High pressure investigation of α -form and CH4 -loaded β -form of hydroquinone compounds

Yongjae Lee; Jong Won Lee; Hyun Hwi Lee; Dong Ryeol Lee; Chi Chang Kao; Taro Kawamura; Yoshitaka Yamamoto; Ji Ho Yoon

doi:10.1063/1.3097763

High pressure investigation of α -form and CH4 -loaded β -form of hydroquinone compounds

Yongjae Lee, Jong Won Lee, Hyun Hwi Lee, Dong Ryeol Lee, Chi Chang Kao, Taro Kawamura, Yoshitaka Yamamoto, Ji Ho Yoon

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Abstract

The high pressure compression behaviors of two hydroquinone compounds have been investigated using a combination of in situ synchrotron x-ray powder diffraction and Raman spectroscopy up to ca. 7 GPa. The structural integrity of the α -form hydroquinone clathrate is maintained throughout the pressure range, whereas the CH4 -loaded β -form hydroquinone clathrate decomposes and transforms to a new high pressure phase near 5 GPa. The bulk modulus (K) and its pressure derivative (K′) of the α -form and the CH4 -loaded β -form hydroquinones are measured to be 8.2(3) GPa and 8.4(4), and 10(1) GPa and 9(2), respectively, representing one of the most compressible classes of crystalline solids reported in the literature. The corresponding axial compression behaviors, however, show greater contrast between the two hydroquinone compounds; the elastic anisotropy of the α -form is only marginal, being K (a):K (c) =1.08:1, whereas that of the CH4 -loaded β -form is rather drastic, being K (a):K (c) =11.8:1. This is attributed to the different dimensionality of the hydrogen bonding networks between the two structures and might in turn explain the observed structural instability of the β -form, compared to the α -form.

Original language	English
Article number	124511
Journal	Journal of Chemical Physics
Volume	130
Issue number	12
DOIs	https://doi.org/10.1063/1.3097763
Publication status	Published - 2009

Bibliographical note

Funding Information:
This work was supported by the Ministry of Knowledge Economy through Energy Technology Innovation Program of the Korean Government and the Korea Sanhak Foundation. Experiments at PAL were supported in part by the Ministry of Education, Science and Technology of the Korean Government and Pohang University of Science and Technology (POSTECH). Research carried out in part at the NSLS at BNL is supported by the U.S. Department of Energy, Office of Basic Energy Sciences. Y. Lee thanks the technical assistant of Dr. Z. Hu of beamline X17C at NSLS.

All Science Journal Classification (ASJC) codes

Physics and Astronomy(all)
Physical and Theoretical Chemistry

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title = "High pressure investigation of α -form and CH4 -loaded β -form of hydroquinone compounds",

abstract = "The high pressure compression behaviors of two hydroquinone compounds have been investigated using a combination of in situ synchrotron x-ray powder diffraction and Raman spectroscopy up to ca. 7 GPa. The structural integrity of the α -form hydroquinone clathrate is maintained throughout the pressure range, whereas the CH4 -loaded β -form hydroquinone clathrate decomposes and transforms to a new high pressure phase near 5 GPa. The bulk modulus (K) and its pressure derivative (K′) of the α -form and the CH4 -loaded β -form hydroquinones are measured to be 8.2(3) GPa and 8.4(4), and 10(1) GPa and 9(2), respectively, representing one of the most compressible classes of crystalline solids reported in the literature. The corresponding axial compression behaviors, however, show greater contrast between the two hydroquinone compounds; the elastic anisotropy of the α -form is only marginal, being K (a):K (c) =1.08:1, whereas that of the CH4 -loaded β -form is rather drastic, being K (a):K (c) =11.8:1. This is attributed to the different dimensionality of the hydrogen bonding networks between the two structures and might in turn explain the observed structural instability of the β -form, compared to the α -form.",

author = "Yongjae Lee and Lee, {Jong Won} and Lee, {Hyun Hwi} and Lee, {Dong Ryeol} and Kao, {Chi Chang} and Taro Kawamura and Yoshitaka Yamamoto and Yoon, {Ji Ho}",

note = "Funding Information: This work was supported by the Ministry of Knowledge Economy through Energy Technology Innovation Program of the Korean Government and the Korea Sanhak Foundation. Experiments at PAL were supported in part by the Ministry of Education, Science and Technology of the Korean Government and Pohang University of Science and Technology (POSTECH). Research carried out in part at the NSLS at BNL is supported by the U.S. Department of Energy, Office of Basic Energy Sciences. Y. Lee thanks the technical assistant of Dr. Z. Hu of beamline X17C at NSLS.",

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AU - Lee, Yongjae

AU - Lee, Jong Won

AU - Lee, Hyun Hwi

AU - Lee, Dong Ryeol

AU - Kao, Chi Chang

AU - Kawamura, Taro

AU - Yamamoto, Yoshitaka

AU - Yoon, Ji Ho

N1 - Funding Information: This work was supported by the Ministry of Knowledge Economy through Energy Technology Innovation Program of the Korean Government and the Korea Sanhak Foundation. Experiments at PAL were supported in part by the Ministry of Education, Science and Technology of the Korean Government and Pohang University of Science and Technology (POSTECH). Research carried out in part at the NSLS at BNL is supported by the U.S. Department of Energy, Office of Basic Energy Sciences. Y. Lee thanks the technical assistant of Dr. Z. Hu of beamline X17C at NSLS.

PY - 2009

Y1 - 2009

N2 - The high pressure compression behaviors of two hydroquinone compounds have been investigated using a combination of in situ synchrotron x-ray powder diffraction and Raman spectroscopy up to ca. 7 GPa. The structural integrity of the α -form hydroquinone clathrate is maintained throughout the pressure range, whereas the CH4 -loaded β -form hydroquinone clathrate decomposes and transforms to a new high pressure phase near 5 GPa. The bulk modulus (K) and its pressure derivative (K′) of the α -form and the CH4 -loaded β -form hydroquinones are measured to be 8.2(3) GPa and 8.4(4), and 10(1) GPa and 9(2), respectively, representing one of the most compressible classes of crystalline solids reported in the literature. The corresponding axial compression behaviors, however, show greater contrast between the two hydroquinone compounds; the elastic anisotropy of the α -form is only marginal, being K (a):K (c) =1.08:1, whereas that of the CH4 -loaded β -form is rather drastic, being K (a):K (c) =11.8:1. This is attributed to the different dimensionality of the hydrogen bonding networks between the two structures and might in turn explain the observed structural instability of the β -form, compared to the α -form.

AB - The high pressure compression behaviors of two hydroquinone compounds have been investigated using a combination of in situ synchrotron x-ray powder diffraction and Raman spectroscopy up to ca. 7 GPa. The structural integrity of the α -form hydroquinone clathrate is maintained throughout the pressure range, whereas the CH4 -loaded β -form hydroquinone clathrate decomposes and transforms to a new high pressure phase near 5 GPa. The bulk modulus (K) and its pressure derivative (K′) of the α -form and the CH4 -loaded β -form hydroquinones are measured to be 8.2(3) GPa and 8.4(4), and 10(1) GPa and 9(2), respectively, representing one of the most compressible classes of crystalline solids reported in the literature. The corresponding axial compression behaviors, however, show greater contrast between the two hydroquinone compounds; the elastic anisotropy of the α -form is only marginal, being K (a):K (c) =1.08:1, whereas that of the CH4 -loaded β -form is rather drastic, being K (a):K (c) =11.8:1. This is attributed to the different dimensionality of the hydrogen bonding networks between the two structures and might in turn explain the observed structural instability of the β -form, compared to the α -form.

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High pressure investigation of α -form and CH4 -loaded β -form of hydroquinone compounds

Abstract

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