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Books on the topic 'Hydrogen recycling'

Author: Grafiati
Published: 4 June 2021
Last updated: 17 June 2025

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1

Wu, C. H., ed. Hydrogen Recycling at Plasma Facing Materials. Springer Netherlands, 2000. http://dx.doi.org/10.1007/978-94-011-4331-8.

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2

H, Wu C., North Atlantic Treaty Organization. Scientific Affairs Division., and NATO Advanced Research Workshop on Hydrogen Recycling at Plasma Facing Materials (1999 : Saint Petersburg, Russia), eds. Hydrogen recycling at plasma facing materials. Kluwer Academic, 2000.

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3

Wu, C. H. Hydrogen Recycling at Plasma Facing Materials. Springer Netherlands, 2000.

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4

Hassanein, Ahmed, ed. Hydrogen and Helium Recycling at Plasma Facing Materials. Springer Netherlands, 2002. http://dx.doi.org/10.1007/978-94-010-0444-2.

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5

Mizuki, Nobuaki. Arumi-kei haikibutsu kara no arumi kōkōritsu kaishū gijutsu to, Hokuriku chihō ni tekishita suiso enerugī riyō shisutemu no kaihatsu: Heisei 21-nendo chikyū ondanka taisaku gijutsu kaihatsu jigyō seika hōkokusho. Tonami Unʼyu, 2010.

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6

NATO Advanced Research Workshop on Hydrogen Isotope Recycling at Plasma Facing Materials in Fusion Reactors (2001 Argonne, Ill.). Hydrogen and helium recycling at plasma facing materials: [proceedings of the NATO Advanced Research Workshop on Hydrogen Isotope Recycling at Plasma Facing Materials in Fusion Reactors, Argonne, Illinois, U.S.A., 22-24 August 2001]. Kluwer Academic, 2002.

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7

Wu, C. H. Hydrogen Recycling at Plasma Facing Materials. Springer, 2000.

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8

Hassanein, Ahmed. Hydrogen and Helium Recycling at Plasma Facing Materials. Springer, 2012.

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9

Hassanein, Ahmed. Hydrogen and Helium Recycling at Plasma Facing Materials. Springer, 2002.

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10

Hassanein, Ahmed. Hydrogen and Helium Recycling at Plasma Facing Materials: Mathematics, Physics and. Springer, 2002.

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11

Carretti, C., G. Gervasini, and F. Reiter. Recycling, Inventory and Permeation of Hydrogen Isotopes and Helium in the First Wall of a Thermonuclear Fusion Reactor. European Communities / Union (EUR-OP/OOPEC/OPOCE), 1989.

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12

Vincent, Julian. Biomimetic materials. Oxford University Press, 2018. http://dx.doi.org/10.1093/oso/9780199674923.003.0010.

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Biological materials present the conventional materials scientist with alternative ways of achieving durability, recyclability, and adaptability. Technical materials are commonly designed to resist the initiation of cracks; biological materials control disaster by initiating failure where it can be more closely controlled and the strain energy can be more easily absorbed, at the same time controlling shape so that stress concentrations are avoided in sensitive areas. Most materials are hydrated and soft, achieving stiffness by dehydration and mineralization. The low energy of the predominant hydrogen bonds allows relatively easy breakdown and recycling of the units of biological materials. Since most biological materials are metabolically accessible (obvious exceptions are keratins and wood) they can be recycled and repaired in situ, adapting the organism to changing circumstances internally and externally. At the molecular level, liquid crystallinity is a driving force.
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13

Bright Green Lies: How the Environmental Movement Lost Its Way and What We Can Do About It. Monkfish Book Publishing Company, 2021.

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14

Jensen, Derrick, Lierre Keith, and Max Wilbert. Bright Green Lies. Monkfish Book Publishing Company, 2021.

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15

Keith, Lierre, Derrick Jensen, and Max Wilbert. Bright Green Lies: How the Environmental Movement Lost Its Way and What We Can Do About It. Monkfish Book Publishing Company, 2021.

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16

Schöner Grüner Schein: Warum »grüne« Technologien derselbe Irrweg in Grün sind. Neue Erde, 2023.

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