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This research investigates the short-range magnetic correlations in Li(Mn0.976Co0.024)2O4 using neutron scattering and magnetic susceptibility measurements.
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Short range magnetic correlations in spinel Li(Mn0.976Co0.024)2O4
Short range magnetic correlations in spinel Li(Mn0.976Co0.024)2O4 Nanophysics Laboratory, Department of Physics, National Central University
C. C. Yang,a F. C. Tsao,a S. Y. Wu,a W.-H. Li,a* and K. C. Lee,a J. W. Lynn,b R. S. Liu, c aDepartment of Physics, National Central Universtiy, Chung-Li, Taiwan 32054, Republic of China bNIST Center for Neutron Research, NIST, Gaithersburg, Maryland 20899-8562 cDepartment of Chemistry, National Taiwan University, Taipei, Taiwan 106, Republic of China Nanophysics Laboratory, Department of Physics, National Central University
The energy material Li(Mn0.976Co0.024)2O4 was prepared by standard solid-state reaction techniques. The structures are confirmed by varied temperature neutron scattering experiments. From 300 K to 1.8 K, these samples hold cubic Fd3m spinal phase without any structure change. In ac magnetization experiments, M(T) may be described using the Curie-Weiss law for antiferro- magnetic coupling at high temperatures, which T = 86 K. At low temperature, two anomaly peaks are observed at 25 K and 13 K, which are mainly contributed by Mn spins. The neutron magnetic scattering discovered Li(Mn0.0976Co0.024)2O4.036 with varied temp- erature which shows the short-range correlation started from 80 K and saturated around 40 K. _ Abstract Nanophysics Laboratory, Department of Physics, National Central University
As a cathode material for rechargeable lithium-ion batteries, the spinel LiMn2O4 is known [1,2] to be economically a more suitable material than currently popular LiCoO2. Improvement in the rechargeable cycle-performance at room temperature has been reported [3] in Li-rich systems, and a small amount of Co-doping has been found to stabilize the structure. A polycrystalline sample of Li(Mn0.976Co0.024)2O4 was prepared by employing the standard solid-state reaction techniques. High purity Li2CO3, MnO2, and CoO powders were evenly mixed at a stoichiometric molar ratio, and then sintered in air at 800°C for 24 h, followed by slowly cooling to room temperature. High-resolution neutron powder diffraction and Rietveld analysis [4] were employed to determine the detailed structural parameters. The diffraction pattern was collected on the BT-1 powder diffractometer at the NIST Center for Neutron Research, employing a Cu(311) monochromator crystal to extract =1.5402 Å neutrons. The diffraction pattern taken at 300 K displayed a cubic Fd3m symmetry as Fig. 1, occupy their which is the same structure as the reported onethe for undoped compound [5,6]. Both the Li and Mn/Co atoms occupy their normal sites, and the Co atoms enter the Mn sites. Analysis of the occupancy factors gave a chemical formula of Li(Mn0.976Co0.024)2O4.036 for the present compound as list in the table 1. No traces of any impurity phases were found, as the temperature was reduced to 7 K, showing that 2.4% Co-doping stabilizing the crystalline structure against temperature change. _ Structural Analysis Nanophysics Laboratory, Department of Physics, National Central University
Magnetic Susceptibility The effects of Co-doping on the magnetic properties of the system were studied by means of ac magnetic susceptibility and neutron magnetic diffraction measurements. Neutron magnetic diffraction measurements were also conducted at the NIST Center for Neutron Research, using the BT-9 triple-axis spectrometers, with a pyrolytic graphite PG(002) monochromator crystal and PG filters to extract =2.359 Å neutrons.Figure 2 shows the in-phase component of the ac magnetic susceptibility, χ(T), measured at various applied dc magnetic fields. The main features perceivable in χ(T) are the peaks at ~15 K. Finite values for χ were obtained at low temperatures, cusps in the χ(T) curves are clearly seen, and an applied field suppresses the responses in χ at low temperatures, suggesting the existence of both the ferromagnetic and antiferromagnetic components for the Mn moments. Although the peaks occur at ~15 K, the correlations between the Mn spins develop at a much higher temperature, as indicated by the observations that χ(T) departs from the Curie-Weiss behavior at ~150 K, as can be seen in the 1/χ curve shown in the inset to Fig. 2. Nanophysics Laboratory, Department of Physics, National Central University
Magnetic Neutron Diffraction Figure 3 shows the magnetic diffraction pattern obtained at 1.4 K. Two broad peaks at around 2θ=31 and 45, with very different widths, are clearly revealed, signaling the development of short-range magnetic correlations among the Mn spins, as the temperature was reduced from 160 to 1.4 K. Detail investigations show that the magnetic intensities include three peaks, as marked by the dashed curves shown in Fig. 3. The magnetic diffraction pattern observed for the 2.4% Co-doped compound is similar to that was observed [6] in the undoped compound, but with the widths of the peaks are much broader. As has been observed [6,7] in the undoped compound, there are both the ferromagnetic, characterized by the {111} peak, and antiferromagnetic, characterized by the {01½} and {011} peaks, components for the Mn moments in the 2.4% Co-doped compound. The magnetic correlation lengths that we obtained for the 2.4% Co-doped compound at 1.4 K are 100 Å and 30 Å for the antiferromagnetic and ferromagnetic components, respectively, which are somewhat smaller than the 120 Å and 40 Å observed for the undoped compound [6]. The temperature dependence of the intensity at 2θ=31 is shown in Fig. 3, showing that the magnetic correlations began to develop below Tm=150 K. The Tm observed for the 2.4% Co-doped compound is almost a factor of 2 higher than that of the undoped compound, indicating that the Co-doping enhancing the couplings between the Mn spins. Nanophysics Laboratory, Department of Physics, National Central University
Acknowledgements The work at was supported by the NSC of the ROC under Grant No. NSC 91-2112-M-008-056. Reference 1. M. Thackeray et al., Mater. Res. Bull. 18, 461 (1983). 2. D. Guyomard et al., Solid State Ionics 69, 222 (1994). 3. R. J. Gummow et al., Solid State Ionic 69, 59 (1994). 4. H. M. Rietveld, J. Appl. Cryst. 2, 65 (1969). 5. W. I. F. David et al., J. Solid State Chem. 67, 316 (1987). 6. C. C. Yang et al., Mat. Sci. Eng. B 95, 162 (2002). 7. I Tomeno et al., Phys. Rev. B 64, 94422 (2001). Nanophysics Laboratory, Department of Physics, National Central University
10000 Li(Mn0.976Co0.024)2O4.036 T = 300 K, Fd3m λ = 1.5402 Å, 15'-20'–7' a = 8.23256(8) Å Li (¼, ¼, ¼), Mn(½, ½, ½) O(x, x, x), x=0.26338(4) _ 8000 6000 4000 Neutron Counts 2000 0 0 20 40 60 80 100 120 140 160 Scattering Angle 2 ( deg. ) The neutron-powder-diffraction pattern of sample Li0.96(Mn0.976Co0.024)2O4.036 at room temperature. Observed (crosses) and Fd3m-fitted (solid lines) patterns with their differences plotted at the bottom. The inset table shows the fitting parameter at other different temperatures. _ Fig. 1. Nanophysics Laboratory, Department of Physics, National Central University
150 K Temperature dependence of (a) and (b), measured using a probing field with an rms strength of 10 Oe and a frequency of 103 Hz, and the insert shows the dependence of applied field. The main feature is the cusp at ~13 K, which signifies the ordering of the Mn spins with an antiferromagnetic character. Anomalies observed around 25 K which is govern by the ratio of Mn3+/ Mn4+ ion. Fig. 2. Nanophysics Laboratory, Department of Physics, National Central University
Differences between the diffraction patterns token at 1.4 and 140 K. The broaden peak between 27 ~ 37 show the short-range magnetic ordering of Mn. Fig. 3. Nanophysics Laboratory, Department of Physics, National Central University
Temperature dependence of the 31 peak intensity where the solid lines are only guides to the eye. The 31 intensity disappears at 130 K. Fig. 4. Nanophysics Laboratory, Department of Physics, National Central University
Li(Mn0.976Co0.024)2O4 Neutron diffraction pattern taken at various temperatures. No structure change observed between 9 K~300 K. The inset show the temperature dependence of fitted lattice parameters, Mn-O length, and Mn-O-Mn angle. The lattice parameters and Mn-O length increasing monotonically as thermo expansion. No obvious changes on the Mn-O-Mn angle were seen. Fig. 5. Nanophysics Laboratory, Department of Physics, National Central University
Li(Mn0.95Co0.05)2O4 Neutron scattering pattern taken at different temperature. No structure change observed between 7 K~300 K. The inset show the temperature dependence of lattice parameters, Mn-O length and Mn-O-Mnangle got from structure refinement. The lattice parameters and Mn-O length increasing monotonically as thermo expansion. No observed change of Mn-O-Mn angle. Fig. 6. Nanophysics Laboratory, Department of Physics, National Central University
Temperature dependence of (a) and (b), measured using a probing field with an rms strength of 10 Oe and a frequency of 103 Hz, and the insert shows the dependence of applied field. The main feature is the cusp at ~13 K, which signifies the ordering of the Mn spins with an antiferromagnetic character. Anomalies observed around 25 K which is govern by the ratio of Mn3+/ Mn4+ ion. The red curve was Curie-Weiss fit of zero field experiment. We can get the fitting parameter Tθ~57 K and eff ~3.33 B. Fig. 7. Nanophysics Laboratory, Department of Physics, National Central University
(a) (b) Li(Mn0.95Co0.05)2O4 λ = 2.359 A 40’-48’-40’ (c) (d) The neutron magnetic diffraction patterns of Li(Mn0.95Co0.05)2O4 , taken at various temperatures, Showing the development of magnetic correlations when the temperature was reduced. Fig. 8. Nanophysics Laboratory, Department of Physics, National Central University
(e) (f) (g) (h) The neutron magnetic scattering pattern of Li(Mn0.95Co0.05)2O4. The Fig (e), (f), (g), (h) were collected at 65 K, 80 K, 110 K, 120 K, which show the growth of short range magnetic ordering. Fig. 9. Nanophysics Laboratory, Department of Physics, National Central University
_ Table. 1. Nanophysics Laboratory, Department of Physics, National Central University