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 Results for DC.creator="P." AND DC.creator="Pattison" in section 2.9.3 of volume H   page 1 of 2 pages.
Main types of reaction cells
van Beek, W. and Pattison, P.  International Tables for Crystallography (2019). Vol. H, Section 2.9.3, pp. 189-197 [ doi:10.1107/97809553602060000944 ]
... expension/contraction. Adv. X-ray Anal. 39, 713-722.GoogleScholar Chupas, P. J., Chapman, K. W., Kurtz, C., Hanson, J. C., Lee, P. L. & Grey, C. P. (2008). A versatile sample-environment cell for non- ...

Electrochemistry using neutron diffraction
van Beek, W. and Pattison, P.  International Tables for Crystallography (2019). Vol. H, Section 2.9.3.4.3, p. 196 [ doi:10.1107/97809553602060000944 ]
... 280-290.GoogleScholar Rosciano, F., Holzapfel, M., Scheifele, W. & Novák, P. (2008). A novel electrochemical cell for in situ neutron ... International Tables for Crystallography (2019). Vol. H, ch. 2.9, p. 196 © International Union of Crystallography 2019 | home | resources | advanced search ...

Solid-gas reactions
van Beek, W. and Pattison, P.  International Tables for Crystallography (2019). Vol. H, Section 2.9.3.4.2, p. 196 [ doi:10.1107/97809553602060000944 ]
... problem of hydrogen embrittlement. References Tonus, F., Bahout, M., Henry, P. F., Dutton, S. E., Roisnel, T. & Battle, P. D. (2009). Use of in situ neutron diffraction to ... International Tables for Crystallography (2019). Vol. H, ch. 2.9, p. 196 © International Union of Crystallography 2019 | home | resources | advanced ...

Introduction
van Beek, W. and Pattison, P.  International Tables for Crystallography (2019). Vol. H, Section 2.9.3.4.1, pp. 195-196 [ doi:10.1107/97809553602060000944 ]
Introduction 2.9.3.4.1. Introduction The special characteristics of neutrons imply both advantages and challenges for the design of in situ experiments and their associated equipment. The differences in penetration depths between X-rays and neutrons and the correspondingly smaller scattering cross sections for neutrons, together with the much lower flux densities, imply ...

Cells specifically for neutrons
van Beek, W. and Pattison, P.  International Tables for Crystallography (2019). Vol. H, Section 2.9.3.4, pp. 195-197 [ doi:10.1107/97809553602060000944 ]
... 280-290.GoogleScholar Rosciano, F., Holzapfel, M., Scheifele, W. & Novák, P. (2008). A novel electrochemical cell for in situ neutron ... batteries. ChemSusChem, 8, 2826-2853.GoogleScholar Tonus, F., Bahout, M., Henry, P. F., Dutton, S. E., Roisnel, T. & Battle, P. D. (2009). Use of in situ neutron diffraction ...

Large-volume cells for angular-dispersive diffraction
van Beek, W. and Pattison, P.  International Tables for Crystallography (2019). Vol. H, Section 2.9.3.3.4, pp. 194-195 [ doi:10.1107/97809553602060000944 ]
... academic and industrial worlds. References Friscic, T., Halasz, I., Beldon, P. J., Belenguer, A. M., Adams, F., Kimber, S. A. J. ... Brien, M. G., Espinosa-Alonso, L., Weckhuysen, B. M. & Barnes, P. (2011). Dynamic X-ray diffraction computed tomography reveals real ... Ed. 50, 10148-10152.GoogleScholar Jensen, H., Bremholm, M., Nielsen, R. P., Joensen, K. D., Pedersen, J., Birkedal, H., Chen, Y.- ...

Large-volume cells for energy-dispersive diffraction
van Beek, W. and Pattison, P.  International Tables for Crystallography (2019). Vol. H, Section 2.9.3.3.3, p. 194 [ doi:10.1107/97809553602060000944 ]
... al. (2011 ) with permission from Elsevier. References He, H., Barnes, P., Munn, J., Turrillas, X. & Klinowski, J. (1992). Autoclave synthesis ... ray diffraction. Rev. Sci. Instrum. 83, 084101.GoogleScholar Munn, J., Barnes, P., Haüsermann, D., Axon, S. A. & Klinowski, J. (1992). ... X-ray diffraction. J. Phase Transit. 39, 129-134.GoogleScholar Norby, P. (2006). In-situ XRD as a tool to ...

Cells with humidity control
van Beek, W. and Pattison, P.  International Tables for Crystallography (2019). Vol. H, Section 2.9.3.3.2, pp. 193-194 [ doi:10.1107/97809553602060000944 ]
... materials. Cryst. Growth Des. 8, 336-343.GoogleScholar Walspurger, S., Cobden, P. D., Haije, W. G., Westerwaal, R., Elzinga, G. D. & Safonova ...

Cells for electrochemistry
van Beek, W. and Pattison, P.  International Tables for Crystallography (2019). Vol. H, Section 2.9.3.3.1, pp. 192-193 [ doi:10.1107/97809553602060000944 ]
... Power Sources, 244, 109-114.GoogleScholar De Marco, R. & Veder, J.-P. (2010). In situ structural characterization of electrochemical systems using ... J. Appl. Cryst. 49, 340-345.GoogleScholar Johnsen, R. E. & Norby, P. (2013). Capillary-based micro-battery cell for in situ ...

Reactions requiring specialist cells
van Beek, W. and Pattison, P.  International Tables for Crystallography (2019). Vol. H, Section 2.9.3.3, pp. 192-195 [ doi:10.1107/97809553602060000944 ]
... ray Anal. 39, 713-722.GoogleScholar De Marco, R. & Veder, J.-P. (2010). In situ structural characterization of electrochemical systems using ... Anal. Chem. 29, 528-537.GoogleScholar Friscic, T., Halasz, I., Beldon, P. J., Belenguer, A. M., Adams, F., Kimber, S. A. J. ... milling reactions. Nat. Chem. 5, 66-73.GoogleScholar He, H., Barnes, P., Munn, J., Turrillas, X. & Klinowski, J. (1992). Autoclave ...

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