High pressure: A complementary tool for probing solid-state processes

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High pressure: A complementary tool for probing solid-state processes. / Zakharov, Boris A.; Boldyreva, Elena V.

в: CrystEngComm, Том 21, № 1, 01.01.2019, стр. 10-22.

Результаты исследований: Научные публикации в периодических изданиях › обзорная статья › Рецензирование

BibTeX

@article{4179175fee274994a07711c402215194,

title = "High pressure: A complementary tool for probing solid-state processes",

abstract = "Since the early days of X-ray diffraction, researchers have tried to follow the evolution of crystal structures under extremes of pressure. Recently, interest in this area has exploded, attracting scientists from backgrounds across the physical and life sciences. Much of this rapid expansion has been due to the enhancement of diffraction equipment, including detectors, goniometers, and high-pressure cells, and the development of synchrotron radiation and neutron sources. The high-pressure research generally focuses on the direct effects of pressure on the structural evolution of a system. The present contribution describes examples of a less common application: hydrostatic compression of crystals of organic and coordination compounds can be used as a complementary tool in order to rationalise the mechanisms of the transformations in these solids that take place at atmospheric pressure. The data on the compressibility, equations of state, phase changes, or the effects of pressure on intermolecular distances, molecular conformations and chemical bonds can shed light on the factors that are important for thermal and photochemical reactions in the same crystals without an external load as well as on their solid-state or solvent-assisted polymorphic transformations. The manuscript also discusses how structural studies under extreme conditions can help to rationalise the thermo- and photosalient effects that accompany some solid-state transformations. This knowledge is currently of great importance for materials science since mechanically responsive materials have the potential to be used for the design and manufacture of new supramolecular devices.",

keywords = "X-RAY-DIFFRACTION, III AMMINE COMPLEXES, INDUCED STRUCTURAL-CHANGES, DOT-H INTERACTIONS, EQUATION-OF-STATE, CRYSTAL-STRUCTURE, SINGLE-CRYSTAL, PHASE-TRANSITION, HYDROSTATIC-PRESSURE, MOLECULAR-CRYSTALS",

author = "Zakharov, {Boris A.} and Boldyreva, {Elena V.}",

note = "B. A. Z. acknowledges the support by a grant from the Russian Foundation for Basic Research (RFBR), research project No. 16-33-60093 mol_a_dk. E. V. B. acknowledges the support by Russian Ministry of Science and High Education. B. A. Z and E. V. B. thank Mrs. Evgeniya Kolesnik, Mr. Nikita Bogdanov for technical assistance and Mr. Adam Michalchuk for valuable advice and language polishing.",

year = "2019",

month = jan,

day = "1",

doi = "10.1039/c8ce01391h",

language = "English",

volume = "21",

pages = "10--22",

journal = "CrystEngComm",

issn = "1466-8033",

publisher = "Royal Society of Chemistry",

number = "1",

}

RIS

TY - JOUR

T1 - High pressure: A complementary tool for probing solid-state processes

AU - Zakharov, Boris A.

AU - Boldyreva, Elena V.

N1 - B. A. Z. acknowledges the support by a grant from the Russian Foundation for Basic Research (RFBR), research project No. 16-33-60093 mol_a_dk. E. V. B. acknowledges the support by Russian Ministry of Science and High Education. B. A. Z and E. V. B. thank Mrs. Evgeniya Kolesnik, Mr. Nikita Bogdanov for technical assistance and Mr. Adam Michalchuk for valuable advice and language polishing.

PY - 2019/1/1

Y1 - 2019/1/1

N2 - Since the early days of X-ray diffraction, researchers have tried to follow the evolution of crystal structures under extremes of pressure. Recently, interest in this area has exploded, attracting scientists from backgrounds across the physical and life sciences. Much of this rapid expansion has been due to the enhancement of diffraction equipment, including detectors, goniometers, and high-pressure cells, and the development of synchrotron radiation and neutron sources. The high-pressure research generally focuses on the direct effects of pressure on the structural evolution of a system. The present contribution describes examples of a less common application: hydrostatic compression of crystals of organic and coordination compounds can be used as a complementary tool in order to rationalise the mechanisms of the transformations in these solids that take place at atmospheric pressure. The data on the compressibility, equations of state, phase changes, or the effects of pressure on intermolecular distances, molecular conformations and chemical bonds can shed light on the factors that are important for thermal and photochemical reactions in the same crystals without an external load as well as on their solid-state or solvent-assisted polymorphic transformations. The manuscript also discusses how structural studies under extreme conditions can help to rationalise the thermo- and photosalient effects that accompany some solid-state transformations. This knowledge is currently of great importance for materials science since mechanically responsive materials have the potential to be used for the design and manufacture of new supramolecular devices.

AB - Since the early days of X-ray diffraction, researchers have tried to follow the evolution of crystal structures under extremes of pressure. Recently, interest in this area has exploded, attracting scientists from backgrounds across the physical and life sciences. Much of this rapid expansion has been due to the enhancement of diffraction equipment, including detectors, goniometers, and high-pressure cells, and the development of synchrotron radiation and neutron sources. The high-pressure research generally focuses on the direct effects of pressure on the structural evolution of a system. The present contribution describes examples of a less common application: hydrostatic compression of crystals of organic and coordination compounds can be used as a complementary tool in order to rationalise the mechanisms of the transformations in these solids that take place at atmospheric pressure. The data on the compressibility, equations of state, phase changes, or the effects of pressure on intermolecular distances, molecular conformations and chemical bonds can shed light on the factors that are important for thermal and photochemical reactions in the same crystals without an external load as well as on their solid-state or solvent-assisted polymorphic transformations. The manuscript also discusses how structural studies under extreme conditions can help to rationalise the thermo- and photosalient effects that accompany some solid-state transformations. This knowledge is currently of great importance for materials science since mechanically responsive materials have the potential to be used for the design and manufacture of new supramolecular devices.

KW - X-RAY-DIFFRACTION

KW - III AMMINE COMPLEXES

KW - INDUCED STRUCTURAL-CHANGES

KW - DOT-H INTERACTIONS

KW - EQUATION-OF-STATE

KW - CRYSTAL-STRUCTURE

KW - SINGLE-CRYSTAL

KW - PHASE-TRANSITION

KW - HYDROSTATIC-PRESSURE

KW - MOLECULAR-CRYSTALS

UR - http://www.scopus.com/inward/record.url?scp=85058837281&partnerID=8YFLogxK

UR - https://www.mendeley.com/catalogue/5fe62a22-226a-31d2-8dd1-3abfcea1ae53/

U2 - 10.1039/c8ce01391h

DO - 10.1039/c8ce01391h

M3 - Review article

AN - SCOPUS:85058837281

VL - 21

SP - 10

EP - 22

JO - CrystEngComm

JF - CrystEngComm

SN - 1466-8033

IS - 1

ER -

ID: 18070627