Liquids with High Compressibility

Beibei Lai; Siyuan Liu; John Cahir; Yueting Sun; Haixia Yin; Tristan Youngs; Jin-Chong Tan; Sergio F. Fonrouge; Mario G. Del Pópolo; José L. Borioni; Deborah E. Crawford; Francesca M. Alexander; Chunchun Li; Steven E. J. Bell; Barry Murrer; Stuart L. James

doi:10.1002/adma.202306521

Liquids with High Compressibility

Beibei Lai, Siyuan Liu, John Cahir, Yueting Sun, Haixia Yin, Tristan Youngs, Jin-Chong Tan, Sergio F. Fonrouge, Mario G. Del Pópolo, José L. Borioni, Deborah E. Crawford, Francesca M. Alexander, Chunchun Li, Steven E. J. Bell, Barry Murrer, Stuart L. James^*

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

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Abstract

Compressibility is a fundamental property of all materials. For fluids, that is, gases and liquids, compressibility forms the basis of technologies such as pneumatics and hydraulics and determines basic phenomena such as the propagation of sound and shock waves. In contrast to gases, liquids are almost incompressible. If the compressibility of liquids could be increased and controlled, new applications in hydraulics and shock absorption could result. Here, it is shown that dispersing hydrophobic porous particles into water gives aqueous suspensions with much greater compressibilities than any normal liquids such as water (specifically, up to 20 times greater over certain pressure ranges). The increased compressibility results from water molecules being forced into the hydrophobic pores of the particles under applied pressure. The degree of compression can be controlled by varying the amount of porous particles added. Also, the pressure range of compression can be reduced by adding methanol or increased by adding salt. In all cases, the liquids expand back to their original volume when the applied pressure is released. The approach shown here is simple and economical and could potentially be scaled up to give large amounts of highly compressible liquids.

Original language	English
Article number	2306521
Number of pages	9
Journal	Advanced Materials
Early online date	29 Aug 2023
DOIs	https://doi.org/10.1002/adma.202306521
Publication status	E-pub ahead of print - 29 Aug 2023

Keywords

hydrophobicity
ZIF
compressible liquids
neutron scattering
porous liquids

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title = "Liquids with High Compressibility",

abstract = "Compressibility is a fundamental property of all materials. For fluids, that is, gases and liquids, compressibility forms the basis of technologies such as pneumatics and hydraulics and determines basic phenomena such as the propagation of sound and shock waves. In contrast to gases, liquids are almost incompressible. If the compressibility of liquids could be increased and controlled, new applications in hydraulics and shock absorption could result. Here, it is shown that dispersing hydrophobic porous particles into water gives aqueous suspensions with much greater compressibilities than any normal liquids such as water (specifically, up to 20 times greater over certain pressure ranges). The increased compressibility results from water molecules being forced into the hydrophobic pores of the particles under applied pressure. The degree of compression can be controlled by varying the amount of porous particles added. Also, the pressure range of compression can be reduced by adding methanol or increased by adding salt. In all cases, the liquids expand back to their original volume when the applied pressure is released. The approach shown here is simple and economical and could potentially be scaled up to give large amounts of highly compressible liquids.",

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author = "Beibei Lai and Siyuan Liu and John Cahir and Yueting Sun and Haixia Yin and Tristan Youngs and Jin-Chong Tan and Fonrouge, {Sergio F.} and P{\'o}polo, {Mario G. Del} and Borioni, {Jos{\'e} L.} and Crawford, {Deborah E.} and Alexander, {Francesca M.} and Chunchun Li and Bell, {Steven E. J.} and Barry Murrer and James, {Stuart L.}",

year = "2023",

month = aug,

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doi = "10.1002/adma.202306521",

language = "English",

journal = "Advanced Materials",

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publisher = "Wiley-VCH Verlag",

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T1 - Liquids with High Compressibility

AU - Lai, Beibei

AU - Liu, Siyuan

AU - Cahir, John

AU - Sun, Yueting

AU - Yin, Haixia

AU - Youngs, Tristan

AU - Tan, Jin-Chong

AU - Fonrouge, Sergio F.

AU - Pópolo, Mario G. Del

AU - Borioni, José L.

AU - Crawford, Deborah E.

AU - Alexander, Francesca M.

AU - Li, Chunchun

AU - Bell, Steven E. J.

AU - Murrer, Barry

AU - James, Stuart L.

PY - 2023/8/29

Y1 - 2023/8/29

N2 - Compressibility is a fundamental property of all materials. For fluids, that is, gases and liquids, compressibility forms the basis of technologies such as pneumatics and hydraulics and determines basic phenomena such as the propagation of sound and shock waves. In contrast to gases, liquids are almost incompressible. If the compressibility of liquids could be increased and controlled, new applications in hydraulics and shock absorption could result. Here, it is shown that dispersing hydrophobic porous particles into water gives aqueous suspensions with much greater compressibilities than any normal liquids such as water (specifically, up to 20 times greater over certain pressure ranges). The increased compressibility results from water molecules being forced into the hydrophobic pores of the particles under applied pressure. The degree of compression can be controlled by varying the amount of porous particles added. Also, the pressure range of compression can be reduced by adding methanol or increased by adding salt. In all cases, the liquids expand back to their original volume when the applied pressure is released. The approach shown here is simple and economical and could potentially be scaled up to give large amounts of highly compressible liquids.

AB - Compressibility is a fundamental property of all materials. For fluids, that is, gases and liquids, compressibility forms the basis of technologies such as pneumatics and hydraulics and determines basic phenomena such as the propagation of sound and shock waves. In contrast to gases, liquids are almost incompressible. If the compressibility of liquids could be increased and controlled, new applications in hydraulics and shock absorption could result. Here, it is shown that dispersing hydrophobic porous particles into water gives aqueous suspensions with much greater compressibilities than any normal liquids such as water (specifically, up to 20 times greater over certain pressure ranges). The increased compressibility results from water molecules being forced into the hydrophobic pores of the particles under applied pressure. The degree of compression can be controlled by varying the amount of porous particles added. Also, the pressure range of compression can be reduced by adding methanol or increased by adding salt. In all cases, the liquids expand back to their original volume when the applied pressure is released. The approach shown here is simple and economical and could potentially be scaled up to give large amounts of highly compressible liquids.

KW - hydrophobicity

KW - ZIF

KW - compressible liquids

KW - neutron scattering

KW - porous liquids

U2 - 10.1002/adma.202306521

DO - 10.1002/adma.202306521

M3 - Article

SN - 0935-9648

JO - Advanced Materials

JF - Advanced Materials

M1 - 2306521

ER -

Liquids with High Compressibility

Abstract

Keywords

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