Low-energy magnetic excitations in Co/CoO core/shell nanoparticles

Feygenson, Mikhail; Teng, Xiaowei; Inderhees, S. E.; Yiu, Yuen; Du, Wenxin; Han, Wei; Wen, Jinsheng; Xu, Z. J.; Podlesnyak, A.; Niedziela, Jennifer L.; Hagen, M.; Qiu, Yiming; Brown, Craig M.; Zhang, L.; Aronson, M. C.

doi:10.1103/physrevb.83.174414

Cited by 21 publications

(24 citation statements)

References 84 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…We therefore have no evidence for the low-energy spin excitations claimed to be seen in Ref. 40 below the gapped (∼25 meV) onemagnon excitations described previously.…”

Section: Search For Low-energy Crystal Fieldsmentioning

confidence: 52%

Neutron scattering investigation of thed−dexcitations below the Mott gap of CoO

et al. 2013

View full text Add to dashboard Cite

Neutron scattering is used to investigate the single-ion spin and orbital excitations below the Mott-Hubbard gap in CoO. Three excitations are reported at 0.870±0.009 eV, 1.84±0.03, and 2.30±0.15 eV. These were parameterized within a weak crystal field scheme with an intra-orbital exchange of J(dd)=1.3 ± 0.2 eV and a crystal field splitting 10Dq=0.94 ± 0.10 eV. A reduced spinorbit coupling of λ=-0.016± 0.003 eV is derived from dilute samples of Mg0.97Co0.03O, measured to remove complications due to spin exchange and structural distortion parameters which split the cubic phase degeneracy of the orbital excitations complicating the inelastic spectrum. The 1.84 eV, while reported using resonant x-ray and optical techniques, was absent or weak for non resonant x-ray experiments and overlaps with the expected position of a 4 A2 level. This transition is absent in the dipolar approximation but expected to have a finite quadrupolar matrix element that can be observed with neutron scattering techniques at larger momentum transfers. Our results agree with a crystal field analysis (in terms of Racah parameters and Tanabe-Sugano diagrams) and with previous calculations performed using local-density band theory for Mott insulating transition metal oxides. The results also demonstrate the use of neutron scattering for measuring dipole forbidden transitions in transition metal oxide systems.

show abstract

“…We therefore have no evidence for the low-energy spin excitations claimed to be seen in Ref. 40 below the gapped (∼25 meV) onemagnon excitations described previously.…”

Section: Search For Low-energy Crystal Fieldsmentioning

confidence: 52%

Neutron scattering investigation of thed−dexcitations below the Mott gap of CoO

et al. 2013

View full text Add to dashboard Cite

show abstract

“…A key difference between MnF 2 and both α-CoV 3 O 8 and FeF 2 is the presence of strong crystal field effects and spin-orbit coupling in the latter two compounds 133,175 . It is also worth noting that unlike the case of pure CoO 81,91,94,[181][182][183][184] where the large and far reaching exchange constants result in a significant and ultimately problematic entanglement of spin-orbit levels 94 , in the case of α-CoV 3 O 8 , the exchange constants are weak and the Weiss temperature is near 0 K. Both observations suggest that the presence of both strong crystal field effects and spin-orbit coupling with well-separated j eff manifolds, as is the case for α-CoV 3 O 8 , may be central to making the dynamics robust against strong disorder.…”

Section: Comparison Between α-Cov3o8 and Randommentioning

confidence: 99%

Ordered magnetism in the intrinsically decorated jeff=12α−CoV3O8

et al. 2018

View full text Add to dashboard Cite

The antiferromagnetic mixed valence ternary oxide α-CoV3O8 displays disorder on the Co 2+ site that is inherent to the Ibam space group resulting in a local selection rule requiring one Co 2+ and one V 4+ reside next to each other, thus giving rise to an intrinsically disordered magnet without the need for any external influences such as chemical dopants or porous media. The zero field structural and dynamic properties of α-CoV3O8 have been investigated using a combination of neutron and x-ray diffraction, DC susceptibility, and neutron spectroscopy. The low temperature magnetic and structural properties are consistent with a random macroscopic distribution of Co 2+ over the 16k metal sites. However, by applying the sum rules of neutron scattering we observe the collective magnetic excitations are parameterized with an ordered Co 2+ arrangement and critical scattering consistent with a three dimensional Ising universality class. The low energy spectrum is well-described by Co 2+ cations coupled via a three dimensional network composed of competing ferromagnetic and stronger antiferromagnetic superexchange within the ab plane and along c, respectively. While the extrapolated Weiss temperature is near zero, the 3D dimensionality results in long range antiferromagnetic order at T N ∼ 19 K. A crystal field analysis finds two bands of excitations separated in energy at ω ∼ 5 meV and 25 meV, consistent with a j eff = 1 2 ground state with little mixing between spin-orbit split Kramers doublets. A comparison of our results to the random 3D Ising magnets and other compounds where spin-orbit coupling is present indicate that the presence of an orbital degree of freedom, in combination with strong crystal field effects and well-separated j eff manifolds may play a key role in making the dynamics largely insensitive to disorder.

show abstract

“…It is found that above some threshold magnetic field the uniform precessional mode, i.e., the k = 0 magnons decay into nonuniform magnons (k = 0), i.e., the Zeeman energy stays in the magnetic subsystem and scatters between magnon modes. [17][18][19][20] However, in ultrafast magnetization reversal the high-energy electrons generated by the laser field decay into the lower-energy magnon excitations. [22][23][24] In both cases spin-orbit coupling (SOC) is responsible for the transfer of the angular momentum to the lattice through different scattering mechanisms such as magnon-magnon, magnon-phonon, magnon-impurity scattering, and so on, where each process has a different relaxation time.…”

mentioning

confidence: 99%

“…12 In current devices the switching speeds have reached a point where dynamical effects are becoming very important [12][13][14][15][16] Magnons are created in fast (field driven) as well as ultrafast (laser induced) magnetization reversal processes. [17][18][19][20][21][22][23][24][25][26] The former case is of particular interest for current device applications. It is found that above some threshold magnetic field the uniform precessional mode, i.e., the k = 0 magnons decay into nonuniform magnons (k = 0), i.e., the Zeeman energy stays in the magnetic subsystem and scatters between magnon modes.…”

mentioning

confidence: 99%

Strong magnon softening in tetragonal FeCo compounds

2013

View full text Add to dashboard Cite

Magnons play an important role in fast precessional magnetization reversal processes serving as a heat bath for dissipation of the Zeeman energy and thus being responsible for the relaxation of magnetization. Employing ab initio many-body perturbation theory we studied the magnon spectra of the tetragonal FeCo compounds considering three different experimental c/a ratios, c/a = 1.13, 1.18, and 1.24 corresponding to FeCo grown on Pd, Ir, and Rh, respectively. We find that for all three cases the short-wavelength magnons are strongly damped and tetragonal distortion gives rise to a significant magnon softening. The magnon stiffness constant D decreases almost by a factor of 2 from FeCo/Pd to FeCo/Rh. The combination of soft magnons together with the giant magnetic anisotropy energy suggests FeCo/Rh to be a promising material for perpendicular magnetic recording applications. Since the introduction of the first commercial hard disk drive in 1956, the recording density in a hard disk, that is, the amount of information that can be stored per square inch, has increased by more than seven orders of magnitude to meet an ever-growing need.1 This has been achieved by a simple scaling of the dimensions of the bits recorded in storage medium. Due to the superparamagnetic effect, however, the recording density has an upper limit. For longitudinal magnetic recording it is around 200 Gbit per square inch, whereas it is predicted to be much larger for perpendicular recording, up to 1000 Gbit per square inch, though this limit is constantly changing with the discovery of new materials. 2-4The major problem in designing magnetic storage media is to retain the magnetization of the medium over a long period of time despite thermal fluctuations. If the ratio of the thermal energy k B T to the magnetic energy per grain K u V , where V is the grain volume and K u is the uniaxial magnetocrystalline anisotropy energy (MAE), becomes sufficiently large, the thermal fluctuations can reverse the magnetization in a region of the medium, destroying the data stored there. 3,5 In order to further increase the recording density in future recording media, high-K u materials are needed. 6 Additionally, a large saturation magnetization M s is beneficial to reduce the write field, which has to be applied by the writing head. Materials that combine the desired large values of K u and M s are tetragonal near-equiatomic FeCo alloys. The large values of K u and M s in these alloys were first predicted by first-principles calculations 7 and then confirmed by experiments. [8][9][10][11] In particular, Yildiz et al.11 achieved a strong perpendicular magnetic anisotropy (PMA) in tetragonal FeCo alloys epitaxially grown on Pd (c/a = 1.13), Ir (c/a = 1.18), and Rh (c/a = 1.24) substrates. The authors found that the PMA is very sensitive to the tetragonal distortion and increases with increasing c/a ratio, which allows to tune the PMA by growing the alloys on different substrates.Besides large K u and M s values, another very important issue in magnetic recor...

show abstract

Low-energy magnetic excitations in Co/CoO core/shell nanoparticles

Cited by 21 publications

References 84 publications

Neutron scattering investigation of thed−dexcitations below the Mott gap of CoO

Neutron scattering investigation of thed−dexcitations below the Mott gap of CoO

Ordered magnetism in the intrinsically decorated jeff=12α−CoV3O8

Strong magnon softening in tetragonal FeCo compounds

Contact Info

Product

Resources

About