Masaaki Yamakata scite author profile

First-order structural phase transitions are common in crystalline solids, whereas first-order liquid-liquid phase transitions (that is, transitions between two distinct liquid forms with different density and entropy) are exceedingly rare in pure substances. But recent theoretical and experimental studies have shown evidence for such a transition in several materials, including supercooled water and liquid carbon. Here we report an in situ X-ray diffraction observation of a liquid-liquid transition in phosphorus, involving an abrupt, pressure-induced structural change between two distinct liquid forms. In addition to a known form of liquid phosphorus--a molecular liquid comprising tetrahedral P4 molecules--we have found a polymeric form at pressures above 1 GPa. Changing the pressure results in a reversible transformation from the low-pressure molecular form into the high-pressure polymeric form. The transformation is sharp and rapid, occurring within a few minutes over a pressure range of less than 0.02 GPa. During the transformation, the two forms of liquid coexist. These features are strongly suggestive of a first-order liquid-liquid phase transition.

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The large Debye–Scherrer camera installed at SPring-8 BL02B2 for charge density studies

Nishibori¹,

Takata²,

Kato³

et al. 2001

Nuclear Instruments and Methods in Physics Research Section A:

453

270

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High-pressurein situx-ray-diffraction study of the phase transformation from graphite to hexagonal diamond at room temperature

et al. 1992

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Macroscopic Separation of Dense Fluid Phase and Liquid Phase of Phosphorus

Katayama

Inamura

Mizutani

et al. 2004

Science

171

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Structural transformation between a dense molecular fluid and a polymeric liquid of phosphorus that occurred at about 1 gigapascal and 1000 degrees C was investigated by in situ x-ray radiography. When the low-pressure fluid was compressed, dark and round objects appeared in the radiograph. X-ray diffraction measurements confirmed that these objects were the highpressure liquid. The drops grew and eventually filled the sample space. Decompressing caused the reverse process. The macroscopic phase separation supported the existence of a first-order phase transition between two stable disordered phases besides the liquid-gas transition. X-ray absorption measurements revealed that the change in density at the transition corresponds to about 40% of the density of the high-pressure liquid.

show abstract

The large Debye–Scherrer camera installed at SPring-8 BL02B2 for charge density studies

Nishibori

Takata

Kato

et al. 2001

Journal of Physics and Chemistry of Solids

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