Shuqing Jiang scite author profile

The recent discovery of H 3 S and LaH 10 superconductors with record high superconducting transition temperatures T c at high pressure has fueled the search for room-temperature superconductivity in the compressed superhydrides. Here we introduce a new class of high T c hydrides with a novel structure and unusual properties. We predict the existence of an unprecedented hexagonal HfH 10 , with remarkably high value of T c (around 213-234 K) at 250 GPa. As concerns the novel structure, the H ions in HfH 10 are arranged in clusters to form a planar "pentagraphenelike" sublattice. The layered arrangement of these planar units is entirely different from the covalent sixfold cubic structure in H 3 S and clathratelike structure in LaH 10 . The Hf atom acts as a precompressor and electron donor to the hydrogen sublattice. This pentagraphenelike H 10 structure is also found in ZrH 10 , ScH 10 , and LuH 10 at high pressure, each material showing a high T c ranging from 134 to 220 K. Our study of dense superhydrides with pentagraphenelike layered structures opens the door to the exploration of a new class of high T c superconductors.

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Effects of amines on particle growth observed in new particle formation events

Tao

Jiang

et al. 2016

JGR Atmospheres

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Particle size distributions in the range of 0.01–10 µm were measured in urban Shanghai in the summer of 2013 using a Wide‐range Particle Spectrometer (WPS). Size‐segregated aerosol samples were collected concurrently using a Micro‐Orifice Uniform Deposit Impactor (MOUDI), which aided our in‐depth understanding of the new particle formation (NPF) mechanism in the polluted Yangtze River Delta area. During the observations, 16 NPF events occurred at high temperatures (~34.7°C) on clear and sunny days. In the ammonium‐poor PM1.0 (particulate matter less than 1.0 µm), sulfate and ammonium accounted for 92% of the total water‐soluble inorganic species. Six aminiums were detected in these MOUDI samples, among which the group of diethylaminium and trimethylaminium (DEAH+ + TMAH+) was the most abundant. The very high level of aminiums (average concentration up to 86.4 ng m−3 in PM1.8), together with highly acidic aerosols, provided insight into the frequent NPF events. The high mass ratio of total aminiums to NH4+ (>0.2 for PM0.056) further highlighted the important role of amines in promoting NPF. The concentration of DEAH+ + TMAH+ in new particles below 180 nm was strongly correlated with aerosol phase acidity, indicating that acid‐base reactions dominated the aminium formation in NPF events. The unexpected enhancement of DEAH+ + TMAH+ on a nonevent day was attributed to the transportation of an SO2 plume. Our results reveal that the heterogeneous uptake of amines is dominated by the acid‐base reaction mechanism, which can effectively contribute to particle growth in NPF events.

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Large Volume Collapse during Pressure-Induced Phase Transition in Lithium Amide

Huang

et al. 2012

J. Phys. Chem. C

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The structural studies of lithium amide (LiNH2) have been performed by synchrotron X-ray diffraction measurements and ab initio density functional theoretical calculations up to 28.0 GPa. It is revealed that LiNH2 undergoes a reversible pressure-induced phase transitions from tetragonal phase (I-4) into the monoclinic phase (P21), which starts from about 10.3 GPa and completes at about 15.0 GPa. This transition is accompanied by about 11% large volume collapse, and this volume collapse is much larger than other complex ternary hydrides. The experimental pressure–volume data for the two phases of LiNH2 are fitted by third-order Birch–Murnaghan equation of state, yielding B 0 of 37.2 (1.7) GPa for the tetragonal phase and 7.6 (4.9) GPa for the monoclinic phase with the pressure derivatives at 3.5. We also have calculated the total and partial density of states of the two phases in order to explore the mechanism of the volume reduction.

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Synthesis and properties of selenium trihydride at high pressures

Zhang

et al. 2018

Phys. Rev. B

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Shuqing Jiang

Uranium polyhydrides at moderate pressures: Prediction, synthesis, and expected superconductivity

Hydrogen Pentagraphenelike Structure Stabilized by Hafnium: A High-Temperature Conventional Superconductor

Effects of amines on particle growth observed in new particle formation events

Large Volume Collapse during Pressure-Induced Phase Transition in Lithium Amide

Synthesis and properties of selenium trihydride at high pressures

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