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1. Pressure-Induced Superconductivity at 18.2 K in CuIr2S4

Author

Chen, Bijuan, Gu, Yuhao, Wang, Dong, Shao, Dexi, Deng, Wen, Han, Xin, Jin, Meiling, Zeng, Yu, Ishii, Hirofumi, Liao, Yen-Fa, Zhang, Dongzhou, Zhang, Jianbo, Long, Youwen, Zhu, Jinlong, Yang, Liuxiang, Xiao, Hong, Nei, Jia-cai, Shi, Youguo, Jin, Changqing, Hu, Jiangping, Mao, Ho-kwang, and Ding, Yang

Subjects
Condensed Matter - Superconductivity
Abstract

Attaining superconducting critical temperatures (Tc) beyond the limit around 14 K observed thus far in spinel compounds AB2X4 (A, B = transition metals, X = O/chalcogen) could elucidate interaction intricacies and inform materials design. This work spotlights CuIr2S4, which exhibits a distinct metal-insulator transition below 230 K, as an unconventional candidate for activation under high pressure. Through transport, diffraction, and spectroscopy experiments conducted at pressures up to 224 GPa, we unveil pressure-tuning that suppressed CuIr2S4's transition, yielding two superconducting phases with an un-precedented Tc for spinels. Initially, 3.8 K onset rose monotonically, reaching 18.2 K at 133 GPa. Unexpectedly, a distinct phase with Tc = 2.2 K distinctly emerged at higher pressures, intimating unconventional couplings. Our findings suggest that both geometric frustration and electron-electron interactions play crucial roles in the superconductivity observed in CuIr2S4. The findings stretch perceived temperature limits in spinels and provide structure-property insights to guide the optimiza-tion of quantum materials interactions for tailored targeted functionalities., Comment: 12 pages, 7 gifures

Published
2024

8. Silvanite AuAgTe$_4$: a rare case of gold superconducting material

Author

Amiel, Yehezkel, Kafle, Gyanu P., Komleva, Evgenia V., Greenberg, Eran, Ponosov, Yuri S., Chariton, Stella, Lavina, Barbara, Zhang, Dongzhou, Palevski, Alexander, Ushakov, Alexey V., Mori, Hitoshi, Khomskii, Daniel I., Mazin, Igor I., Streltsov, Sergey V., Margine, Elena R., and Rozenberg, Gregory Kh.

Subjects
Condensed Matter - Strongly Correlated Electrons, Condensed Matter - Superconductivity
Abstract

Gold is one of the most inert metals, forming very few compounds, some with rather interesting properties, and only two of them currently known to be superconducting under certain conditions (AuTe$_2$ and SrAuSi$_3$). Compounds of another noble element, Ag, are also relatively rare, and very few of them are superconducting. Finding new superconducting materials containing gold (and silver) is a challenge - especially having in mind that the best high-$T_c$ superconductors at normal conditions are based upon their rather close ''relative'', Cu. Here we report combined X-ray diffraction, Raman, and resistivity measurements, as well as first-principles calculations, to explore the effect of hydrostatic pressure on the properties of the sylvanite mineral, AuAgTe$_4$. Our experimental results, supported by density functional theory, reveal a structural phase transition at $\sim$5 GPa from a monoclinic $P2/c$ to $P2/m$ phase, resulting in almost identical coordinations of Au and Ag ions, with rather uniform interatomic distances. Further, resistivity measurements show the onset of superconductivity at $\sim$1.5 GPa in the $P2/c$ phase, followed by a linear increase of $T_c$ up to the phase transition, with a maximum in the $P2/m$ phase, and a gradual decrease afterwards. Our calculations indicate phonon-mediated superconductivity, with the electron-phonon coupling coming predominantly from the low-energy phonon modes. Thus, along with the discovery of a new superconducting compound of gold/silver, our results advance understanding of the mechanism of the superconductivity in Au-containing compounds, which may pave the way to the discovery of novel ones.

Published
2023

10. Pressure-Induced Insulator-to-Metal Transition in van der Waals compound CoPS$_3$

Author

Matsuoka, Takahiro, Rao, Rahul, Susner, Michael A., Conner, Benjamin S., Zhang, Dongzhou, and Mandrus, David

Subjects
Condensed Matter - Strongly Correlated Electrons, Condensed Matter - Materials Science
Abstract

We have studied the insulator-to-metal transition and crystal structure evolution under high pressure in the van der Waals compound CoPS$_3$ through $\textit{in-situ}$ electrical resistance, Hall resistance, magnetoresistance, X-ray diffraction, and Raman scattering measurements. CoPS$_3$ exhibits a $C2/m$ $\rightarrow$ $P\overline{3}$ structural transformation at 7 GPa accompanied by a 2.9$\%$ reduction in the volume per formula unit. Concomitantly, the electrical resistance decreases significantly, and CoPS$_3$ becomes metallic. This metallic CoPS$_3$ is a hole-dominant conductor with multiple conduction bands. The linear magnetoresistance and the small volume collapse at the metallization suggest the incomplete high-spin $\rightarrow$ low-spin transition in the metallic phase. Thus, the metallic CoPS$_3$ possibly possesses an inhomogeneous magnetic moment distribution and short-range magnetic ordering. This report summarizes the comprehensive phase diagram of $M$PS$_3$ ($M$ = V, Mn, Fe, Co, Ni, and Cd) that metalize under pressures., Comment: 14 pages, 6 figures, 1 table

Published
2022
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12. Pressure-induced charge orders and their coupling to magnetism in hexagonal multiferroic LuFe2O4

Author

Liu, Fengliang, Hao, Yiqing, Ni, Jinyang, Zhao, Yongsheng, Zhang, Dongzhou, Fabbris, Gilberto, Haske, Daniel, Cheng, Shaobo, Xu, Xiaoshan, Yin, Lifeng, Xiang, Hongjun, Zhao, Jun, Lü, Xujie, Wang, Wenbin, Shen, Jian, and Yang, Wenge

Subjects
Condensed Matter - Materials Science, Condensed Matter - Strongly Correlated Electrons
Abstract

Hexagonal LuFe2O4 is a promising charge-order (CO) driven multiferroic material with high charge and spin ordering temperatures. The coexisting charge and spin orders on Fe3+/Fe2+ sites result in novel magnetoelectric behaviors, but the coupling mechanism between the charge and spin orders remains elusive. Here, by tuning external pressure, we reveal three correlated spin-charge ordered phases in LuFe2O4: i) a centrosymmetric incommensurate three-dimensional CO with ferrimagnetism, ii) a non-centrosymmetric incommensurate quasi-two-dimensional CO with ferrimagnetism, and iii) a centrosymmetric commensurate CO with antiferromagnetism. Experimental in-situ single-crystal X-ray diffraction and X-ray magnetic circular dichroism measurements combined with density functional theory calculations suggest that the charge density redistribution caused by pressure-induced compression in the frustrated double-layer [Fe2O4] cluster is responsible for the correlated spin-charge phase transitions. The pressure-enhanced effective Coulomb interactions among Fe-Fe bonds drive the frustrated (1/3, 1/3) CO to a less frustrated (1/4, 1/4) CO, which induces the ferrimagnetic to antiferromagnetic transition. Our results not only elucidate the coupling mechanism among charge, spin and lattice degrees of freedom in LuFe2O4 but also provide a new way to tune the spin-charge orders in a highly controlled manner.

Published
2021

13. Lonsdaleite: The diamond with optimized bond lengths and enhanced hardness

Author

Yang, Liuxiang, Lau, Kah Chun, Zeng, Zhidan, Zhang, Dongzhou, Tang, Hu, Yan, Bingmin, Gou, Huiyang, Yang, Yanping, Xiao, Yuming, Luo, Duan, Srinivasan, Srilok, Sankaranarayanan, Subramanian, Yang, Wenge, Wen, Jianguo, and Mao, Ho-kwang

Subjects
Condensed Matter - Materials Science
Abstract

Diamond is known as the hardest substance due to its ultra-strong tetrahedral sp3 carbon bonding framework. The only weak link is its cubic cleavage planes between (111) buckled honeycomb layers. Compressing graphite single crystals and heating to moderate temperatures, we synthesized a bulk, pure, hexagonal diamond (lonsdaleite) with distorted carbon tetrahedrons that shorten the bond between its hexagonal (001) buckled honeycomb layers, thus strengthening their linkage. We observed direct transformation of graphite (100) to lonsdaleite (002) and graphite (002) to lonsdaleite (100). We find the bulk lonsdaleite has superior mechanical properties of Vicker hardnesses HV = 164+/-11 GPa and 124+/-13 GPa, measured on the surface corresponding to the original graphite (001) and (100) surfaces, respectively. Properties of lonsdaleite as the supreme material can be further enhanced by purifying the starting material graphite carbon and fine-tuning the high pressure-temperature synthesis conditions.

Published
2021

15. Pressure-induced Topological and Structural Phase Transitions in an Antiferromagnetic Topological Insulator

Author

Pei, Cuiying, Xia, Yunyouyou, Wu, Jiazhen, Zhao, Yi, Gao, Lingling, Ying, Tianping, Gao, Bo, Li, Nana, Yang, Wenge, Zhang, Dongzhou, Gou, Huiyang, Chen, Yulin, Hosono, Hideo, Li, Gang, and Qi, Yanpeng

Subjects
Condensed Matter - Superconductivity, Condensed Matter - Materials Science
Abstract

Recently, natural van der Waals heterostructures of (MnBi2Te4)m(Bi2Te3)n have been theoretically predicted and experimentally shown to host tunable magnetic properties and topologically nontrivial surface states. In this work, we systematically investigate both the structural and electronic responses of MnBi2Te4 and MnBi4Te7 to external pressure. In addition to the suppression of antiferromagnetic order, MnBi2Te4 is found to undergo a metal-semiconductor-metal transition upon compression. The resistivity of MnBi4Te7 changes dramatically under high pressure and a non-monotonic evolution of \r{ho}(T) is observed. The nontrivial topology is proved to persists before the structural phase transition observed in the high-pressure regime. We find that the bulk and surface states respond differently to pressure, which is consistent with the non-monotonic change of the resistivity. Interestingly, a pressure-induced amorphous state is observed in MnBi2Te4, while two high pressure phase transitions are revealed in MnBi4Te7. Our combined theoretical and experimental research establishes MnBi2Te4 and MnBi4Te7 as highly tunable magnetic topological insulators, in which phase transitions and new ground states emerge upon compression., Comment: 13 pages, 7 figures

Published
2020
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20. Superconducting and magnetic phase diagram of RbEuFe4As4 and CsEuFe4As4 at high pressure

Author

Jackson, Daniel E., VanGennep, Derrick, Bi, Wenli, Zhang, Dongzhou, Materne, Philipp, Liu, Yi, Cao, Guang-Han, Weir, Samuel T., Vohra, Yogesh K., and Hamlin, James J.

Subjects
Condensed Matter - Superconductivity, Condensed Matter - Strongly Correlated Electrons
Abstract

The recently discovered (Rb,Cs)EuFe4As4 compounds exhibit an unusual combination of superconductivity (Tc = 35 K) and ferromagnetism (Tm = 15 K). We have performed a series of x-ray diffraction, ac magnetic susceptibility, dc magnetization, and electrical resistivity measurements on both RbEuFe4As4 and CsEuFe4As4 to pressures as high as 30 GPa. We find that the superconductivity onset is suppressed monotonically by pressure while the magnetic transition is enhanced at initial rates of dTm/dP = 1.7 K/GPa and 1.5 K/GPa for RbEuFe4As4 and CsEuFe4As4, respectively. Near 7 GPa, Tc onset and Tm become comparable. At higher pressures, signatures of bulk superconductivity gradually disappear. Room temperature x-ray diffraction measurements suggest the onset of a transition from tetragonal (T) to a half collapsed-tetragonal (hcT) phase at 10 GPa (RbEuFe4As4) and 12 GPa (CsEuFe4As4). The ability to tune Tc and Tm into coincidence with relatively modest pressures highlights (Rb,Cs)EuFe4As4 compounds as ideal systems to study the interplay of superconductivity and ferromagnetism., Comment: 10 pages, 8 figures, updated references

Published
2018
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21. Suppression of the magnetic order in CeFeAsO: non-equivalence of hydrostatic and chemical pressure

Author

Materne, Philipp, Bi, Wenli, Alp, Esen Ercan, Zhao, Jiyong, Hu, Michael Yu, Jesche, Anton, Geibel, Christoph, Kappenberger, Rhea, Aswartham, Saicharan, Wurmehl, Sabine, Büchner, Bernd, Zhang, Dongzhou, Goltz, Til, Spehling, Johannes, and Klauss, Hans-Henning

Subjects
Condensed Matter - Superconductivity
Abstract

We present a detailed investigation of the electronic properties of CeFeAsO under chemical (As by P substitution) and hydrostatic pressure by means of in-house and synchrotron M\"ossbauer spectroscopy. The Fe magnetism is suppressed due to both pressures and no magnetic order was observed above a P-substitution level of 40% or 5.2 GPa hydrostatic pressure. We compared both pressures and found that the isovalent As by P substitution change the crystallographic and electronic properties differently than hydrostatic pressure., Comment: supplement is included in the pdf file

Published
2018
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22. Pressure-Induced Phase Transitions of Natural Brookite

Author

Liu, Weixin, Chen, Jian, Zhang, Xiaoliang, Yan, Jinyuan, Hou, Mingqiang, Kunz, Martin, Zhang, Dongzhou, and Zhang, Hengzhong

Abstract

The structures and stabilities of the high-pressure phases of titania (TiO2) are of great interest in the earth sciences, as these phases are the accessible analogs of component minerals in the earth's mantle. Brookite is a natural titania mineral, whose bulk phase is hard to synthesize in the laboratory, and its phase behavior at very high pressure remains unknown. Thus, in this work, using phase-pure natural brookite as the sample, we studied the phase transition of bulk brookite under compression up to ∼60 GPa in three different pressure transmitting media. Results show that, at room temperature and in near hydrostatic conditions, brookite undergoes a series of transitions, i.e., brookite (∼0-12 GPa) → TiO2-II and minor rutile (∼1-21 GPa) → baddeleyite (∼12-60 GPa) → TiO2-OI (∼33-60 GPa). Taking into account that all transitions occur at finite rates and that solidification of a pressure medium can influence transition kinetics, we show that the observed transition sequence is consistent with the expected high-pressure phase stability of TiO2 calculated from density functional theory. The knowledge obtained from this work may be used to infer the geological fate of brookite in nature.

Published
2019

25. Simultaneous band gap narrowing and carrier lifetime prolongation of organic-inorganic trihalide perovskites

Author

Kong, Lingping, Liu, Gang, Gong, Jue, Hu, Qingyang, Schaller, Richard D., Dera, Przemyslaw, Zhang, Dongzhou, Liu, Zhenxian, Yang, Wenge, Zhu, Kai, Tang, Yuzhao, Wang, Chuanyi, Wei, Su-Huai, Xu, Tao, and Mao, Ho-kwang

Subjects
Condensed Matter - Materials Science, Physics - Optics
Abstract

The organic-inorganic hybrid lead trihalide perovskites have been emerging as the most attractive photovoltaic material. As regulated by Shockley-Queisser theory, a formidable materials science challenge for the next level improvement requires further band gap narrowing for broader absorption in solar spectrum, while retaining or even synergistically prolonging the carrier lifetime, a critical factor responsible for attaining the near-band gap photovoltage. Herein, by applying controllable hydrostatic pressure we have achieved unprecedented simultaneous enhancement in both band gap narrowing and carrier lifetime prolongation (up to 70~100% increase) under mild pressures at ~0.3 GPa. The pressure-induced modulation on pure hybrid perovskites without introducing any adverse chemical or thermal effect clearly demonstrates the importance of band edges on the photon-electron interaction and maps a pioneering route towards a further boost in their photovoltaic performance., Comment: 23 pages, 4 figures

Published
2016
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29. Structure and equation of state of Ti-bearing davemaoite: New insights into the chemical heterogeneity in the lower mantle.

Author

Chao, Keng-Hsien, Berrada, Meryem, Wang, Siheng, Peckenpaugh, Juliana, Zhang, Dongzhou, Chariton, Stella, Prakapenka, Vitali, and Chen, Bin

Subjects
SLABS (Structural geology), EARTH'S mantle, CORE-mantle boundary, FRICTION velocity, PEROVSKITE
Abstract

Davemaoite (CaSiO3 perovskite) is considered the third most abundant phase in the pyrolytic lower mantle and the second most abundant phase in the subducted mid-ocean ridge basalt (MORB). During the partial melting of the pyrolytic upper mantle, incompatible titanium (Ti) becomes enriched in the basaltic magma, forming Ti-rich MORB. Davemaoite is considered an important Ti-bearing mineral in subducted slabs by forming a Ca(Si,Ti)O3 solid solution. However, the crystal structure and compressibility of Ca(Si,Ti)O3 perovskite solid solution at relevant pressure and temperature conditions had not been systematically investigated. In this study, we investigated the structure and equations of state of Ca(Si0.83Ti0.17)O3 and Ca(Si0.75Ti0.25)O3 perovskites at room temperature up to 82 and 64 GPa, respectively, by synchrotron X-ray diffraction (XRD). We found that both Ca(Si0.83Ti0.17)O3 and Ca(Si0.75Ti0.25)O3 perovskites have a tetragonal structure up to the maximum pressures investigated. Based on the observed data and compared to pure CaSiO3 davemaoite, both Ca(Si0.83Ti0.17)O3 and Ca(Si0.75Ti0.25)O3 perovskites are expected to be less dense up to the core-mantle boundary (CMB), and specifically ~1–2% less dense than CaSiO3 davemaoite in the pressure range of the transition zone (15–25 GPa). Our results suggest that the presence of Ti-bearing davemaoite phases may result in a reduction in the average density of the subducting slabs, which in turn promotes their stagnation in the lower mantle. The presence of low-density Ti-bearing davemaoite phases and subduction of MORB in the lower mantle may also explain the seismic heterogeneity in the lower mantle, such as large low shear velocity provinces (LLSVPs). [ABSTRACT FROM AUTHOR]

Published
2024
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30. Phase Transitions and Thermal Equation of State of Fe‐9wt.%Si Applied to the Moon and Mercury.

Author

Berrada, Meryem, Chen, Bin, Chao, Keng‐Hsien, Peckenpaugh, Juliana, Wang, Siheng, Zhang, Dongzhou, Nguyen, Phuong, and Li, Jie

Subjects
PHASE diagrams, EQUATIONS of state, ELECTRICAL resistivity, PHASE transitions, CORE materials, IRON alloys
Abstract

Accurate knowledge of the phase transitions and thermoelastic properties of candidate iron alloys, such as Fe‐Si alloys, is essential for understanding the nature and dynamics of planetary cores. The phase diagrams of some Fe‐Si alloys between 1 atm and 16 GPa have been back‐extrapolated from higher pressures, but the resulting phase diagram of Fe83.6Si16.4 (9 wt.% Si) is inconsistent with temperature‐induced changes in its electrical resistivity between 6 and 8 GPa. This study reports in situ synchrotron X‐ray diffraction (XRD) measurements on pre‐melted and powder Fe83.6Si16.4 samples from ambient conditions to 60 GPa and 900 K using an externally heated diamond‐anvil cell. Upon compression at 300 K, the bcc phase persisted up to ∼38 GPa. The hcp phase appeared near 8 GPa in the pre‐melted sample, and near 17 GPa in the powder sample. The appearance of the hcp phase in the pre‐melted sample reconciles the reported changes in electrical resistivity of a similar sample, thus resolving the low‐pressure region of the phase diagram. The resulting high‐temperature Birch‐Murnaghan equation of state (EoS) and thermal EoS based on the Mie‐Gruneisen‐Debye model of the bcc and hcp structures are consistent with, and complement the literature data at higher pressures. The calculated densities based on the thermal EoS of Fe‐9wt.%Si indicate that both bcc and hcp phases agree with the reported core density estimates for the Moon and Mercury. Plain Language Summary: The compositions of the interiors of planetary bodies such as the Moon and Mercury can be inferred by examining how core analogue materials (e.g., Fe‐Si alloys) behave at high pressures and temperatures. However, phase transitions of Fe‐Si alloys under conditions relevant to the Moon and Mercury have only been inferred from the extrapolations of data acquired at higher pressures. Additionally, electrical resistivity measurements have suggested that Fe‐Si alloy containing 9 wt.% Si undergoes pressure‐induced changes that are not well understood. To clarify these ambiguities, we acquired XRD patterns of Fe‐9wt.%Si up to 60 GPa and 900 K using an externally heated diamond‐anvil cell. The results show that Fe‐9wt.%Si can exist in two different crystal structures, body‐centered cubic and hexagonal close‐packed, depending on the pressure‐temperature conditions. The transition between these structures occurs at different pressures for the pre‐melted and powder samples. By modeling how the volume of the sample changes with pressure and temperature, we found that the densities of the Moon's and Mercury's cores align closely with existing models, implying a substantial presence of Fe‐9wt.%Si. Key Points: New constraints on the phase diagram of iron with 9 weight percent silicon between 1 bar and 16 GPa are establishedThermal equations of state of body‐centered‐cubic and hexagonal‐closed‐packed Fe‐9wt.%Si are established up to 60 GPa and 900 KThe calculated core densities of the Moon and Mercury are consistent with previous estimates [ABSTRACT FROM AUTHOR]

Published
2024
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34. High-Pressure Polymorphism in Silver Ferrite Delafossite, AgFeO2

Author

Manganaro, Nicholas S., primary, Ambos, Scott D., additional, DeCapua, Matthew, additional, Thiel, Scott D., additional, Mitchell, Wyatt E., additional, Liu, Zhenxian, additional, Zhang, Dongzhou, additional, Nguyen, Phuong Q. H., additional, Lavina, Barbara, additional, Alp, Esen Ercan, additional, Yan, Jun, additional, and Walsh, James P. S., additional

Published
2024
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45. Pressure induced structural and electronic band transition in CsPbBr3.

Author

Zhang, Dongzhou, Mandal, Sagarmoy, Chung, Duck Young, Xu, Jingui, Shan, Nannan, Kanatzidis, Mercouri G., and Chen, Ming

Subjects
ELECTRONIC band structure, BAND gaps, ELECTRONIC structure, PHASE transitions, CRYSTAL structure
Abstract

Cesium lead bromide (CsPbBr3) is a prominent halide perovskite with extensive optoelectronic applications. In this study, we report the pressure modulation of CsPbBr3's crystal structure and electronic properties at room temperature up to 5 GPa. We have observed a crystal structure transition from the orthorhombic Pnma space group to a new monoclinic phase in the space group P21/c at 2.08 GPa. The structure is associated with ~8% of density jump across the transition boundary. DFT calculations have suggested that the structure transition leads to a change in the electronic band structure, and there is an emergent indirect bandgap at the Pnma-P21/c phase transition boundary at 2.08 GPa. Across the transition boundary, the electronic band gap of CsPbBr3 increased from 2.07 eV to 2.38 eV, which explains its pressure-induced color change. Our study demonstrates the importance of using in-situ crystal structure in the electronic band structure calculations in halide perovskites. CsPbBr3 is a characteristic halide perovskite with extensive optoelectronic application potential. Here, the authors report the pressure modulation of the crystal structure and electronic properties of CsPbBr3 at room temperature and pressures up to 5 GPa. [ABSTRACT FROM AUTHOR]

Published
2024
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49. Non-Newtonian Dynamics in Water-in-Salt Electrolytes

Author

Yamaguchi, Tsuyoshi, primary, Dukhin, Andrei, additional, Ryu, Young-Jay, additional, Zhang, Dongzhou, additional, Borodin, Oleg, additional, González, Miguel A., additional, Yamamuro, Osamu, additional, Price, David L., additional, and Saboungi, Marie-Louise, additional

Published
2023
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