Your search keyword '"Qu D"' showing total 23 results

1. Development of ferromagnetism in the doped topological insulator Bi_(2−x)Mn_xTe_3

Author

Hor, Y. S., Roushan, P., Beidenhopf, H., Seo, J., Qu, D., Checkelsky, J. G., Wray, L. A., Hsieh, D., Xia, Y., Xu, S.-Y., Qian, D., Hasan, M. Z., Ong, N. P., Yazdani, A., and Cava, R. J.

Subjects

Condensed Matter::Materials Science, Condensed Matter::Superconductivity, Condensed Matter::Strongly Correlated Electrons

Abstract

The development of ferromagnetism in Mn-doped Bi_2Te_3 is characterized through measurements on a series of single crystals with different Mn content. Scanning tunneling microscopy analysis shows that the Mn substitutes on the Bi sites, forming compounds of the type Bi_(2−x)Mn_xTe_3, and that the Mn substitutions are randomly distributed, not clustered. Mn doping first gives rise to local magnetic moments with Curie-like behavior, but by the compositions Bi_(1.96)Mn_(0.04)Te_3 and Bi_(1.91)Mn_(0.09)Te_3, a second-order ferromagnetic transition is observed, with T_C∼9–12 K. The easy axis of magnetization in the ferromagnetic phase is perpendicular to the Bi2Te3 basal plane. Thermoelectric power and Hall effect measurements show that the Mn-doped Bi_2Te_3 crystals are p-type. Angle-resolved photoemission spectroscopy measurements show that the topological surface states that are present in pristine Bi_2Te_3 are also present at 15 K in ferromagnetic Mn-doped Bi2−xMnxTe3 and that the dispersion relations of the surface states are changed in a subtle fashion.

Published

2010

2. Extreme sensitivity of superconductivity to stoichiometry in Fe1+?Se

Author

McQueen, T.M. (author), Huang, Q. (author), Ksenofontov, V. (author), Felser, C. (author), Xu, Q. (author), Zandbergen, H. (author), Hor, Y.S. (author), Allred, J. (author), Williams, A.J. (author), Qu, D. (author), Checkelsky, J. (author), Ong, N.P. (author), Cava, R.J. (author), McQueen, T.M. (author), Huang, Q. (author), Ksenofontov, V. (author), Felser, C. (author), Xu, Q. (author), Zandbergen, H. (author), Hor, Y.S. (author), Allred, J. (author), Williams, A.J. (author), Qu, D. (author), Checkelsky, J. (author), Ong, N.P. (author), and Cava, R.J. (author)

Abstract

The recently discovered iron arsenide superconductors appear to display a universal set of characteristic features, including proximity to a magnetically ordered state and robustness of the superconductivity in the presence of disorder. Here we show that superconductivity in Fe1+?Se, which can be considered the parent compound of the superconducting arsenide family, is destroyed by very small changes in stoichiometry. Further, we show that nonsuperconducting Fe1+?Se is not magnetically ordered down to 5 K. These results suggest that robust superconductivity and immediate instability against an ordered magnetic state should not be considered as intrinsic characteristics of iron-based superconducting systems., Kavli Institute of Nanoscience, Applied Sciences

Published

2009

3. Self-consistent determination of spin Hall angles in selected 5d metals by thermal spin injection.

Author

Qu, D., Huang, S. Y., Miao, B. F., Huang, S. X., and Chien, C. L.

Subjects

*SPIN Hall effect, *ANGLES, *SPINTRONICS, *METALS, *THIN films

Abstract

We demonstrate a self-consistent and versatile method to determine the relative spin Hall angle θSH and spin diffusion length λSF of selected 5d metals (Pt, Au, Ta, and W) by thermal spin injection from a common ferromagnetic insulator, yttrium iron garnet, into thin metal films of various thicknesses. The values of θSH for Pt and Au are opposite in sign to those of Ta and W. The inverse spin Hall effect voltage depends on spin Hall resistivity, which is the product of θSH and electrical resistivity. We also show evidence of magnetic proximity effects including magnetoresistance and the anomalous Hall effect in these 5d metals, except for Au. [ABSTRACT FROM AUTHOR]

Published

2014

4. Intrinsic Spin Seebeck Effect in Au/YIG.

Author

Qu, D., Huang, S. Y., Jun Hu, Ruqian Wu, and Chien, C. L.

Subjects

*SEEBECK effect, *YTTRIUM iron garnet, *PLATINUM, *MAGNETORESISTANCE, *HALL effect, *SPIN excitations

Abstract

The acute magnetic proximity effects in Pt/YIG compromise the suitability of Pt as a spin current detector. We show that Au/YIG, with no anomalous Hall effect and a negligible magnetoresistance, allows the measurements of the intrinsic spin Seebeck effect with a magnitude much smaller than that in Pt/YIG. The experiment results are consistent with the spin polarized density functional calculations for Pt with a sizable and Au with a negligible magnetic moment near the interface with YIG. [ABSTRACT FROM AUTHOR]

Published

2013

5. Inverse spin Hall effect in Aux Ta1-x alloy films.

Author

Qu, D., Huang, S. Y., Guo, G. Y., and Chien, C. L.

Subjects

*SPIN Hall effect, *GOLD alloys, *TANTALUM alloys

Abstract

Gold (Au) and tantalum (Ta) metals are two important spin Hall materials with diametrically different crystalline structure, resistivity, and spin Hall angle. By vapor quenching, Aux Ta1-x alloys of different crystalline and amorphous structures, stable and metastable, have been formed over the entire composition range. We have studied the inverse spin Hall voltage induced by the longitudinal spin Seebeck effect in Aux Ta1-x alloy films. We have found that the inverse spin Hall voltage Δ V ISHE , resistivity ρ , and the spin Hall angle θ S H vary smoothly with composition. Both the spin Hall angle and the spin Hall conductivity exhibit a quasilinear dependence on composition in the concentrated alloy regime, despite drastic differences in other properties. As corroborated by first-principles calculation, we show that the contribution to spin Hall effect in Aux Ta1-x alloy is dominated by the number of valence electrons. We also show that the magnetoresistance correlates with the spin Hall angle. [ABSTRACT FROM AUTHOR]

Published

2018

6. Reply to "Comment on 'Hybrid magnetoresistance in the proximity of a ferromagnet' ".

Author

Huang, S. Y., Qu, D., Cai, J. W., Miao, B. F., and Chien, C. L.

Subjects

*FERROMAGNETIC materials, *MAGNETIC fields

Abstract

A response by the authors to a letter to the editor about the article "Hybrid magnetoresistance in the proximity of a ferromagnet," by Y.M. Lu et al. published in this issue of the journal is presented.

Published

2014

7. Inverse spin Hall effect in Cr: Independence of antiferromagnetic ordering.

Author

Qu, D., Huang, S. Y., and Chien, C. L.

Subjects

*HALL effect, *ELECTRIC currents, *ANTIFERROMAGNETIC materials, *MAGNETIC field effects, *MOLECULAR physics

Abstract

Chromium is a 3d spin-density wave antiferromagnetic (AF) metal with a Néel temperature of 311 K. By using the thermal spin injection method, we have observed a large inverse spin Hall voltage in Cr. With a negligible magnetic proximity effect and a large spin Hall angle, Cr is an intrinsic pure spin current detector that is superior to many 5d metals. Even more strikingly, the temperature dependent thermal spin injection measurements show that the large spin Hall angle in Cr is independent of the AF ordering, and indicating that the inverse spin Hall effect is unrelated to AF ordering in Cr. [ABSTRACT FROM AUTHOR]

Published

2015

8. Physical Origins of the New Magnetoresistance in Pt/YIG.

Author

Miao, B. F., Huang, S. Y., Qu, D., and C. L. Chien

Subjects

*MAGNETORESISTANCE, *YTTRIUM iron garnet, *FERRIMAGNETISM, *PROXIMITY effect (Electron beam lithography), *ALUMINUM

Abstract

A new type of magnetoresistance (MR) observed in Pt/YIG when nominally nonmagnetic Pt comes in contact with a ferrimagnetic insulator yttrium iron garnet (YIG) has drawn intense experimental and theoretical interest. In this Letter, we experimentally demonstrate two physical origins of the new MR: a spin current across the Pt/YIG interface and the magnetic proximity effect. The new MR can also be reproduced when Pt is in contact with a nonmagnetic insulator doped with a few percent of Fe impurities. By tuning the YIG surface and inserting an Au layer between the Pt and YIG, we are able to separate the two contributions. [ABSTRACT FROM AUTHOR]

Published

2014

9. Inverse Spin Hall Effect in a Ferromagnetic Metal.

Author

Miao, B. F., Huang, S. Y., Qu, D., and Chien, C. L.

Subjects

*SPIN Hall effect, *FERROMAGNETIC materials, *SPIN-orbit interactions, *YTTRIUM iron garnet, *ANGULAR momentum (Mechanics), *COUPLING agents (Chemistry)

Abstract

The inverse spin Hall effect (ISHE) has been observed only in nonmagnetic metals, such as Pt and Au, with a strong spin-orbit coupling. We report the observation of ISHE in a ferromagnetic permalloy (Py) on ferromagnetic insulator yttrium iron garnet (YIG). Through controlling the spin current injection by altering the Py-YIG interface, we have isolated the spin current contribution and demonstrated the ISHE in a ferromagnetic metal, the reciprocal phenomenon of the anomalous Hall effect. A large spin Hall angle in Py, determined from Py thin films of different thicknesses, indicates many other ferromagnetic metals may be exploited as superior pure spin current detectors and for applications in spin current. [ABSTRACT FROM AUTHOR]

Published

2013

10. Transport Magnetic Proximity Effects in Platinum.

Author

Huang, S. Y., Fan, X., Qu, D., Chen, Y. P., Wang, W. G., Wu, J., Chen, T. Y., Xiao, J. Q., and Chien, C. L.

Subjects

*SPIN-orbit interactions, *PLATINUM, *RELAXATION phenomena, *FERROMAGNETISM, *THIN films, *ELECTRIC insulators & insulation, *THERMAL analysis, *SEEBECK effect

Abstract

Platinum (Pt) metal, being nonmagnetic and with a strong spin-orbit coupling interaction, has been central in detecting the pure spin current and establishing most of the recent spin-based phenomena. Magnetotransport measurements, both electrical and thermal, conclusively show strong ferromagnetic characteristics in thin Pt films on the ferromagnetic insulator due to the magnetic proximity effects. The pure spin current phenomena measured by Pt, including the inverse spin Hall and the spin Seebeck effects, are thus contaminated and not exclusively established. [ABSTRACT FROM AUTHOR]

Published

2012

11. Absence of Evidence of Electrical Switching of the Antiferromagnetic Néel Vector.

Author

Chiang, C. C., Huang, S. Y., Qu, D., Wu, P. H., and Chien, C. L.

Subjects

*DENSITY currents, *MAGNETORESISTANCE, *EVIDENCE, *TORQUE

Abstract

Much theoretical and experimental attention has been focused on the electrical switching of the antiferromagnetic (AFM) Néel vector via spin-orbit torque. Measurements employing multiterminal patterned structures of Pt/AFM show recurring signals of the supposedly planar Hall effect and magnetoresistance, implying AFM switching. We show in this Letter that similar signals have been observed in structures with and without the AFM layer, and of an even larger magnitude using different metals and substrates. These may not be the conclusive evidence of spin-orbit torque switching of AFM, but the thermal artifacts of patterned metal structure on substrate. Large current densities in the metallic devices, beyond the Ohmic regime, can generate unintended anisotropic thermal gradients and voltages. AFM switching requires unequivocal detection of the AFM Néel vector before and after SOT switching. [ABSTRACT FROM AUTHOR]

Published

2019

12. Manipulation of pure spin current in ferromagnetic metals independent of magnetization.

Author

Dai Tian, Yufan Li, Qu, D., Huang, S. Y., Xiaofeng Jin, and Chien, C. L.

Subjects

*FERROMAGNETIC materials, *MAGNETIZATION, *SPIN Hall effect

Abstract

Upon the injection of a pure spin current, a ferromagnet, similar to a nonmagnetic metal, also exhibits inverse spin Hall effect (ISHE). We show in Co/Cu/YIG, where the thin Cu layer allows transmission of spin current from YIG into Co but decouples the two ferromagnets, that the interaction between ISHE and ferromagnetic ordering in Co can be unambiguously investigated. By switching on and off the pure spin current contribution, we demonstrate that the ISHE in Co is independent of the direction of the Co magnetization, which clearly suggests that the ISHE in Co is dominated not by the extrinsic impurity scatterings, but from the intrinsic origin. [ABSTRACT FROM AUTHOR]

Published

2016

13. Separation of Inverse Altermagnetic Spin-Splitting Effect from Inverse Spin Hall Effect in RuO_{2}.

Author

Liao CT, Wang YC, Tien YC, Huang SY, and Qu D

Abstract

Recently, a significant amount of attention has been attracted toward a third classification of magnetism, altermagnetism, due to the unique physical properties of altermagnetic materials, which are compensated collinear antiferromagnets that host time-reversal symmetry-breaking phenomena like a ferromagnet. In an altermagnetic material, through the nonrelativistic altermagnetic spin-splitting effect (ASSE), a transverse spin current is generated upon charge current injection. However, it is very challenging to experimentally establish the ASSE since it is inevitably mixed with the spin Hall effect due to the relativistic spin-orbit coupling of the material. Additionally, the dependence on the hard-to-probe and hard-to-control Néel vectors makes it even more difficult to observe and establish the ASSE. In this Letter, we utilize the thermal spin injection from the ferrimagnetic insulator yttrium iron garnet and detect an inverse altermagnetic spin-splitting effect (IASSE) in the high-quality epitaxial altermagnetic RuO_{2} thin films. We observe an opposite sign for the spin-to-charge conversion through the IASSE compared to the inverse spin Hall effect (ISHE). The efficiency of the IASSE is approximately 70% of the ISHE in RuO_{2}. Moreover, we demonstrate that the ASSE or IASSE effect is observable only when the Néel vectors are well aligned. By modifying the Néel vector domains via RuO_{2} crystallinity, we study the ASSE or IASSE unequivocally and quantitatively. Our Letter provides significant insight into the spin-splitting effect in altermagnetic materials.

Published

2024

14. Experimental Observation of the Yang-Lee Quantum Criticality in Open Quantum Systems.

Author

Gao H, Wang K, Xiao L, Nakagawa M, Matsumoto N, Qu D, Lin H, Ueda M, and Xue P

Abstract

The Yang-Lee edge singularity was originally studied from the standpoint of mathematical foundations of phase transitions. However, direct observation of anomalous scaling with the negative scaling dimension has remained elusive due to an imaginary magnetic field required for the nonunitary criticality. We experimentally implement an imaginary magnetic field with an open quantum system of heralded single photons, directly measure the partition function, and demonstrate the Yang-Lee edge singularity via the quantum-classical correspondence. We also demonstrate unconventional scaling laws for finite-temperature quantum dynamics.

Published

2024

15. Unequivocal Identification of Spin-Triplet and Spin-Singlet Superconductors with Upper Critical Field and Flux Quantization.

Author

Chiang CC, Lee HC, Lin SC, Qu D, Chu MW, Chen CD, Chien CL, and Huang SY

Abstract

Spin-triplet superconductors play central roles in Majorana physics and quantum computing but are difficult to identify. We show the methods of kink-point upper critical field and flux quantization in superconducting rings can unequivocally identify spin-singlet, spin-triplet in centrosymmetric superconductors, and singlet-triplet admixture in noncentrosymmetric superconductors, as realized in γ-BiPd, β-Bi_{2}Pd, and α-BiPd, respectively. Our findings are essential for identifying triplet superconductors and exploring their quantum properties.

Published

2023

16. Generalized Quantum Measurements on a Higher-Dimensional System via Quantum Walks.

Author

Wang X, Zhan X, Li Y, Xiao L, Zhu G, Qu D, Lin Q, Yu Y, and Xue P

Abstract

Quantum measurements play a fundamental role in quantum mechanics. Especially, generalized quantum measurements provide a powerful and versatile tool to extract information from quantum systems. However, how to realize them on an arbitrary higher-dimensional quantum system remains a challenging task. Here we propose a simple recipe for the implementation of a general positive-operator valued measurement (POVM) on a higher-dimensional quantum system via a one-dimensional discrete-time quantum walk with a two-dimensional coin. Furthermore, using single photons and linear optics, we realize experimentally a symmetric, informationally complete (SIC) POVM on a three-dimensional system with high fidelity. As an application, we realize a qutrit state tomography with SIC-POVM and confirm that the infidelity scaling achieved by the qutrit SIC-POVM is as good as that based on mutually unbiased bases. Our study paves the way to explore physics and information in higher-dimensional quantum systems and finds applications in various quantum information processing tasks that rely on generalized quantum measurements.

Published

2023

17. Observation of Vector Spin Seebeck Effect in a Noncollinear Antiferromagnet.

Author

Xu J, He J, Zhou JS, Qu D, Huang SY, and Chien CL

Abstract

Spintronic phenomena to date have been established in magnets with collinear moments, where the spin injection through the spin Seebeck effect (SSE) is always along the out-of-plane direction. Here, we report the observation of a vector SSE in a noncollinear antiferromagnet (AF) LuFeO_{3}, where temperature gradient along the out-of-plane and also the in-plane directions can both inject a pure spin current and generate a voltage in the heavy metal via the inverse spin Hall effect (ISHE). We show that the thermovoltages are due to the magnetization from canted spins in LuFeO_{3}. Furthermore, in contrast to the challenges of generating, manipulating, and detecting spin current in collinear AFs, the vector SSE in LuFeO_{3} is readily viable in zero magnetic field and can be controlled by a small magnetic field of about 150 Oe at room temperature. The noncollinear AFs expand new realms for exploring spin phenomena and provide a new route to low-field antiferromagnetic spin caloritronics and magnonics.

Published

2022

18. Exploiting Spin Fluctuations for Enhanced Pure Spin Current.

Author

Wu PH, Qu D, Tu YC, Lin YZ, Chien CL, and Huang SY

Abstract

We demonstrate the interplay of pure spin current, spin-polarized current, and spin fluctuation in 3d Ni_{x}Cu_{1-x}. By tuning the compositions of the Ni_{x}Cu_{1-x} alloys, we separate the effects due to the pure spin current and spin-polarized current. By exploiting the interaction of spin current with spin fluctuation in suitable Ni-Cu alloys, we obtain an unprecedentedly high spin Hall angle of 46%, about 5 times larger than that in Pt, at room temperature. Furthermore, we show that spin-dependent thermal transport via anomalous Nernst effect can serve as a sensitive magnetometer to electrically probe the magnetic phase transitions in thin films with in-plane anisotropy. The enhancement of spin Hall angle by exploiting spin current fluctuation via composition control makes 3d magnets functional materials in charge-to-spin conversion for spintronic application.

Published

2022

19. Deterministic Search on Star Graphs via Quantum Walks.

Author

Qu D, Marsh S, Wang K, Xiao L, Wang J, and Xue P

Abstract

We propose a novel algorithm for quantum spatial search on a star graph using interleaved continuous-time quantum walks and marking oracle queries. Initializing the system in the star's central vertex, we determine the optimal quantum walk times to reach full overlap with the marked state using ⌈(π/4)sqrt[N]-(1/2)⌉ oracle queries, matching the well-known lower bound of Grover's search. We implement the deterministic search in a database of size seven on photonic quantum hardware, and demonstrate the effective scaling of the approach up to size 115. This is the first experimental demonstration of quantum walk-based search on the highly noise-resistant star graph, which provides new evidence for the applications of quantum walk in quantum algorithms and quantum information processing.

Published

2022

20. Efficient Simulation of Loop Quantum Gravity: A Scalable Linear-Optical Approach.

Author

Cohen L, Brady AJ, Huang Z, Liu H, Qu D, Dowling JP, and Han M

Abstract

The problem of simulating complex quantum processes on classical computers gave rise to the field of quantum simulations. Quantum simulators solve problems, such as boson sampling, where classical counterparts fail. In another field of physics, the unification of general relativity and quantum theory is one of the greatest challenges of our time. One leading approach is loop quantum gravity (LQG). Here, we connect these two fields and design a linear-optical simulator such that the evolution of the optical quantum gates simulates the spin-foam amplitudes of LQG. It has been shown that computing transition amplitudes in simple quantum field theories falls into the bounded-error quantum polynomial time class, which strongly suggests that computing transition amplitudes of LQG are classically intractable. Therefore, these amplitudes are efficiently computable with universal quantum computers, which are, alas, possibly decades away. We propose here an alternative special-purpose linear-optical quantum computer that can be implemented using current technologies. This machine is capable of efficiently computing these quantities. This work opens a new way to relate quantum gravity to quantum information and will expand our understanding of the theory.

Published

2021

21. Quantum interference in macroscopic crystals of nonmetallic Bi2Se3.

Author

Checkelsky JG, Hor YS, Liu MH, Qu DX, Cava RJ, and Ong NP

Abstract

Photoemission experiments have shown that Bi2Se3 is a topological insulator. By controlled doping, we have obtained crystals of Bi2Se3 with nonmetallic conduction. At low temperatures, we uncover a novel type of magnetofingerprint signal which involves the spin degrees of freedom. Given the mm-sized crystals, the observed amplitude is 200-500x larger than expected from universal conductance fluctuations. The results point to very long phase-breaking lengths in an unusual conductance channel in these nonmetallic samples. We discuss the nature of the in-gap conducting states and their relation to the topological surface states.

Published

2009

22. Surviving structure in colloidal suspensions squeezed from 3D to 2D.

Author

Klapp SH, Zeng Y, Qu D, and von Klitzing R

Subjects

Computer Simulation, Monte Carlo Method, Osmolar Concentration, Silicon Dioxide chemistry, Static Electricity, Models, Chemical, Suspensions chemistry

Abstract

Combining colloidal-probe experiments and computer simulations, we analyze the solvation forces F of charged silica colloids confined in films of various thicknesses h. We show that the oscillations characterizing F(h), for sufficiently large h, are determined by the dominant wavelength of the bulk radial distribution function. As a consequence, both quantities display the same power-law density dependence. This is the first direct evidence, in a system treatable both by experiment and by simulation, that the structural wavelength in bulk and confinement coincide, in agreement with predictions from density functional theory. Moreover, theoretical and experimental data are in excellent quantitative agreement.

Published

2008

23. Observation of a new type of THz resonance of surface plasmons propagating on metal-film hole arrays.

Author

Qu D and Grischkowsky D

Abstract

Highly conducting metal-film subwavelength hole arrays, lithographically fabricated on high-resistivity silicon wafers in optical contact with thick silicon plates, have been characterized by terahertz time-domain spectroscopy with subpicosecond resolution and over a frequency range from 0.5 to 3 THz with 5 GHz resolution. A well-defined ringing structure extending to more than 250 psec is observed on the trailing edge of the transmitted THz pulse. In the frequency domain this ringing structure corresponds to a new type of extremely sharp resonant line structure between the fundamental surface plasmon modes of the hole array. A simple theoretical model is presented and shows good agreement with the experimental data.

Published

2004