Ultrafast compact classical Mott polarimeter

Petrov, V. N.; Grebenshikov, V. V.; Andronov, A. N.; Gabdullin, P. G.; Maslevtcov, A. V.

doi:10.1063/1.2437112

Cited by 14 publications

(11 citation statements)

References 25 publications

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“…The main advantage of this type of Mott detector is its high stability and reliability. The main disadvantage that the polarimeter was very large because high voltages were used in order to be able to discriminate the background from the signal, has been resolved due to developments in detection technology [20]. The other main disadvantage is that the detectors, pre-amplifiers and discriminators are all at high voltage which results in rather complex electronics where not all standard components can be easily integrated.…”

Section: Technical Background Of Spin and Angle-resolved Photoemissionmentioning

confidence: 99%

Spin and angle resolved photoemission on non-magnetic low-dimensional systems

Dil

2009

J. Phys.: Condens. Matter

155

149

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Abstract. The electronic structure of non-magnetic low dimensional materials can acquire a spin structure due to the breaking of the inversion symmetry at the surface or interface. This so-called Rashba effect is a prime candidate for the manipulation of the electron spin without using any magnetic fields. This is crucial for the emerging field of spintronics, where the spin of the electron instead of its charge are used to transport or store information. Spin and angle-resolved photoemission is currently one of the main experimental methods to measure the spin-resolved electronic structure, which contains all the relevant information for spintronics. In this review, the technique of spin and angle-resolved photoemission will be explained and recent results on low dimensional non-magnetic structures will be discussed.

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Section: Technical Background Of Spin and Angle-resolved Photoemissionmentioning

confidence: 99%

Spin and angle resolved photoemission on non-magnetic low-dimensional systems

Dil

2009

J. Phys.: Condens. Matter

155

149

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“…For this reason, Petrov and coworkers have been active in combining various electron energy analyzers with compact spherical high-energy Mott polarimeters [15,31,45,46]; they have also performed comparative tests of this type of polarimeter with the retarding-potential Mott polarimeter [41].…”

Section: Commercially Available Polarimetersmentioning

confidence: 98%

“…The early polarimeters, now generally referred to as "classical" Mott polarimeters, were bulky (typically several cubic meters) as electron energies of around 100 keV were involved for both scattering and detection. A modern classical Mott polarimeter has been developed and fully characterized by Petrov [45,46]. This instrument (which is commercially available; see "Commercially Available Polarimeters") has a spherical geometry and is used, inter alia, for photoemission studies on the Swiss Light Source where it has proved to be very reliable.…”

Section: Mott Scatteringmentioning

confidence: 99%

Spin-Resolved Valence Photoemission

Seddon

2014

Handbook of Spintronics

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Spin-resolved valence photoemission has recently seen a resurgence of interest fostered by exciting results in a range of interesting materials. Reviewed here are the basics of, the instrumentation for, and techniques useful in spin-resolved photoemission, together with illustrative examples of its utilization for materials of general importance and of particular relevance to spintronics applications. The example materials are broadly classified into nonmagnetic and magnetic systems. The former covers Rashba systems and topological insulators. The latter includes thin films, half-metals, adsorbates and induced moments, and, finally, a short section on imaging. The review is not intended to be comprehensive in its coverage but rather to provide an introduction to hardware and techniques together with an overview of selected results and state-of-the-art developments. List of Abbreviations 1DOne

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Section: Introductionmentioning

confidence: 99%

“…The Mott spin detectors (for entries see Petrov et al, 1997Petrov et al, , 2007Hoesch et al, 2002) are based on quasielastic scattering of high-energy electrons (about 40 keV) from a target of a high-Z material such as Au. As a spin selective process, the Mott scattering is characterized by a FOM value of about 6 Â 10 À4 per one spin projection (Petrov et al, 1997(Petrov et al, , 2007 measured by two opposite electron detectors working simultaneously. Other spin selective processes such as the lowenergy electron reflectivity from W(100) or Ir(100) Kutnyakhov et al, 2013;Vasilyev et al, 2015;Kolbe et al, 2011) or exchange scattering from the Fe 2 O 3 surface (Okuda et al, 2008(Okuda et al, , 2011 may certainly have larger FOM values, in the latter case reaching 9.5 Â 10 À3 per one spin projection (Okuda et al, 2008) acquired in two successive measurements under re-magnetization of the target or sample.…”

Section: Introductionmentioning

confidence: 99%

Concept of a multichannel spin-resolving electron analyzer based on Mott scattering

Strocov

Petrov

Dil

2015

J Synchrotron Radiat

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The concept of a multichannel electron spin detector based on optical imaging principles and Mott scattering (iMott) is presented. A multichannel electron image produced by a standard angle-resolving (photo) electron analyzer or microscope is re-imaged by an electrostatic lens at an accelerating voltage of 40 kV onto the Au target. Quasi-elastic electrons bearing spin asymmetry of the Mott scattering are imaged by magnetic lenses onto position-sensitive electron CCDs whose differential signals yield the multichannel spin asymmetry image. Fundamental advantages of this concept include acceptance of inherently divergent electron sources from the electron analyzer or microscope focal plane as well as small aberrations achieved by virtue of high accelerating voltages, as demonstrated by extensive ray-tracing analysis. The efficiency gain compared with the single-channel Mott detector can be a factor of more than 10 4 which opens new prospects of spin-resolved spectroscopies in application not only to standard bulk and surface systems (Rashba effect, topological insulators, etc.) but also to buried heterostructures. The simultaneous spin detection combined with fast CCD readout enables efficient use of the iMott detectors at X-ray freeelectron laser facilities.

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Ultrafast compact classical Mott polarimeter

Cited by 14 publications

References 25 publications

Spin and angle resolved photoemission on non-magnetic low-dimensional systems

Spin and angle resolved photoemission on non-magnetic low-dimensional systems

Spin-Resolved Valence Photoemission

Concept of a multichannel spin-resolving electron analyzer based on Mott scattering

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