investigation of slow (∼ 1 to 100 ns) relaxation processes. Typical problems from the �elds of “soft matter” and glass transition are: • Thermal �uctuations of surfactant membranes in microemulsions • Polymer chain dynamics in melts • Thermally activated domain motion in proteins, which is an important key for understanding the protein function 2 http://dx.doi.org/10.17815/jlsrf-1-34 https://creativecommons.org/licenses/by/4.0/ http://dx.doi.org/10.17815/jlsrf-1-34 Journal of large-scale research facilities, 1, A11 (2015) Figure 2: Schematic drawing of J-NSE set-up, top view. 3 Sample Environment • circulation thermostat furnace (260 – 360 K) • Cryofour (3 – 650 K) • Furnace (300 – 510 K) • CO2- pressure cell (500 bar) Other specialised sample environments are available on request. 4 Technical Data 4.1 Main parameters • Polarised neutron �ux at sample position 7 Å: 1 · 107 n cm-2 s-1 12 Å: 6.8 · 105 n cm-2 s-1 • Momentum transfer range: 0.02 – 1.5 Å-1 • Fourier time range: 2 ps (4.5 Å) < τ < 350 ns (16 Å) • Max. �eld integral: 0.5 Tm 4.2 Primary beam • Neutron guide NL2a • Polarisation: Short wavelength by bent section with FeSi m = 3 remanent supermirror coating Long wavelength by FeSi polariser at entrance of the spectrometer • Cross section of guide: 6 cm x 6 cm • Max. sample size: 3 cm x 3 cm • Collimation: By source and sample size or wire collimators 0.5° x 0.5° 3 http://dx.doi.org/10.17815/jlsrf-1-34 https://creativecommons.org/licenses/by/4.0/ Journal of large-scale research facilities, 1, A11 (2015) http://dx.doi.org/10.17815/jlsrf-1-34 4.3 Analyzer • 30 x 30 cm2 CoTi supermirror Venetian blind 4.4 Detector • 32 x 32 1 cm2 cells 3He multidetector References Mezei, F. (1980). The principles of neutron spin echo. In F. Mezei (Ed.), Neutron spin echo (Vol. 128, p. 1-26). Springer Berlin Heidelberg. http://dx.doi.org/10.1007/3-540-10004-0_16 4 http://dx.doi.org/10.17815/jlsrf-1-34 http://dx.doi.org/10.1007/3-540-10004-0_16 https://creativecommons.org/licenses/by/4.0/ Introduction Typical Applications Sample Environment Technical Data Main parameters Primary beam Analyzer Detector