Shown is the change of mass of a sample of 10% yttrium substituted barium zirconate proton conductor powder during exposure at dry nitrogen gas (dehydration) and subsequent exposure of humidified, H2O-enriched nitrogen gas (hydration) at temperatures from ambient temperatrure to 900°C.Data recorded 22 April 2008 at Empa Switzerland.

Shown is the change of mass of a sample of 10% yttrium substituted barium zirconate proton conductor powder during exposure at dry nitrogen gas (dehydration) and subsequent exposure of humidified, H2O-enriched nitrogen gas (hydration) at temperatures from ambient temperatrure to 900°C.Data recorded 22 April 2008 at Empa Switzerland.

This research was funded by Swiss National Science Foundation project shown in https://data.snf.ch/grants/grant/189455.We would like to thank the International Foundation High Altitude Research Stations Jungfraujoch and Gornergrat (HFSJG), 3012 Bern, Switzerland, for enabling us to carry out our experiments at the Jungfraujoch High Altitude Research Station.We also thank the HFSJG custodians Mr. Thomas Furter and Mrs. Sonja Stöckli for the support of our activities.We are grateful to Mrs. Ilse Koninckx from SCK CEN for support with cyanobacteria cultivation.We are grateful to Michael Fink and Erwin Pieper from Empa Engineering & Workshop for manufacturing the HFSJG container box.

This research was funded by Swiss National Science Foundation project shown in https://data.snf.ch/grants/grant/189455.We would like to thank the International Foundation High Altitude Research Stations Jungfraujoch and Gornergrat (HFSJG), 3012 Bern, Switzerland, for enabling us to carry out our experiments at the Jungfraujoch High Altitude Research Station.We also thank the HFSJG custodians Mr. Thomas Furter and Mrs. Sonja Stöckli for the support of our activities.We are grateful to Mrs. Ilse Koninckx from SCK CEN for support with cyanobacteria cultivation.We are grateful to Michael Fink and Erwin Pieper from Empa Engineering & Workshop for manufacturing the HFSJG container box.

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The Thorlabs Raman spectroscopy kit was tested with water. The excitation light was 785nm laser diode. The laser wavelength was calibrated with a NIST polystyrene sample in the shape of a prisma with size of a cuvette. The sample was the empty quartz cuvette, and the cuvette filled with water. Simple subtraction of both spectry yields a watzer spectrum, with a broad H-O-H vibration peak at 900 nm. Modular Raman Spectroscopy Kit (thorlabs.de)

The Thorlabs Raman spectroscopy kit was tested with water. The excitation light was 785nm laser diode. The laser wavelength was calibrated with a NIST polystyrene sample in the shape of a prisma with size of a cuvette. The sample was the empty quartz cuvette, and the cuvette filled with water. Simple subtraction of both spectry yields a watzer spectrum, with a broad H-O-H vibration peak at 900 nm. Modular Raman Spectroscopy Kit (thorlabs.de)

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