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X-ray diffraction methods for high-pressure solid-state synthesis

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MLA citation style (9th ed.)

Walsh, J, Thiel, S, and Tamerius, Alexandra. X-ray Diffraction Methods for High-pressure Solid-state Synthesis. Elsevier. 2022. mushare.marian.edu/concern/generic_works/bb366e45-b3ec-4a02-b68a-68e16dbd72fd?locale=fr.

APA citation style (7th ed.)

W. J, T. S, & T. Alexandra. (2022). X-ray diffraction methods for high-pressure solid-state synthesis. https://mushare.marian.edu/concern/generic_works/bb366e45-b3ec-4a02-b68a-68e16dbd72fd?locale=fr

Chicago citation style (CMOS 17, author-date)

Walsh, J., Thiel, S., and Tamerius, Alexandra. X-Ray Diffraction Methods for High-Pressure Solid-State Synthesis. Elsevier. 2022. https://mushare.marian.edu/concern/generic_works/bb366e45-b3ec-4a02-b68a-68e16dbd72fd?locale=fr.

Note: These citations are programmatically generated and may be incomplete.

This chapter provides a comprehensive overview of modern high pressure solid-state synthesis methods, with a specific focus on their integration with in situ X-ray diffraction methods. Fundamental concepts in solid-state synthesis are re-examined within the context of synthesis at high pressures, and additional considerations specific to high pressure are introduced. We examine three common apparatuses for achieving high pressures: the Paris–Edinburgh press, the diamond anvil cell, and the multi-anvil press. We present the advantages and disadvantages of each method in the context of high-pressure synthesis, using illustrative examples from the literature. We hope that this chapter will provide the curious solid-state chemist with the foundational understanding required to begin their foray into world of high-pressure synthesis.

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  • Reference Module in Chemistry, Molecular Sciences and Chemical Engineering

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