ISSN 2072-5981
aänetic Resonance in Solids
Electronic Journal
Volume 18, Issue 2 Paper No 16207, 1-8 pages 2016
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August 2, 1996 First Issue was appeared at 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. MRSey is free for the authors (no page charges) as well as for the readers (no subscription fee). The language of MRSey is English. All exchanges of information will take place via Internet. Articles are submitted in electronic form and the refereeing process uses electronic mail. All accepted articles are immediately published by being made publicly available by Internet (http://MRSe/. kpfu.ru).
Editors-in-Chief Jean Jeener (Universite Libre de Bruxelles, Brussels) Boris Kochelaev (KFU, Kazan) Raymond Orbach (University of California, Riverside)
Executive Editor Yurii Proshin (KFU, Kazan) [email protected] [email protected]
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) Valentin Zhikharev (KNRTU, Kazan)
In Kazan University the Electron Paramagnetic Resonance (EPR) was discovered by Zavoisky E.K. in 1944.
Lithium diffusion in a new cathode material Lio.8[Nio.6Sbo.4]O2 studied by 7Li NMR
T. Salikhov 1 *, E. Klysheva E. Zvereva 2, V. Nalbandyan 3, I. Shukaev 3, B. Medvedev 3, E. Vavilova 1 1 Zavoisky Physical-Technical Institute of RAS, Sibirskii trakt 10/7, Kazan 420029, Russia 2 Faculty of Physics, Moscow State University, Leninskie Gory 1-2, Moscow 119991, Russia 3 Chemistry Faculty, Southern Federal University, Sorge 7, Rostov-on-Don 344090, Russia
*E-mail: [email protected] (Received December 10, 2016; accepted December 18, 2016)
A rhombohedral layered a-NaFeO2-type compound, Lix[Ni(1+x)/3Sb(2-x)/3]O2 (x = 0.8) has been prepared from the sodium analogue by ion exchange at 570 K. In contrast to the stoichiometric composition Li3Ni2SbO6, it shows considerable Li/Ni inversion and no long-range Ni/Sb ordering. The temperature dependence of the 7Li NMR spin-lattice relaxation rate and linewidth data measured at temperature range from 30-450 K show the sharp increase of lithium ions mobility comparing to the stoichiometric compound Li3Ni2SbO6. From the NMR data the activation energy was estimated by different methods.
PACS: 76.60.-k, 76.60.Es, 66.30.H-, 82.47.Aa, 82.56.Lz, 82.56.Na Keywords: NMR, lithium, diffusion, cathode material
1. Introduction
Lithium-ion batteries play important role in energy storage and transport. They are widespread in modern life, from portable devices to electric vehicles. However, the rapid development of science and technology requires the creation of more and more effective energy storage devices. In particular, the positive electrode is responsible for such characteristics as energy density, safety, cost and toxicity. Therefore, the creation of new cathode materials is a key step for improving the effectiveness of the lithium batteries [1-3]. Most of today's cathode materials belong to the layered transition metal oxides, LiCoO2 being the most widely used. However, materials based on Ni2+ are also of great interest because it is less expensive and less toxic than cobalt and provides possibility of a two-electron redox process. In particular, layered lithium nickel antimonates first prepared and characterized by our group in 2007 [4] attracted attention as possible positive electrode materials for Li-ion batteries [5-8].
Thereby, considering the charge/discharge characteristics of the battery, the ion diffusion and activation energies that describe Li-ion transport within cathode materials are of big interest. Nuclear magnetic resonance (NMR) is widely used for study the diffusion processes in ionic conductors, electrolytes and electrode materials [9-16]. The advantage of this method is the ability to study intragranular ion mobility without contribution from grain-boundary impedance that is very important for the investigation of polycrystalline materials. Furthermore, being a local method, NMR allows monitoring the characteristics of the ions on different structural positions selectively. However, the conventional NMR study of the ion diffusion is extremely difficult in magnetic materials since the interaction with magnetic ions in the lattice strongly affects Li-NMR parameters even in a paramagnetic state [17, 18].
In this work, we have studied the diffusion of lithium ions in the cathode material with Li vacancies. For this purpose, we synthesized two compositions Lix[Ni(1+x>/3Sb(2-x)/3]O2: one Li-deficient (x = 0.8) and, for comparison, another one with completely filled Li sites (x = 1). The investigation of the lithium mobility was done by NMR technique modified for better quality of measurements in the paramagnetic compounds.
f This paper material was selected at XIX International Youth Scientific School "Actual problems of magnetic resonance and its application", Kazan, 24 - 28 October 2016. The paper was recommended to publication in our journal and it is published after additional MRSej reviewing.
2. Experimental
2.1 Sample _preparation and characterization
In contrast to the sodium analogue [19] and stoichiometric Li3Ni2SbO6 [20], its cation-deficient solid solutions, Lix[Ni(i+I)/3Sb(2-x)/3]O2, x < 1, could not be prepared by direct high-temperature synthesis. Therefore, Na0.8Ni0.6Sb0.4O2 was prepared first as described previously [19]. Reagent-grade antimonic acid, hydrous nickel oxide (both analyzed gravimetrically) and dried sodium carbonate were mixed thoroughly, pressed, reacted at 1070 K and, after regrinding and pressing, sintered at 1380 K for 3 h within the sacrificial packing powder of the same composition. 3 % sodium excess was employed to compensate for volatilisation at the high temperature.
Phase-pure sodium samples were ion-exchanged in 20-fold excess molten LiNO3 to give Li0.8Ni0.6Sb0.4O2. The sintered discs and those ground to powder were treated at 610 K for 4 h and at 570 K for 3 h, respectively, and then washed and dried. The discs were porous and this enabled complete exchange in the bulk, as confirmed by the X-ray diffraction (XRD) powder analysis of a crushed sample. For comparison, a pellet of stoichiometric Li3Ni2SbO6 [20] was sintered at 1370 K. All samples were light green, excluding any possibility of a mixed-valence state of nickel that always gives rise to dark coloration even at low fractions of Ni3+ (<< 1%).
The XRD phase analysis was performed in CuKa radiation using an ARL X'TRA diffractometer equipped with a solid-state Si(Li) detector. The higher-intensity data for the structural analysis of Li0.8Ni0.6Sb0.4O2 were collected using a rotating-anode Rigaku instrument with a secondary-beam graphite monochromator, also in copper radiation. Structural analysis was performed by the Rietveld method implemented in GSAS+EXPGUI suite [21, 22].
2.2 Magnetic susceptibility measurements
Magnetic susceptibility measurements were done by means of a Quantum Design Magnetic Property Measurement System (MPMS) XL-7 magnetometer. The temperature dependencies of the magnetic susceptibility were measured at a magnetic field B = 0.7 T in the temperature range 2-350 K.
2.3 NMR measurements
Nuclear magnetic resonance (NMR) experiments were carried out using Tecmag solid-state pulse spectrometer and Bruker resistive 0-1.5 T magnet at the frequency 12 MHz. The NMR signals were observed on 7Li nuclei with spin I = 3/2 and gyromagnetic ratio yN/2n = 16.546 MHz/T. The NMR spectra were obtained either by Fourier transformation of the NMR solid-echo signal at a fixed field of H = 0.724 T or by step-by-step sweeping the field and integrating the solid-echo signal at each field step. 7Li spin-lattice relaxation rate 1/T\ was measured using a stimulated echo pulse sequence. 7Li relaxation rate 1/72 was obtained by measuring the solid-echo integral as a function of t, where t is time between two rc/2 pulses. In the temperature range from 30 K to 450 K a home-made low temperature and high temperature thermostats and probes was used.
3. Results
3.1 Crystal structure
Similar to the sodium precursor, XRD pattern of Li0.8Ni0.6Sb0.4O2 was completely indexed on the basis of a small rhombohedral unit cell of the a-NaFeO2 type. No superlattice reflections indicating longrange Ni/Sb ordering characteristic of the x = 1 sample (Li3Ni2SbO6) could be found. Instead, an elevated background is observed in the same angular range (2© = 19-24°, Fig. 1) indicating that short-range order does exist. The XRD pattern may be found in the PDF database [4].
The crystal structure was successfully refined within the space group R 3 m and refinement results are shown in Fig. 1. The most interesting result of the refinement is considerable degree of Li/Ni inversion: about 8 % Li was found on Ni site and vice versa, similar to Li3Cu2SbO6, also prepared by the low-temperature ion exchange, where 16 % Li was found on Cu site [23].
Figure 1. Results of the Rietveld refinement of Li0.8Ni0.6Sb0.4O2. XRD profile (left): asterisks, experimental points; line, calculated profile; line at the bottom, difference plot; vertical bars, Bragg positions. Polyhedral view of the crystal structure (right): gray octahedra, (Ni,Sb)O6 with small admixture of Li; white octahedra, LiO6, partially occupied, with small admixture of Ni.
3.2 Magnetic susceptibility
The temperature dependence of the magnetic susceptibility % = M/B for Li0.8Ni0.6Sb0.4O2 measured at B = 0.7 T is shown in Fig. 2. Overall the %(T) dependence manifests a Curie-Weiss-type behavior upon a decrease of temperature. At low temperatures the %(T) deviates from the Curie-Weiss law but still does not show any sign of long-range magnetic ordering down to 2 K. Obviously, these data are cardinally different from those detected for stoichiometric compound Li3Ni2SbO6 [20, 24] indicating the new type of magnetic properties which should be expected for this new compound. The high-temperature part of %(T) was fitted in accordance the Curie-Weiss law with addition of a temperature-independent term %0:
%=%0 +
C
T-0
(1)
where 0 is the Weiss temperature, C is the Curie constant C = NA-^eff2'^B2/3kB, Na is Avogadro's number, ¡eff is the effective magnetic moment, ¡b is Bohr's magneton, and £b is Boltzmann's constant. The best fit of experimental data yields the following parameters: 0«-4K, C ~ 0.97 emu/mol K and yp ~ 2.8-10 4 emu/mol. The effective magnetic moment calculated from the Curie constant is about ¡eff ~ 2.7 ¡¡b /f.u. Relatively large positive value of temperature-independent term indicates non-negligible Van-Fleck contribution from Ni2+ similarly to native compound Li3Ni2SbO6 [20, 24]. At the same time the Weiss temperature 0 takes here a negative value, which indicates the predomination of the antiferromagnetic interactions in Li0.8Ni0.6Sb0.4O2 and again points to the clear difference between our sample and the stoichiometric compound Li3Ni2SbO6 [24].
Figure 2. The dependence of the magnetic susceptibility of Li0.8Ni0.6Sb0.4O2 at B = 0.7 T as a function of temperature.
3.3 NMR Spectra
For the quadrupolar 7Li (I = 3/2) nucleus, one can expect two satellite lines and the central line in the single crystal corresponding to three allowed transitions, the powder spectra usually demonstrate the averaged profile of the satellites. As shown in Fig. 3, in the Li0.8Ni0.6Sb0.4O2 we observe only a single
spectral line without any satellites, which is conventional line shape for the case of small quadrupole splitting and the inhomogeneous line broadening. At the room temperature and up to 450 K the spectra have a Lorentzian shape and their positions are very close to the Larmor frequency. Upon lowering the temperature, the spectrum is shifted to the lower field and its shape changes to Gaussian. The line shift above 250 K is in order of magnitude of the external magnetic field inhomogeneity (10-4) so the reliable parameter in this case is only the linewidth but not the line position. Fig. 4 shows the width of 7Li NMR spectrum as a function of temperature. Below 250 K, the temperature dependence of the linewidth follows the temperature dependence of the static susceptibility indicating that the main origin of spectral broadening in this temperature region is a hyperfine coupling of the 7Li nuclei with paramagnetic Ni2+ ions. Above 250 K, the additional line narrowing is observed. Investigation of the stoichio-metric sample Li3Ni2SbO6 demonstrates similar lineshape and linewidth behavior below 250 K, but no extra narrowing of the line up to the 450 K.
3.4 NMR Relaxation
The decay of longitudinal magnetization was fitted well by a single exponential function (Fig. 5):
( r . n
Mz = M n
exp 1- 7
(2)
The good agreement with the experimental data proves that during the experiment all the
transitions have exited but not only a main
transition (+1/2) - (-1/2) (in the last case, the relaxation process for spin 3/2 is described by two-exponential function)
-100k 0 100k
Frequency (Hz)
Figure 3. Temperature evolution of the 7Li NMR spectra at 12 MHz.
0,15
0,10
N T
X)
■> 0,05
w Li0.8Ni0.6SbcA"
1 B0=724mT "
t - * f0=12MHz -
100 150 200 250 300 350 400
0,035
0,025
0,020 E
E
0,015 a
0,005
0,000 450
T(K)
Figure 4. Temperature dependence of 7Li NMR linewidth (square), the static susceptibility data (blue line) and fit according Curie-Weiss law (red line).
Here we can consider following mechanisms of relaxation: dipolar interaction of 7Li nuclei and magnetic ions, dipolar interaction between nuclei, relaxation due to motion of ions and quadrupolar relaxation. Efficiency of relaxation mechanism depends of value of magnetic field at the position of nucleus and the proximity of the frequency of fluctuating field to Larmor frequency. The magnetic moment of Ni2+ ion is about 1000 times bigger than the magnetic moment of Li nucleus therefore the magnetic field induced by Ni ions is much bigger than one from lithium nuclei. At the same time the electron fluctuations slowdown in the neighborhood of the phase transition and their frequency becomes close to the Larmor frequency only at the very low temperatures. Relaxation due to the ion
1000 t, (IS
Figure 5. Time dependence of the 7Li stimulated spin echo decay at T = 20 K. The solid line is a fit to Eq. (2).
Figure 6. Temperature dependence of the 7Li spin-lattice relaxation rate 1/T1, for Li3Ni2SbO6 (open squares) and Li0.8Ni0.6Sb0.4O2 (solid squares) at frequency 12 MHz. Solid lines are guides for eye.
motion usually appears above the room temperature where the ions starts moving fast enough. Quadrupolar relaxation in our case is ineffective because a quadrupole splitting is very small, as shown in NMR spectra. Therefore, in further discussion we will consider only two contributions to the relaxation, which are resulting by interaction with magnetic ions and by lithium ion mobility.
The temperature dependence of the relaxation rate 1/Ti is shown in Fig. 6. At the temperatures 70 K < T < 250 K, 1/Ti is almost temperature-independent. At T > 250 K, the relaxation shows a slight growth at least up to 450 K. For the pristine compound Li3Ni2SbO6 there is no significant change of the relaxation rate above 100 K up to 450 K (see Fig. 6).
4. Discussion
At the temperatures T > 300 K, the relaxation rate T1-1 in Li0.8Ni0.6Sb0.4O2, increases (see Fig. 6) unlike the temperature-independent relaxation behavior in Li3Ni2SbO6. The only reason for such dependence is a diffusion of Li ions appearing due to the vacancies in lithium positions in the non-stoichiometric sample that is favorable for lithium ion mobility. Spin-lattice relaxation in this case can be described by Bloembergen-Purcell-Pound theory (BBP) and reaches its maximum at the temperature where the correlation time 7 is equal to the 1/©l, where ©l is a Larmor frequency. The correlation rate determined as a ion hopping rate obeys the Arrenius low:
x^1 = x^1
0
exp<
k^T
(3)
where Ea is an activation energy. The relaxation rate due to the ion mobility for T < Tmax can be described [13] by formula:
i i r
1
T
■ = raT
1,diff
exp
KT
The total relaxation rate is the sum of the diffusion and magnetic contributions
T= T+ T
-M 1,diff 1,mag •
(4)
(5)
The relaxation rate due to the interaction with magnetic ions moments is proportional to the temperature and the Ni2+ ion susceptibility [25-27], which obeys the Curie-Weiss law. When the temperature is much higher than Weiss parameter, we can assume T^ = const
Figure 7. 7Li spin-lattice relaxation rate as a function of 1000/7. The solid line shows the result of fitting according the Eq. (6).
300 T(K)
Figure 8. NMR linewidth as a function of temperature. The solid line is a fit by Eq. (7).
(
— = й,
T 1
exp<
kT
- const,
(6)
where the constant value can be estimated as Tr1 at T ~ 200 K. Similar procedure was proposed by Sugiyama et al. when interpreting the MuSR data of lithium diffusion in paramagnetic Li2MnO3 [28]. The value of the activation energy that can be obtained from the fitting of our experimental data is equal to 0.25 eV (Fig. 7). The maximum of the relaxation rate where x0 = 1/ ®L is out of the temperature range of the measurement, so we cannot get the correlation rate value and the diffusion coefficient.
Another way to find activation energy is to investigate the temperature dependence of the NMR linewidth. At T < 250 K, the NMR line is inhomogeneously broadened due to the presence of the magnetic Ni ions creating a distribution of the quasi-static local fields in the sample. At high temperatures, with a developing of lithium ions mobility, the ion jump rate becomes bigger than the rigid lattice linewidth. At the fast mobility limit the hopping becomes so fast that lithium nuclei sense a uniform average local field. All nuclei have the same resonance frequency and so-called motional narrowing of the NMR line is observed. The temperature dependence of the linewidth can be used to get the activation energy value (see, for example, [29]). We used the formula proposed by Wilkening, Martin, et al. [15] for diamagnetics and modified it by adding the term к (T) to the rigid line width,
which takes into account broadening due to the interaction with paramagnetic ions and is proportional to Curie-Weiss susceptibility at high temperature limit:
Av =
-vA R
k ( T
■vAR
B
--1
exP
KT
-C.
(7)
where Av is the line width of the central transition at temperature T, assuming as 1/3 of the total linewidth, vAR and B are parameters, attributed to the line widths of the rigid lattice. C is additional linewidth caused by the inhomogeneity of the external static magnetic field which is almost temperature-independent above 300 K. Fit of the linewidth dependence on temperature shown at Fig. 8 gives an activation energy value about 0.35 eV.
A third way to obtain Ea is the empirical Waugh-Fedin expression [29]:
Ea = 1.617 x 10-3 x Tc
1
here Ea is an activation energy in eV, T is onset of motional narrowing in K. Taking Tc = 200 K, we can determine Ea = 0.323 eV that is comparable to the activation energy value obtained from the linewidth temperature dependence but bigger than one from the relaxation rate slope. Authors of the works [15, 30, 31] notice that the phenomenological equation (7) and the empirical Waugh-Fedin expression (8) usually give the higher value of activation energy than the analysis of the relaxation rates dependence. This indicates that the lineshape investigations can give a correct order of magnitude of the activation energy but appropriate only for a rough estimation of the diffusion parameters in paramagnetic solids with ion mobility.
In view of these results, we may conclude that the vacancies on the lithium positions, which are formed in the samples of Li0.8Ni0.6Sb0.4O2, are actually favorable for ion mobility in the system. The activation energy value obtained from temperature dependence of spin-lattice relaxation rate and NMR linewidth is comparable with the results gotten by other methods for layered lithium contained compounds [5, 32]. On the other hand, we cannot get the correlation rate value and the diffusion coefficient and obtain the information about possible diffusion pathways from our experiments due to the limited range of the achieved temperatures. The measurements of the relaxation in the rotated frame can give an opportunity to solve this problem.
Acknowledgements
This work was supported by grants 14-03-01122 (I.S. and V.N.), 14-02-00245 (E.Z.) and 14-02-01194 (T.S. and E.V.) from Russian Foundation for Basic Research. Initial XRD characterization of Li0.8Ni0.6Sb0.4O2 was supported by the Grant-in-Aid 00-15 from the International Centre for Diffraction Data. The authors also thank Dr. S.N. Polyakov for the Rigaku scan.
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