Your search keyword '"Alp EE"' showing total 18 results

1. Pressure-Induced Collapse of Magnetic Order in Jarosite.

Author

Klein RA, Walsh JPS, Clarke SM, Liu Z, Alp EE, Bi W, Meng Y, Altman AB, Chow P, Xiao Y, Norman MR, Rondinelli JM, Jacobsen SD, Puggioni D, and Freedman DE

Abstract

We report a pressure-induced phase transition in the frustrated kagomé material jarosite at ∼45  GPa, which leads to the disappearance of magnetic order. Using a suite of experimental techniques, we characterize the structural, electronic, and magnetic changes in jarosite through this phase transition. Synchrotron powder x-ray diffraction and Fourier transform infrared spectroscopy experiments, analyzed in aggregate with the results from density functional theory calculations, indicate that the material changes from a R3[over ¯]m structure to a structure with a R3[over ¯]c space group. The resulting phase features a rare twisted kagomé lattice in which the integrity of the equilateral Fe^{3+} triangles persists. Based on symmetry arguments we hypothesize that the resulting structural changes alter the magnetic interactions to favor a possible quantum paramagnetic phase at high pressure.

Published

2020

2. Topological Singularity Induced Chiral Kohn Anomaly in a Weyl Semimetal.

Author

Nguyen T, Han F, Andrejevic N, Pablo-Pedro R, Apte A, Tsurimaki Y, Ding Z, Zhang K, Alatas A, Alp EE, Chi S, Fernandez-Baca J, Matsuda M, Tennant DA, Zhao Y, Xu Z, Lynn JW, Huang S, and Li M

Abstract

The electron-phonon interaction (EPI) is instrumental in a wide variety of phenomena in solid-state physics, such as electrical resistivity in metals, carrier mobility, optical transition, and polaron effects in semiconductors, lifetime of hot carriers, transition temperature in BCS superconductors, and even spin relaxation in diamond nitrogen-vacancy centers for quantum information processing. However, due to the weak EPI strength, most phenomena have focused on electronic properties rather than on phonon properties. One prominent exception is the Kohn anomaly, where phonon softening can emerge when the phonon wave vector nests the Fermi surface of metals. Here we report a new class of Kohn anomaly in a topological Weyl semimetal (WSM), predicted by field-theoretical calculations, and experimentally observed through inelastic x-ray and neutron scattering on WSM tantalum phosphide. Compared to the conventional Kohn anomaly, the Fermi surface in a WSM exhibits multiple topological singularities of Weyl nodes, leading to a distinct nesting condition with chiral selection, a power-law divergence, and non-negligible dynamical effects. Our work brings the concept of the Kohn anomaly into WSMs and sheds light on elucidating the EPI mechanism in emergent topological materials.

Published

2020

3. Element-resolved thermodynamics of magnetocaloric LaFe(13-x)Si(x).

Author

Gruner ME, Keune W, Roldan Cuenya B, Weis C, Landers J, Makarov SI, Klar D, Hu MY, Alp EE, Zhao J, Krautz M, Gutfleisch O, and Wende H

Abstract

By combination of two independent approaches, nuclear resonant inelastic x-ray scattering and first-principles calculations in the framework of density functional theory, we demonstrate significant changes in the element-resolved vibrational density of states across the first-order transition from the ferromagnetic low temperature to the paramagnetic high temperature phase of LaFe(13-x)Si(x). These changes originate from the itinerant electron metamagnetism associated with Fe and lead to a pronounced magneto-elastic softening despite the large volume decrease at the transition. The increase in lattice entropy associated with the Fe subsystem is significant and contributes cooperatively with the magnetic and electronic entropy changes to the excellent magneto- and barocaloric properties.

Published

2015

4. Reentrant valence transition in EuO at high pressures: beyond the bond-valence model.

Author

Souza-Neto NM, Zhao J, Alp EE, Shen G, Sinogeikin SV, Lapertot G, and Haskel D

Abstract

The pressure-dependent relation between Eu valence and lattice structure in model compound EuO is studied with synchrotron-based x-ray spectroscopic and diffraction techniques. Contrary to expectation, a 7% volume collapse at ≈45  GPa is accompanied by a reentrant Eu valence transition into a lower valence state. In addition to highlighting the need for probing both structure and electronic states directly when valence information is sought in mixed-valent systems, the results also show that widely used bond-valence methods fail to quantitatively describe the complex electronic valence behavior of EuO under pressure.

Published

2012

5. Phonon density of states and compression behavior in iron sulfide under pressure.

Author

Kobayashi H, Kamimura T, Alfè D, Sturhahn W, Zhao J, and Alp EE

Abstract

We report the partial phonon densities of states (DOS) of iron sulfide, a possible component of the rocky planet's core, measured by the 57Fe nuclear resonant inelastic x-ray scattering and calculate the total phonon DOS under pressure. From the phonon DOS, we drive thermodynamic parameters. A comparison of the observed and estimated compressibilities makes it clear that there is a large pure electronic contribution in the observed compressibility in the metallic state. Our results present the observation of thermodynamic parameters of iron sulfide with the low-spin state of an Fe2+ ion at the high density, which is similar to the condition of the Martian core.

Published

2004

6. Nuclear resonant magnetometry and its application to Fe/Cr multilayers.

Author

L'abbé C, Meersschaut J, Sturhahn W, Jiang JS, Toellner TS, Alp EE, and Bader SD

Abstract

We introduce nuclear resonant magnetometry as a means to record the magnetization curve of isotopically enhanced regions of a sample. It is based on nuclear resonant scattering with circularly polarized synchrotron radiation and the use of a nuclear resonant reference sample. We apply this approach to study the interlayer coupling in Fe/Cr(100) multilayers and to obtain a layer-specific magnetization curve. Our measurements provide experimental evidence for the existence of a nontrivial interlayer-coupling angle in Fe/Cr/Fe.

Published

2004

7. X-ray interferometry with microelectronvolt resolution.

Author

Shvyd'ko YV, Lerche M, Wille HC, Gerdau E, Lucht M, Rüter HD, Alp EE, and Khachatryan R

Abstract

We demonstrate an interferometer for hard x rays with two back-reflecting sapphire crystal mirrors--a prototype x-ray Fabry-Pérot interferometer. A finesse of 15 and 0.76 mu eV broad Fabry-Pérot transmission resonances are measured by the time response of the interferometer. Interference patterns are observed directly in spectral dependences of reflectivity.

Published

2003

8. Vibrational dynamics of myoglobin determined by the phonon-assisted Mössbauer effect.

Author

Achterhold K, Keppler C, Ostermann A, van Bürck U, Sturhahn W, Alp EE, and Parak FG

Abstract

The phonon-assisted Mössbauer effect is used to determine the partial phonon density of states of the iron within the active center of deoxymyoglobin, carboxymyoglobin, and dry and wet metmyoglobin between 40 and 300 K. Between 0 and 1 meV the iron density of states increases quadratically with the energy, as in a Debye solid. Mean sound velocities are extracted from this slope. Between 1 and 3 meV a nearly quadratic "Debye-like" increase follows due to the similar strength of intermolecular and intramolecular forces. Above 3 meV, optical vibrations are characteristic for the iron-ligand conformation. The overall mean square displacements of the heme iron atom obtained from the density of states agree well with the values of Mössbauer absorption experiments below 180 K. In the physiological temperature regime the data confirm the existence of harmonic vibrations in addition to the protein specific dynamics measured by Mössbauer absorption. In the Debye energy regime the mean square displacement of the iron is in agreement with that of the hydrogens measured by incoherent neutron scattering demonstrating the global character of these modes. At higher energies the vibration of the heavy iron atom at 33 meV in metmyoglobin is as large as that of the lightweight hydrogens at that energy. A freeze dried, rehydrated (h=0.38 g H2O/g protein) metmyoglobin sample shows an excess of states above the Debye law between 1 and 3 meV, similar to neutron scattering experiments. The room temperature density of states below 3 meV exhibit an increase of the density compared to the low temperature data, which can be interpreted as mode softening.

Published

2002

9. Nuclear inelastic x-ray scattering of FeO to 48 GPa.

Author

Struzhkin VV, Mao HK, Hu J, Schwoerer-Böhning M, Shu J, Hemley RJ, Sturhahn W, Hu MY, Alp EE, Eng P, and Shen G

Abstract

The partial density of vibrational states has been measured for Fe in compressed FeO (wüstite) using nuclear resonant inelastic x-ray scattering. Substantial changes have been observed in the overall shape of the density of states close to the magnetic transition around 20 GPa from the paramagnetic (low pressure) to the antiferromagnetic (high pressure) state. The results indicate that strong magnetoelastic coupling in FeO is the driving force behind the changes in the phonon spectrum of FeO. The paper presents the first observation of changes in the density of terahertz acoustic phonon states under magnetic transition at high pressure.

Published

2001

10. Observation of the 22.5-keV resonance in (149)Sm by the nuclear lighthouse effect.

Author

Röhlsberger R, Quast KW, Toellner TS, Lee PL, Sturhahn W, Alp EE, and Burkel E

Abstract

We have observed coherent nuclear resonant scattering of synchrotron radiation at the 22.5-keV resonance of (149)Sm. High-speed rotational sample motion led to an angular deflection of the resonantly scattered radiation off the nonresonant primary beam. This allowed us to determine the resonance energy of the first excited nuclear level of (149)Sm to be 22496(4) eV. Because of the angular deflection of the resonant photons, time spectra of coherent nuclear resonant scattering can be recorded as a function of a spatial coordinate. Time resolutions of a few 10 ps can be expected, which are beyond the limits of existing x-ray detection schemes.

Published

2001

11. Long-range reactive dynamics in myoglobin.

Author

Sage JT, Durbin SM, Sturhahn W, Wharton DC, Champion PM, Hession P, Sutter J, and Alp EE

Subjects

Animals, Binding Sites, Horses, Myoglobin metabolism, Spectrum Analysis, Thermodynamics, Iron Isotopes chemistry, Myoglobin chemistry

Abstract

We report the complete vibrational spectrum of the probe nucleus 57Fe at the oxygen-binding site of the protein myoglobin. The Fe-pyrrole nitrogen stretching modes of the heme group, identified here, probe asymmetric interactions with the protein environment. Collective oscillations of the polypeptide, rather than localized heme vibrations, dominate the low frequency region. We conclude that the heme "doming" mode is significantly delocalized, so that distant sites respond to oxygen binding on vibrational time scales. This has ramifications for understanding long-range interactions in biomolecules, such as those that mediate cooperativity in allosteric proteins.

Published

2001

12. Evidence for an instability near twice the fermi wave vector in the low electronic density liquid metal Li(NH3)4.

Author

Burns CA, Platzman PM, Sinn H, Alatas A, and Alp EE

Abstract

We report high-resolution inelastic x-ray scattering measurements in the metallic liquid Li(NH3)4, which to a good approximation can be treated as a dilute alkali metal. We see a well-defined excitation out to large momentum transfers. This excitation shows a strong softening at wave vectors near the first peak in the structure factor, which occurs near twice the Fermi momentum.

Published

2001

13. gamma-Ray wavelength standard for atomic scales.

Author

Shvyd'ko YV, Lerche M, Jäschke J, Lucht M, Gerdau E, Gerken M, Rüter HD, Wille HC, Becker P, Alp EE, Sturhahn W, Sutter J, and Toellner TS

Abstract

The wavelength of the 57Fe Mössbauer radiation is measured with a relative uncertainty of 0.19 ppm by using almost exact Bragg backscattering from a reference silicon crystal. Its value is determined as lambda(M) = 0.860 254 74(16)x10(-10) m. The corresponding Mössbauer photon energy is E(M) = 14 412.497(3) eV. The wavelength of the 57Fe Mössbauer radiation is easily reproducible with an accuracy of at least 10(-11)lambda(M) and could be used as a length standard of atomic dimensions.

Published

2000

14. Coherent resonant x-ray scattering from a rotating medium.

Author

Rohlsberger R, Toellner TS, Sturhahn W, Quast KW, Alp EE, Bernhard A, Burkel E, Leupold O, and Gerdau E

Abstract

A coherently excited nuclear state in a rotating sample acquires a phase shift during its time evolution that is proportional to its angular momentum and the rotation angle. As a consequence, the radiative decay of the excited state proceeds into the rotated direction, and the time spectrum of the nuclear decay is mapped onto an angular scale. This effect has been observed in nuclear resonant scattering of synchrotron radiation from a 57Fe metal foil rotating at 18 kHz.

Published

2000

15. Phonon density of states measured by inelastic nuclear resonant scattering.

Author

Sturhahn W, Toellner TS, Alp EE, Zhang X, Ando M, Yoda Y, Kikuta S, Seto M, Kimball CW, and Dabrowski B

Published

1995

16. Observation of Pure Nuclear Diffraction from a Fe/Cr Antiferromagnetic Multilayer.

Author

Toellner TS, Sturhahn W, Röhlsberger R, Alp EE, Sowers CH, and Fullerton EE

Published

1995

17. Time resolved nuclear resonant scattering from 119Sn nuclei using synchrotron radiation.

Author

Alp EE, Mooney TM, Toellner T, Sturhahn W, Witthoff E, Röhlsberger R, Gerdau E, Homma H, and Kentjana M

Published

1993

18. Structure of copper microclusters isolated in solid argon.

Author

Montano PA, Shenoy GK, Alp EE, Schulze W, and Urban J

Published

1986