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507 results on '"Liu, Zhenxian"'

1. Observation of Conventional Near Room Temperature Superconductivity in Carbonaceous Sulfur Hydride

Author

Pasan, Hiranya, Snider, Elliot, Munasinghe, Sasanka, Dissanayake, Sachith E., Salke, Nilesh P., Ahart, Muhtar, Khalvashi-Sutter, Nugzari, Dasenbrock-Gammon, Nathan, McBride, Raymond, Smith, G. Alexander, Mostafaeipour, Faraz, Smith, Dean, Cortés, Sergio Villa, Xiao, Yuming, Kenney-Benson, Curtis, Park, Changyong, Prakapenka, Vitali, Chariton, Stella, Lawler, Keith V., Somayazulu, Maddury, Liu, Zhenxian, Hemley, Russell J., Salamat, Ashkan, and Dias, Ranga P.

Subjects
Condensed Matter - Superconductivity
Abstract

The phenomenon of high temperature superconductivity, approaching room temperature, has been realized in a number of hydrogen-dominant alloy systems under high pressure conditions1-12. A significant discovery in reaching room temperature superconductivity is the photo-induced reaction of sulfur, hydrogen, and carbon that initially forms of van der Waals solids at sub-megabar pressures. Carbonaceous sulfur hydride has been demonstrated to be tunable with respect to carbon content, leading to different superconducting final states with different structural symmetries. A modulated AC susceptibility technique adapted for a diamond anvil cell confirms a Tc of 260 kelvin at 133 GPa in carbonaceous sulfur hydride. Furthermore, direct synchrotron infrared reflectivity measurements on the same sample under the same conditions reveal a superconducting gap of ~85 meV at 100 K in close agreement to the expected value from Bardeen-Cooper-Schrieffer (BCS) theory13-18. Additionally, x-ray diffraction in tandem with AC magnetic susceptibility measurements above and below the superconducting transition temperature, and as a function of pressure at 107-133 GPa, reveal the Pnma structure of the material is responsible for the close to room-temperature superconductivity at these pressures.

Published
2023

4. Pressure induced collapse of magnetic order in jarosite

Author

Klein, Ryan A., Walsh, James P. S., Clarke, Samantha M., Liu, Zhenxian, Alp, E. Ercan, Bi, Wenli, Meng, Yue, Altman, Alison B., Chow, Paul, Xiao, Yuming, Norman, M. R., Rondinelli, James M., Jacobsen, Steven D., Puggioni, Danilo, and Freedman, Danna E.

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

We report a pressure-induced phase transition in the frustrated kagom\'e 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 R-3m structure to a structure with a R-3c space group. The resulting phase features a rare twisted kagom\'e lattice in which the integrity of the equilateral Fe3+ 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., Comment: Manuscript and Supplement included

Published
2020
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7. Lattice frustration in spin-orbit Mott insulator Sr3Ir2O7 at high pressure

Author

Zhang, Jianbo, Yan, Dayu, Yesudhas, Sorb, Deng, Hongshan, Xiao, Hong, Chen, Bijuan, Sereika, Raimundas, Yin, Xia, Yi, Changjiang, Shi, Youguo, Liu, Zhenxian, Pärschke, Ekaterina M., Chen, Cheng-Chien, Chang, Jun, Ding, Yang, and Mao, Ho-kwang

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

The intertwined charge, spin, orbital, and lattice degrees of freedom could endow 5d compounds with exotic properties. Current interest is focused on electromagnetic interactions in these materials, whereas the important role of lattice geometry remains to be fully recognized. For this sake, we investigate pressure-induced phase transitions in the spin-orbit Mott insulator Sr3Ir2O7 with Raman, electrical resistance, and x-ray diffraction measurements. We reveal an interesting magnetic transition coinciding with a structural transition at 14.4 GPa, but without a concurrent insulator-metal transition. The conventional correlation between magnetic and Mott insulating states is thereby absent. The observed softening of the one-magnon mode can be explained by a reduced tetragonal distortion, while the actual magnetic transition is associated with tilting of the IrO6 octahedra. This work highlights the critical role of lattice frustration in determining the high-pressure phases of Sr3Ir2O7. The ability to control electromagnetic properties via manipulating the crystal structure with pressure promises a new way to explore new quantum states in spin-orbit Mott insulators., Comment: 6 pages, 5 figures

Published
2019
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8. Nature of the Structural Symmetries Associated with Hybrid Improper Ferroelectricity in Ca3X2O7

Author

Liu, S., Zhang, H., Ghose, S., Balasubramanian, M., Liu, Zhenxian, Wang, S. G., Chen, Y-S., Gao, B., Kim, J., Cheong, S. -W., and Tyson, T. A.

Subjects
Condensed Matter - Materials Science
Abstract

In hybrid improper ferroelectric systems, polarization arises from the onset of successive nonpolar lattice modes. In this work, measurements and modeling were performed to determine the spatial symmetries of the phases involved in the transitions to these modes. Structural and optical measurements reveal that the tilt and rotation distortions of the MnO6 or TiO6 polyhedra relative to the high symmetry phases driving ferroelectricity in the hybrid improper Ca3X2O7 system (X=Mn and Ti) condense at different temperatures. The tilt angle vanishes abruptly at T$_T$ ~ 400 K for Ca3Mn2O7 (and continuously for X=Ti) and the rotation mode amplitude is suppressed at much higher temperatures T$_R$ ~1060 K. Moreover, Raman measurements in Ca3Mn2O7 under isotropic pressure reveal that the polyhedral tilts can be suppressed by very low pressures (between 1.4 and2.3 GPa) indicating their softness. These results indicate that the Ca3Mn2O7 system provides a new platform for strain engineering of ferroelectric properties in film based systems with substrate induced strain., Comment: Eight figures and one table in main text. Twenty-two figures and eleven tables in supplementary document

Published
2019
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9. Synthesis and electronic structure characterization of diamane

Author

Ke, Feng, Zhang, Lingkong, Chen, Yabin, Yin, Ketao, Wang, Chenxu, Zhu, Wanquan, Wang, Hailun, Lin, Yu, Liu, Zhenxian, Tse, John S., Wu, Guilin, Ewing, Rodney C., Mao, Wendy L., Wu, Junqiao, Mao, Ho-Kwang, and Chen, Bin

Subjects
Condensed Matter - Materials Science
Abstract

Atomically thin graphite, known as graphene, has been a marvel in material science because of its exceptional properties, novel physics and promising applications. Atomically thin diamond, called diamane, has also attracted considerable scientific interest due to its potential physical and mechanical properties. However, until now there has been no reports of successful synthesis of a free-standing pristine diamane film. Here, we report the synthesis and electronic structure characterization of diamane. Electrical measurements, x-ray diffraction and theoretical simulations reveal that trilayer and thicker graphene transform to hexagonal diamane (h-diamane) when compressed to above 20 GPa, which can be preserved down to few GPa. Raman studies indicate that the sample quenched from high pressure and high temperature also has a h-diamane structure, i.e., h-diamane is recovered back to ambient conditions. Optical absorption and band structure calculations reveal an indirect energy gap of 2.8 eV in the diamane film. Compared to gapless graphene, diamane with sizable bandgap may open up new applications of carbon semiconductors., Comment: 17 pages, 4 figures

Published
2019

10. Phase transformation of hydrous ringwoodite to the lower-mantle phases and the formation of dense hydrous silica

Author

Chen, Huawei, Leinenweber, Kurt, Prakapenka, Vitali, Kunz, Martin, Bechtel, Hans A, Liu, Zhenxian, and Shim, Sang-Heon

Subjects
Geochemistry, Geology, Resources Engineering and Extractive Metallurgy, Geochemistry & Geophysics
Abstract

To understand the effects of H2O on the mineral phases forming under the pressure-temperature conditions of the lower mantle, we have conducted laser-heated diamond-anvil cell experiments on hydrous ringwoodite (Mg2SiO4 with 1.1 wt% H2O) at pressures between 29 and 59 GPa and temperatures between 1200 and 2400 K. Our results show that hydrous ringwoodite (hRw) converts to crystalline dense hydrous silica, stishovite (Stv) or CaCl2-type SiO2 (mStv), containing 1 wt% H2O together with Brd and MgO at the pressure-temperature conditions expected for shallow lower-mantle depths between approximately 660 to 1600 km. Considering the lack of sign for melting in our experiments, our preferred interpretation of the observation is that Brd partially breaks down to dense hydrous silica and periclase (Pc), forming the phase assembly Brd + Pc + Stv. The results may provide an explanation for the enigmatic coexistence of Stv and Fp inclusions in lower-mantle diamonds.

Published
2020

11. Large bandgap of pressurized trilayer graphene

Author

Ke, Feng, Chen, Yabin, Yin, Ketao, Yan, Jiejuan, Zhang, Hengzhong, Liu, Zhenxian, Tse, John S, Wu, Junqiao, Mao, Ho-Kwang, and Chen, Bin

Subjects
Physical Sciences, Engineering, Nanotechnology, Condensed Matter Physics, graphene, two-dimensional materials, high pressure, electrical transport, bandgap opening
Abstract

Graphene-based nanodevices have been developed rapidly and are now considered a strong contender for postsilicon electronics. However, one challenge facing graphene-based transistors is opening a sizable bandgap in graphene. The largest bandgap achieved so far is several hundred meV in bilayer graphene, but this value is still far below the threshold for practical applications. Through in situ electrical measurements, we observed a semiconducting character in compressed trilayer graphene by tuning the interlayer interaction with pressure. The optical absorption measurements demonstrate that an intrinsic bandgap of 2.5 ± 0.3 eV could be achieved in such a semiconducting state, and once opened could be preserved to a few GPa. The realization of wide bandgap in compressed trilayer graphene offers opportunities in carbon-based electronic devices.

Published
2019

13. 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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14. 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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17. Pressure induced metallization with absence of structural transition in layered MoSe2

Author

Zhao, Zhao, Zhang, Haijun, Yuan, Hongtao, Wang, Shibing, Lin, Yu, Zeng, Qiaoshi, Xu, Gang, Liu, Zhenxian, Solanki, G. K., Patel, K. D., Cui, Yi, Hwang, Harold Y., and Mao, Wendy L.

Subjects
Condensed Matter - Materials Science
Abstract

Layered transition-metal dichalcogenides have emerged as exciting material systems with atomically thin geometries and unique electronic properties. Pressure is a powerful tool for continuously tuning their crystal and electronic structures away from the pristine states. Here, we systematically investigated the pressurized behavior of MoSe2 up to ~ 60 GPa using multiple experimental techniques and ab -initio calculations. MoSe2 evolves from an anisotropic two-dimensional layered network to a three-dimensional structure without a structural transition, which is a complete contrast to MoS2. The role of the chalcogenide anions in stabilizing different layered patterns is underscored by our layer sliding calculations. MoSe2 possesses highly tunable transport properties under pressure, determined by the gradual narrowing of its band-gap followed by metallization. The continuous tuning of its electronic structure and band-gap in the range of visible light to infrared suggest possible energy-variable optoelectronics applications in pressurized transition-metal dichalcogenides., Comment: Nature Communications in press

Published
2015
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18. Tetrahedrally coordinated carbonates in Earth's lower mantle

Author

Boulard, Eglantine, Pan, Ding, Galli, Giulia, Liu, Zhenxian, and Mao, Wendy

Subjects
Condensed Matter - Materials Science
Abstract

Carbonates are the main species that bring carbon deep into our planet through subduction. They are an important rock-forming mineral group, fundamentally distinct from silicates in Earth's crust in that carbon binds to three oxygen atoms, while silicon is bonded to four oxygens. Here, we present experimental evidence that under the sufficiently high pressures and high temperatures existing in the lower mantle, ferromagnesian carbonates transform to a phase with tetrahedrally coordinated carbons. Above 80 GPa, in situ synchrotron infrared experiments show the unequivocal spectroscopic signature of the high-pressure phase of (Mg,Fe)CO$_3$. Using ab-initio calculations, we assign the new IR signature to C-O bands associated with tetrahedrally coordinated carbon with asymmetric C-O bonds. Tetrahedrally coordinated carbonates are expected to exhibit substantially different reactivity than low pressure three-fold coordinated carbonates, as well as different chemical properties in the liquid state. Hence this may have significant implications on carbon reservoirs and fluxes and the global geodynamic carbon cycle.

Published
2015
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21. Nanocrystals in compression: unexpected structural phase transition and amorphization due to surface impurities

Author

Liu, Gang, Kong, Lingping, Yan, Jinyuan, Liu, Zhenxian, Zhang, Hengzhong, Lei, Pei, Xu, Tao, Mao, Ho-kwang, and Chen, Bin

Subjects
Engineering, Chemical Sciences, Physical Chemistry, Physical Sciences, Technology, Nanoscience & Nanotechnology, Chemical sciences, Physical sciences
Abstract

We report an unprecedented surface doping-driven anomaly in the compression behaviors of nanocrystals demonstrating that the change of surface chemistry can lead to an interior bulk structure change in nanoparticles. In the synchrotron-based X-ray diffraction experiments, titania nanocrystals with low concentration yttrium dopants at the surface are found to be less compressible than undoped titania nanocrystals. More surprisingly, an unexpected TiO2(ii) phase (α-PbO2 type) is induced and obvious anisotropy is observed in the compression of yttrium-doped TiO2, in sharp contrast to the compression behavior of undoped TiO2. In addition, the undoped brookite nanocrystals remain with the same structure up to 30 GPa, whereas the yttrium-doped brookite amorphizes above 20 GPa. The abnormal structural evolution observed in yttrium-doped TiO2 does not agree with the reported phase stability of nano titania polymorphs, thus suggesting that the physical properties of the interior of nanocrystals can be controlled by the surface, providing an unconventional and new degree of freedom in search for nanocrystals with novel tunable properties that can trigger applications in multiple areas of industry and provoke more related basic science research.

Published
2016

22. Bulk Signatures of Pressure-Induced Band Inversion and Topological Phase Transitions in Pb$_{1-x}$Sn$_x$Se

Author

Xi, Xiaoxiang, He, Xu-Gang, Guan, Fen, Liu, Zhenxian, Zhong, R. D., Schneeloch, J. A., Liu, T. S., Gu, G. D., Xu, D., Chen, Z., Hong, X. G., Ku, Wei, and Carr, G. L.

Subjects
Condensed Matter - Materials Science
Abstract

The characteristics of topological insulators are manifested in both their surface and bulk properties, but the latter remain to be explored. Here we report bulk signatures of pressure-induced band inversion and topological phase transitions in Pb$_{1-x}$Sn$_x$Se ($x=$0.00, 0.15, and 0.23). The results of infrared measurements as a function of pressure indicate the closing and the reopening of the band gap as well as a maximum in the free carrier spectral weight. The enhanced density of states near the band gap in the topological phase give rise to a steep interband absorption edge. The change of density of states also yields a maximum in the pressure dependence of the Fermi level. Thus our conclusive results provide a consistent picture of pressure-induced topological phase transitions and highlight the bulk origin of the novel properties in topological insulators.

Published
2014
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24. Signatures of a Pressure-Induced Topological Quantum Phase Transition in BiTeI

Author

Xi, Xiaoxiang, Ma, Chunli, Liu, Zhenxian, Chen, Zhiqiang, Ku, Wei, Berger, H., Martin, C., Tanner, D. B., and Carr, G. L.

Subjects
Condensed Matter - Materials Science
Abstract

We report the observation of two signatures of a pressure-induced topological quantum phase transition in the polar semiconductor BiTeI using x-ray powder diffraction and infrared spectroscopy. The x-ray data confirm that BiTeI remains in its ambient-pressure structure up to 8 GPa. The lattice parameter ratio c/a shows a minimum between 2.0-2.9 GPa, indicating an enhanced c-axis bonding through pz band crossing as expected during the transition. Over the same pressure range, the infrared spectra reveal a maximum in the optical spectral weight of the charge carriers, reflecting the closing and reopening of the semiconducting band gap. Both of these features are characteristics of a topological quantum phase transition, and are consistent with a recent theoretical proposal., Comment: revised final version

Published
2013
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25. Pressure-induced amorphization and polyamorphism in one-dimensional single crystal TiO2 nanomaterials

Author

Li, Quanjun, Liu, Bingbing, Wang, Lin, Li, Dongmei, Liu, Ran, Zou, Bo, Cui, Tian, Zou, Guangtian, Meng, Yue, Mao, Ho-kwang, Liu, Zhenxian, Liu, Jing, and Li, Jixue

Subjects
Condensed Matter - Materials Science, Condensed Matter - Mesoscale and Nanoscale Physics, Physics - Geophysics
Abstract

The structural phase transitions of single crystal TiO2-B nanoribbons were investigated in-situ at high-pressure using the synchrotron X-ray diffraction and the Raman scattering. Our results have shown a pressure-induced amorphization (PIA) occurred in TiO2-B nanoribbons upon compression, resulting in a high density amorphous (HDA) form related to the baddeleyite structure. Upon decompression, the HDA form transforms to a low density amorphous (LDA) form while the samples still maintain their pristine nanoribbon shape. HRTEM imaging reveals that the LDA phase has an {\alpha}-PbO2 structure with short range order. We propose a homogeneous nucleation mechanism to explain the pressure-induced amorphous phase transitions in the TiO2-B nanoribbons. Our study demonstrates for the first time that PIA and polyamorphism occurred in the one-dimensional (1D) TiO2 nanomaterials and provides a new method for preparing 1D amorphous nanomaterials from crystalline nanomaterials., Comment: 4 figures

Published
2012
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26. Ionic high-pressure form of elemental boron

Author

Oganov, Artem R., Chen, Jiuhua, Gatti, Carlo, Ma, Yanzhang, Ma, Yanming, Glass, Colin W., Liu, Zhenxian, Yu, Tony, Kurakevych, Oleksandr O., and Solozhenko, Vladimir L.

Subjects
Condensed Matter - Materials Science
Abstract

Boron is an element of fascinating chemical complexity. Controversies have shrouded this element since its discovery was announced in 1808: the new 'element' turned out to be a compound containing less than 60-70 percent of boron, and it was not until 1909 that 99-percent pure boron was obtained. And although we now know of at least 16 polymorphs, the stable phase of boron is not yet experimentally established even at ambient conditions. Boron's complexities arise from frustration: situated between metals and insulators in the periodic table, boron has only three valence electrons, which would favour metallicity, but they are sufficiently localized that insulating states emerge. However, this subtle balance between metallic and insulating states is easily shifted by pressure, temperature and impurities. Here we report the results of high-pressure experiments and ab initio evolutionary crystal structure predictions that explore the structural stability of boron under pressure and, strikingly, reveal a partially ionic high-pressure boron phase. This new phase is stable between 19 and 89 GPa, can be quenched to ambient conditions, and has a hitherto unknown structure (space group Pnnm, 28 atoms in the unit cell) consisting of icosahedral B12 clusters and B2 pairs in a NaCl-type arrangement. We find that the ionicity of the phase affects its electronic bandgap, infrared adsorption and dielectric constants, and that it arises from the different electronic properties of the B2 pairs and B12 clusters and the resultant charge transfer between them., Comment: Published in Nature 453, 863-867 (2009)

Published
2009
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27. New high-pressure form of boron is significantly ionic

Author

Oganov, Artem R., Chen, Jiuhua, Gatti, Carlo, Ma, Yanzhang, Ma, Yanming, Glass, Colin W., Liu, Zhenxian, Yu, Tony, Kurakevych, Oleksandr O., and Solozhenko, Vladimir L.

Subjects
Condensed Matter - Materials Science
Abstract

The comment of Dubrovinskaia et al. is scientifically flawed. The high-pressure form of boron, discovered by Oganov et al., is indeed new and its bonding has a significant ionic character, as demonstrated in Ref. 1., Comment: This manuscript was submitted to Nature as Reply to 'Brief Communication Arising' by Dubrovinskaia et al. (arXiv:0907.1900) and caused the rejection of the latter with publication of Addendum by Oganov et al. (Nature 460, 292 (2009))

Published
2009

32. Pressure–Temperature–Magnetic Field Phase Diagram of Multiferroic (NH4)2FeCl5·H2O

Author

Clune, Amanda J., Harms, Nathan C., Smith, Kevin A., Tian, Wei, Liu, Zhenxian, and Musfeldt, Janice L.

Abstract

We combined synchrotron-based infrared absorbance and Raman scattering spectroscopies with diamond anvil cell techniques and a symmetry analysis to explore the properties of multiferroic (NH4)2FeCl5·H2O under extreme pressure–temperature conditions. Compression-induced splitting of the Fe–Cl stretching, Cl–Fe–Cl and Cl–Fe–O bending, and NH4+librational modes defines two structural phase transitions, and a group–subgroup analysis reveals space group sequences that vary depending upon proximity to the unexpectedly wide order–disorder transition. We bring these findings together with prior high-field work to develop the pressure–temperature–magnetic field phase diagram uncovering competing polar, chiral, and magnetic phases in this system.

Published
2024
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35. Effects of Hydrogen Addition, Oxygen Level, and Strain Rate on Combustion Characteristics of CH4/H2 in Staged MILD Combustion.

Author

Zhang, Yanfei, Liu, Dianlin, Huang, Mingming, Liu, Zhenxian, Li, Qin, Zhang, Haipeng, Hao, Qing, Yu, Zewen, and Sha, Haoxi

Subjects
STRAIN rate, COMBUSTION, HYDROGEN, GAS turbines, WORKING gases, OXYGEN, HYDROGEN as fuel
Abstract

In this article, the effects of hydrogenation amount (0–80%), oxygen content (14–18%), and strain rate (10–1000 s−1) on the emission characteristics of NO and CO in moderate or intense low‐oxygen dilution (MILD) fractional combustion are studied under the actual working conditions of gas turbine (T = 723 K, P = 16.5 atm). The pathway of NO and CO production and the reaction with the greatest influence on their emissions are analyzed. In the findings, it is indicated that NO emissions are suppressed at lower hydrogen levels, while the addition of hydrogen leads to a decrease in CO emissions. Specifically, the key reaction for NO formation is H + NO + M = HNO + M, whereas CO emissions are primarily controlled by the direct reaction OH + CO = H + CO2. Furthermore, the reduction of oxygen levels effectively suppresses NO and CO emissions during MILD combustion. The variation in oxygen level exerts the greatest influence on the reaction rate of the NNH pathway. High concentrations of O2 are identified as the primary cause of elevated CO levels in MILD combustion. Finally, elevating the strain rate in MILD combustion demonstrates a mitigating effect on NO and CO emissions. [ABSTRACT FROM AUTHOR]

Published
2024
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36. X-ray Diffraction Reveals Two Structural Transitions in Szomolnokite

Author

Pardo, Olivia S., Dobrosavljevic, Vasilije V., Perez, Tyler, Sturhahn, Wolfgang, Liu, Zhenxian, Rossman, George R., Jackson, Jennifer M., Pardo, Olivia S., Dobrosavljevic, Vasilije V., Perez, Tyler, Sturhahn, Wolfgang, Liu, Zhenxian, Rossman, George R., and Jackson, Jennifer M.

Abstract

Hydrated sulfates have been identified and studied in a wide variety of environments on Earth, Mars, and the icy satellites of the solar system. The subsurface presence of hydrous sulfur-bearing phases to any extent necessitates a better understanding of their thermodynamic and elastic properties at pressure. End-member experimental and computational data are lacking and are needed to accurately model hydrous, sulfur-bearing planetary interiors. In this work, high-pressure X-ray diffraction (XRD) and synchrotron Fourier-transform infrared (FTIR) measurements were conducted on szomolnokite (FeSO₄·H₂O) up to ~83 and 24 GPa, respectively. This study finds a monoclinic-triclinic (C2/c to P1̅) structural phase transition occurring in szomolnokite between 5.0(1) and 6.6(1) GPa and a previously unknown triclinic-monoclinic (P1̅ to P2₁) structural transition occurring between 12.7(3) and 16.8(3) GPa. The high-pressure transition was identified by the appearance of distinct reflections in the XRD patterns that cannot be attributed to a second phase related to the dissociation of the P1̅ phase, and it is further characterized by increased H₂O bonding within the structure. We fit third-order Birch-Murnaghan equations of state for each of the three phases identified in our data and refit published data to compare the elastic parameters of szomolnokite, kieserite (MgSO4·H2O), and blödite (Na₂Mg(SO₄)₂·4H₂O). At ambient pressure, szomolnokite is less compressible than blödite and more than kieserite, but by 7 GPa both szomolnokite and kieserite have approximately the same bulk modulus, while blödite’s remains lower than both phases up to 20 GPa. These results indicate the stability of szomolnokite’s high-pressure monoclinic phase and the retention of water within the structure up to pressures found in planetary deep interiors.

Published
2023

48. Superconductivity Induced by Lifshitz Transition in Pristine SnS2 under High Pressure

Author

Feng, Jiajia, primary, Li, Cong, additional, Deng, Wen, additional, Lin, Bencheng, additional, Liu, Wenhui, additional, Susilo, Resta A., additional, Dong, Hongliang, additional, Chen, Zhiqiang, additional, Zhou, Nan, additional, Yi, Xiaolei, additional, Xing, Xiangzhuo, additional, Ke, Feng, additional, Liu, Zhenxian, additional, Sheng, Hongwei, additional, Shi, Zhixiang, additional, and Chen, Bin, additional

Published
2022
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