Научная статья на тему 'Dimer self-organization of 53Cr impurity ions in synthetic forsterite'

Dimer self-organization of 53Cr impurity ions in synthetic forsterite Текст научной статьи по специальности «Физика»

CC BY
159
66
i Надоели баннеры? Вы всегда можете отключить рекламу.
Область наук
Ключевые слова
forsterite / dimer self-organization of impurity ions / 53Cr isotopes.

Аннотация научной статьи по физике, автор научной работы — A. S. Apreleva, A. A. Sukhanov, V. F. Tarasov, K. A. Subbotin, E. V. Zharikov

Paramagnetic centers formed by isotopically pure impurity 53Cr ions in synthetic forsterite (Mg2SiO4) are studied by continuous wave electron paramagnetic resonance. It is shown that chromium ions substitute magnesium ions as single ion with nonlocal charge compensation and dimer associate formed by two closely spaced Cr3+ ions. It is found that the integral intensity of resonance transitions belonging to the dimer associates is much higher than that to be expected for the statistical distribution of the impurity Cr3+ ions in the forsterite host. Therefore, there is a mechanism favoring the self-organization of the Cr3+ ions in dimer associates during the crystal growth.

i Надоели баннеры? Вы всегда можете отключить рекламу.
iНе можете найти то, что вам нужно? Попробуйте сервис подбора литературы.
i Надоели баннеры? Вы всегда можете отключить рекламу.

Текст научной работы на тему «Dimer self-organization of 53Cr impurity ions in synthetic forsterite»

ISSN 2072-5981 doi: 10.26907/mrsej

aänetic Resonance in Solids

Electronic Journal

Volume 21 Special Issue 4 Paper No 19401 1-3 pages 2019

doi: 10.26907/mrsej-19401

http: //mrsej. kpfu. ru http: //mrsej. ksu. ru

Established and published by Kazan University Endorsed by International Society of Magnetic Resonance (ISMAR) Registered by Russian Federation Committee on Press (#015140),

August 2, 1996 First Issue appeared on July 25, 1997

© Kazan Federal University (KFU)*

"Magnetic Resonance in Solids. Electronic Journal" (MRSey) is a

peer-reviewed, all electronic journal, publishing articles which meet the highest standards of scientific quality in the field of basic research of a magnetic resonance in solids and related phenomena.

Indexed and abstracted by Web of Science (ESCI, Clarivate Analytics, from 2015), Scopus (Elsevier, from 2012), RusIndexSC (eLibrary, from 2006), Google Scholar, DOAJ, ROAD, CyberLeninka (from 2006), SCImago Journal & Country Rank, etc.

Editor-in-Chief Boris Kochelaev (KFU, Kazan)

Honorary Editors

Jean Jeener (Universite Libre de Bruxelles, Brussels) Raymond Orbach (University of California, Riverside)

Executive Editor

Yurii Proshin (KFU, Kazan) mrsej@kpfu. ru

0 © I This work is licensed under a Creative

* m-we» Commons Attribution-Share Alike 4.0 International License.

This is an open access journal which means that all content is freely available without charge to the user or his/her institution. This is in accordance with the BOAI definition of open access.

Special Editor of Issue

Eduard Baibekov (KFU)

Editors

Vadim Atsarkin (Institute of Radio Engineering and Electronics, Moscow) Yurij Bunkov (CNRS, Grenoble) Mikhail Eremin (KFU, Kazan) David Fushman (University of Maryland, College Park) Hugo Keller (University of Zürich,

Zürich)

Yoshio Kitaoka (Osaka University,

Osaka)

Boris Malkin (KFU, Kazan) Alexander Shengelaya (Tbilisi State University, Tbilisi) Jörg Sichelschmidt (Max Planck Institute for Chemical Physics of Solids, Dresden) Haruhiko Suzuki (Kanazawa University, Kanazava) Murat Tagirov (KFU, Kazan) Dmitrii Tayurskii (KFU, Kazan) Valentine Zhikharev (KNRTU,

Kazan)

Technical Editors of Issue

Nurbulat Abishev (KFU) Maxim Avdeev (KFU) Eduard Baibekov (KFu) Alexander Kutuzov (KFU)

* In Kazan University the Electron Paramagnetic Resonance (EPR) was discovered by Zavoisky E.K. in 1944.

Short cite this: Magn. Reson. Solids 21, 19401 (2019)

doi: 10.26907/mrsej-19401

EPR of single Yb3+ ions in CsCdBr3 monocrystals

L.K. Aminov*, M.R. Gafurov, I.N. Kurkin, S.I. Nikitin, A.A. Rodionov

Kazan Federal University, Kremlevskaya 18, Kazan 420008, Russia

* E-mail: [email protected]

(Received May 26, 2019; accepted May 28, 2019; published June 6, 2019)

New measurements of EPR spectra in single crystals CsCdBr3:Yb3+ are presented. The lines due to pairs of Yb3+ ions and single Yb3+ ions are observed. The spectra indicate the existence of several types of single Yb3+ paramagnetic centers. Resolved superhyperfine structure of some lines of these centers is observed for the first time.

PACS: 76.70.Dx, 75.10.Dg, 61.43.Bn. Keywords: EPR, rare-earth, crystal.

On the occasion of the 80th anniversary of B.Z. Malkin

1. Introduction

The substantial part of the scientific activity of Prof. B.Z. Malkin is devoted to the investigations of the structure of the admixture paramagnetic centers in crystals. He developed an effective model of exchange charges in the theory of crystal fields and worked out the comprehensive programs for simulation of optical and EPR spectra. These studies are extensively employed for the interpretation of very diverse experimental results. From applications to real systems, in the present report we shall dwell on the system CsCdBr3:Yb3+ which was already studied by a number of researchers, among them B.Z. Malkin (see [1] and cited there papers).

Besides applications in laser techniques this crystal is interesting due to the pronounced dimeric structure of paramagnetic centers. The crystal is composed of linear chains of Cd atoms stretched along the third order axis. Each atom is surrounded by an octahedron of six Br atoms, the neighboring octahedrons having a common face. The [CdBr3] chains are bounded through the chains of Cs atoms disposed between them. Already the first investigations show that trivalent paramagnetic ions in double bromide crystals form charge compensated dimers of the RE3+-vacancy - RE3+ type which substitutes for three successive Cd2+ ions in a chain. EPR spectra of such centers are explained rather satisfactorily with taking into account magnetic dipole - dipole and weak antiferromagnetic interactions between admixture ions. The fact that RE ions in double bromides form not only the pair centers was for the first time clearly demonstrated in Ref. [1] just in the crystal CsCdBr3:Yb3+. Besides EPR spectra of dimers, the authors observe EPR lines definitely belonging to the single Yb3+ ions. At the same time a number of other curious circumstances were found, that is, the variation of the relative concentration of dimers and single ions within the same single crystal and the irregular dependence of the relative concentration on general concentration of ytterbium ions in a sample. All this indicate that further investigations of the considered system are necessary. In this report we present some new measurements of EPR spectra for the system CsCdBr3:Yb3+. They indicate to the existence of several types of single Yb3+ centers. For the first time in this system superhyperfine structure of some EPR lines was revealed.

2. Experimental results

CsCdBr3 single crystals doped with Yb3+ ions were grown by the Bridgman method in quartz sealed ampoule by lowering in the furnace with temperature gradient of about 60°C/cm with rate of about 0.5 mm/h. CsBr (Merck, Germany, 99.99% purity), CdBr2 (Merck, Germany, 99.99%

EPR of single Yb3+ ions in CsCdBr3 monocrystals

purity), and YbBr3 (Cerac, USA, 99.99% purity) bromides were used as starting materials. The concentration of Yb3+ ions in the starting materials were varied from 0.1 to 1 at. % of substituted Cd2+. The quality of the crystals were tested by optical methods and X-ray diffraction. Six samples were investigated with nominal concentration of ytterbium ions within 0.1 - 1.0 at. %. The EPR measurements were made at X-band (microwave frequency v is about 9.42 GHz) cw Bruker ESP 300 spectrometer at low temperatures, typically at T = 10 K. The low temperature measurements were made using the Oxford Instruments ESR 9 helium flow cryogenic system.

In a sample with the highest concentration (1.0 at. %) of paramagnetic centers only intensive EPR spectrum of the symmetric Yb3+-Yb3+ dimer is observed. In other samples supplementary lines of different intensity appear, which may be ascribed to axial paramagnetic centers with single Yb3+ ion. One may separate out at least three such centers.

In Fig. 1 EPR spectra of the sample with the greatest content of single ions are presented for B || c and B ± c. By D the lines due to dimeric D-center are designated. A, B, C correspond to three different single-ion centers, the A-center being discussed before in [1]. The measured concentrations of paramagnetic centers in this sample (compared with the reference point CaF2: 0.8 at. % Er) are the next: A-centers - 0.068, B-centers - 0.011, C-centers - 0.004, D-centers -0.1 at. %. g-factors of single ions are the following: A: g|| = 3.33, g± = 2.16; B: g|| = 3.449, g± = 2.082; C: gM =3.16, g± = 2.219.

a)

b)

BII c

B_LC

B

2000

2500

B, G

3000

2000

2500

3000

B,G

Figure 1. EPR spectra of Yb3+ ions in CsCdBr3 single crystal. a) B || c; b) B ± c, v = 9.417 GHz, T = 10 K. A, B, C refer to single Yb3+ ions; D refer to Yb3+-Yb3+ dimer.

1930 1940 1950 1960 1970 1980

B, G

2100 2110 2120 B,G

2130

Figure 2. Superhyperfine structure of EPR spectra of single Yb3+ in CsCdBr3. a) B-center, b) C-center. B II c, v = 9.417GHz, T = 10K.

L.K. Aminov, M.R. Gafurov, I.N. Kurkin, et al.

We have observed resolved superhyperfine structure (SHFS) of the B and C lines (Figures 2a and 2b, correspondingly). Two spectra differ by their appearance and characteristics. For B-center the distance between components of SHFS is equal to ~2.3 G (11.1 MHz), the width of a component is ~1.0 G (4.83 MHz), while for the C-center the corresponding numbers are 3.5 G (15.48 MHz) and 2.3 G (10.17 MHz).

3. Discussion

The simplest possible model of the single paramagnetic center with axial symmetry is a model with non-local ("remote") charge compensation. An admixture Yb3+ ion takes place in position of Cd2+ and forms a complex with D3d symmetry consisting of the six nearest bromine ions and two cadmium ions along the C3 axis. Other axial complexes with local charge compensation are related to the presence of small univalent ions of the Li+ type, which takes place of Cd2+ neighboring with Yb3+ ion. Intermediate variants are possible similar to those used for the analysis of EPR spectra of Yb3+ ions in mixed crystals Bai—xLaxF2+x [2] and Ce3+ ions in CaF2 [3]. In these variants the compensation of the trivalent ion's charge is accomplished by means of alien ions and vacancies in the second, third etc. coordination spheres of paramagnetic ions. The diversity of the observed centers reflects the variety of possibilities. The rich super-hyperfine structure of EPR lines ascribed to centers B and C is seen in Figures 2a and 2b. Its resolution testifies to rather high quality of the crystal and gives evidence that EPR line-width is mainly due to the nuclear spin I = 3/2 of bromine atom isotopes (79Br, Y/2n = 10.70 MHz/T; 81Br, Y/2n = 11.53 MHz/T). The remarkable difference of the number of SHFS components of two centers is noticeable. According to the famous paper by Ranon and Hyde [4], this may be due to the fact that superhyperfine interaction and Zeeman energy of ligand nuclei are of the same order of magnitude and their relative magnitude varies with the change of experimental conditions.

Acknowledgments

EPR measurements were done using the equipment of the Federal Center of Shared Facilities of Kazan Federal University and initially were supported by the state assignment in the scientific sphere allocated to Kazan University (Project no. 3.6722.2017/8.9, I.N.K.). M.R.G. and A.A.R. are thankful to Russian Science Foundation (Project no. 17-72-20053) for the opportunity to expand research.

References

1. Gafurov M.R., Iskhakova A.S., Kurkin I.N., Kurzin S.P., Malkin B.Z., Nikitin S.I., Orlin-skii S.B., Rakhmatulin R.M.,Shakurov G.S., Tarasov V.F., Demirbilek R., Heber J. SPIE Proceedings 4166, 279 (2002)

2. Aminov L.K., Abdulsabirov R.Y., Korableva S.L., Kurkin I.N., Kurzin S.P., Ziganshin A.G., Orlinskii S.B. Appl. Magn. Reson. 29, 561 (2005)

3. Aminov L.K., Gafurov M.R., Kurkin I.N., Rodionov A.A. Appl. Magn. Reson. 45, 1147 (2014)

4. Ranon U., Hyde J.S. Phys. Rev. 141, 254 (1966)

i Надоели баннеры? Вы всегда можете отключить рекламу.