gescher andreas (32 Ergebnisse)

Zustand: New.

Zustand: As New. Unread book in perfect condition.

235 mm x 155 mm. VIII, 233 p. Hardcover. Versand aus Deutschland / We dispatch from Germany via Air Mail. Einband bestoßen, daher Mängelexemplar gestempelt, sonst sehr guter Zustand. Imperfect copy due to slightly bumped cover, apart from this in very good condition. Stamped. Stamped. Sprache: Englisch.

Zustand: New.

Zustand: As New. Unread book in perfect condition.

Zustand: New.

Zustand: As New. Unread book in perfect condition.

Zustand: New.

Zustand: As New. Unread book in perfect condition.

Zustand: New. In.

Zustand: New. pp. 236.

Zustand: New. pp. 244.

Taschenbuch. Zustand: Neu. Microbial Metal Respiration | From Geochemistry to Potential Applications | Johannes Gescher (u. a.) | Taschenbuch | viii | Englisch | 2014 | Springer | EAN 9783642441387 | Verantwortliche Person für die EU: Springer Verlag GmbH, Tiergartenstr. 17, 69121 Heidelberg, juergen[dot]hartmann[at]springer[dot]com | Anbieter: preigu.

Taschenbuch. Zustand: Neu. Druck auf Anfrage Neuware - Printed after ordering - Microbes can respire on metals. This seemingly simple finding is one of the major discoveries that were made in the field of microbiology in the last few decades. The importance of this observation is evident. Metals are highly abundant on our planet. Iron is even the most abundant element on Earth and the forth most abundant element in the Earth's crust. Hence, in some environments iron, but also other metals or metalloids, are the dominant respiratory electron acceptors. Their reduction massively drives the carbon cycle in these environments and establishes redox cycles of the metallic electron acceptors themselves. These redox cycles are not only a driving force for other biotic reactions but are furthermore necessary for initiating a number of geochemically relevant abiotic redox conversions. Although widespread and ecologically influential, electron transfer onto metals like ferric iron or manganese is biochemically challenging. The challenge is to transfer respiratory electrons onto metals that occur in nature at neutral pH in the form of metal oxides or oxihydroxides that are effectively insoluble. Obviously, it is necessary that the microbes specially adapt in order to catalyze the electron transfer onto insoluble electron acceptors. The elucidation of these adaptations is an exciting ongoing process. To sum it up, dissimilatory metal reduction has wide-spread implications in the field of microbiology, biochemistry and geochemistry and its discovery was one of the major reasons to establish a novel scientific field called geomicrobiology. Recently, the discovery of potential applications of dissimilatory metal reducers in bioremediation or current production in a microbial fuel cell further increased the interest in studying microbial metal reduction.

Buch. Zustand: Neu. Druck auf Anfrage Neuware - Printed after ordering - Microbes can respire on metals. This seemingly simple finding is one of the major discoveries that were made in the field of microbiology in the last few decades. The importance of this observation is evident. Metals are highly abundant on our planet. Iron is even the most abundant element on Earth and the forth most abundant element in the Earth's crust. Hence, in some environments iron, but also other metals or metalloids, are the dominant respiratory electron acceptors. Their reduction massively drives the carbon cycle in these environments and establishes redox cycles of the metallic electron acceptors themselves. These redox cycles are not only a driving force for other biotic reactions but are furthermore necessary for initiating a number of geochemically relevant abiotic redox conversions. Although widespread and ecologically influential, electron transfer onto metals like ferric iron or manganese is biochemically challenging. The challenge is to transfer respiratory electrons onto metals that occur in nature at neutral pH in the form of metal oxides or oxihydroxides that are effectively insoluble. Obviously, it is necessary that the microbes specially adapt in order to catalyze the electron transfer onto insoluble electron acceptors. The elucidation of these adaptations is an exciting ongoing process. To sum it up, dissimilatory metal reduction has wide-spread implications in the field of microbiology, biochemistry and geochemistry and its discovery was one of the major reasons to establish a novel scientific field called geomicrobiology. Recently, the discovery of potential applications of dissimilatory metal reducers in bioremediation or current production in a microbial fuel cell further increased the interest in studying microbial metal reduction.

Paperback. Zustand: Brand New. 2012 edition. 244 pages. 9.30x6.20x0.55 inches. In Stock.

Hardcover. Zustand: Like New. LIKE NEW. SHIPS FROM MULTIPLE LOCATIONS. book.

Zustand: Sehr gut. original Heft, nicht paginiert, ca. 24 Seiten, einige Abbildungen, beiliegendes Heft, ca. 8 Seiten, enthält Portraitfotos und Kurzbiographien von Darstellern, beiliegende Besetzungsliste vom 23. November 1989. Zustand: sehr gut Japanische Tragödie von Luigi Illica und Giuseppe Giacosa nach John L. Long und David Belasco. In italienischer Sprache mit deutschen Übertiteln. Musikalische Leitung: Stephen Kramer. Inszenierung, Bühne und Kostüme: Jean-Pierre Ponnelle. Spielleitung: Per Boye Hansen. Mitwirkende: Hiroko Nishida, Tone Kruse, Michelle Breedt, Juan Lloveras, Wassili Janulako, u. a. ------- Program booklet Giacomo Puccini MADAME BUTTERFLY Cologne Opera 1985 - Original booklet, unpaginated, approx. 24 pages, some illustrations, accompanying booklet, approx. 8 pages, containing portrait photos and short biographies of the actors, enclosed cast list dated November 23, 1989. Condition: very good - A Japanese tragedy by Luigi Illica and Giuseppe Giacosa, based on the novel by John L. Long and David Belasco. Performed in Italian with German surtitles. Musical direction: Stephen Kramer. Stage direction, set and costumes: Jean-Pierre Ponnelle. Production management: Per Boye Hansen. Cast: Hiroko Nishida, Tone Kruse, Michelle Breedt, Juan Lloveras, Wassili Janulako, and others. deu.

Zustand: Sehr gut. original Heft, nicht paginiert, einige Abbildungen, beiliegende Besetzungsliste vom 14. November 1985. Zustand: sehr gut, geringe Spuren Musikalische Leitung: Hilary Griffiths. Inszenierung, Bühne und Kostüme: Jean-Pierre Ponnelle. Mitwirkende: Yoko Watanabe, Camillo Meghor, Martin Finke, Manfred Schmidt, Ulrich Hielscher, Allessandro Mosna, u.a. ------- Program booklet Giacomo Puccini MADAMA BUTTERFLY Cologne Opera 1985 - Original booklet, unpaginated, some illustrations, enclosed cast list dated November 14, 1985. Condition: very good, minor signs of wear. - Musical direction: Hilary Griffiths. Staging, set and costumes: Jean-Pierre Ponnelle. Performers: Yoko Watanabe, Camillo Meghor, Martin Finke, Manfred Schmidt, Ulrich Hielscher, Alessandro Mosna, among others. deu.

Zustand: new. Questo è un articolo print on demand.

Zustand: new. Questo è un articolo print on demand.

Buch. Zustand: Neu. This item is printed on demand - it takes 3-4 days longer - Neuware -Microbes can respire on metals. This seemingly simple finding is one of the major discoveries that were made in the field of microbiology in the last few decades. The importance of this observation is evident. Metals are highly abundant on our planet. Iron is even the most abundant element on Earth and the forth most abundant element in the Earth's crust. Hence, in some environments iron, but also other metals or metalloids, are the dominant respiratory electron acceptors. Their reduction massively drives the carbon cycle in these environments and establishes redox cycles of the metallic electron acceptors themselves. These redox cycles are not only a driving force for other biotic reactions but are furthermore necessary for initiating a number of geochemically relevant abiotic redox conversions. Although widespread and ecologically influential, electron transfer onto metals like ferric iron or manganese is biochemically challenging. The challenge is to transfer respiratory electrons onto metals that occur in nature at neutral pH in the form of metal oxides or oxihydroxides that are effectively insoluble. Obviously, it is necessary that the microbes specially adapt in order to catalyze the electron transfer onto insoluble electron acceptors. The elucidation of these adaptations is an exciting ongoing process. To sum it up, dissimilatory metal reduction has wide-spread implications in the field of microbiology, biochemistry and geochemistry and its discovery was one of the major reasons to establish a novel scientific field called geomicrobiology. Recently, the discovery of potential applications of dissimilatory metal reducers in bioremediation or current production in a microbial fuel cell further increased the interest in studying microbial metal reduction. 244 pp. Englisch.

Taschenbuch. Zustand: Neu. This item is printed on demand - it takes 3-4 days longer - Neuware -Microbes can respire on metals. This seemingly simple finding is one of the major discoveries that were made in the field of microbiology in the last few decades. The importance of this observation is evident. Metals are highly abundant on our planet. Iron is even the most abundant element on Earth and the forth most abundant element in the Earth's crust. Hence, in some environments iron, but also other metals or metalloids, are the dominant respiratory electron acceptors. Their reduction massively drives the carbon cycle in these environments and establishes redox cycles of the metallic electron acceptors themselves. These redox cycles are not only a driving force for other biotic reactions but are furthermore necessary for initiating a number of geochemically relevant abiotic redox conversions. Although widespread and ecologically influential, electron transfer onto metals like ferric iron or manganese is biochemically challenging. The challenge is to transfer respiratory electrons onto metals that occur in nature at neutral pH in the form of metal oxides or oxihydroxides that are effectively insoluble. Obviously, it is necessary that the microbes specially adapt in order to catalyze the electron transfer onto insoluble electron acceptors. The elucidation of these adaptations is an exciting ongoing process. To sum it up, dissimilatory metal reduction has wide-spread implications in the field of microbiology, biochemistry and geochemistry and its discovery was one of the major reasons to establish a novel scientific field called geomicrobiology. Recently, the discovery of potential applications of dissimilatory metal reducers in bioremediation or current production in a microbial fuel cell further increased the interest in studying microbial metal reduction. 244 pp. Englisch.

Zustand: New. Dieser Artikel ist ein Print on Demand Artikel und wird nach Ihrer Bestellung fuer Sie gedruckt. This book is a timely and comprehensive interdisciplinary review of our current understanding of respiratory metal reductionElucidates the different principles that have to be regarded to fully understand microbial metal reductionWritten by.

Zustand: New. Dieser Artikel ist ein Print on Demand Artikel und wird nach Ihrer Bestellung fuer Sie gedruckt. This book is a timely and comprehensive interdisciplinary review of our current understanding of respiratory metal reductionElucidates the different principles that have to be regarded to fully understand microbial metal reductionWritten by.

Buch. Zustand: Neu. Microbial Metal Respiration | From Geochemistry to Potential Applications | Johannes Gescher (u. a.) | Buch | viii | Englisch | 2012 | Springer | EAN 9783642328664 | Verantwortliche Person für die EU: Springer Verlag GmbH, Tiergartenstr. 17, 69121 Heidelberg, juergen[dot]hartmann[at]springer[dot]com | Anbieter: preigu Print on Demand.

Zustand: New. Print on Demand pp. 236.

Zustand: New. Print on Demand pp. 244 47 Illus. (14 Col.).

Zustand: New. PRINT ON DEMAND pp. 236.

Taschenbuch. Zustand: Neu. This item is printed on demand - Print on Demand Titel. Neuware -Microbes can respire on metals. This seemingly simple finding is one of the major discoveries that were made in the field of microbiology in the last few decades. The importance of this observation is evident. Metals are highly abundant on our planet. Iron is even the most abundant element on Earth and the forth most abundant element in the Earth¿s crust. Hence, in some environments iron, but also other metals or metalloids, are the dominant respiratory electron acceptors. Their reduction massively drives the carbon cycle in these environments and establishes redox cycles of the metallic electron acceptors themselves. These redox cycles are not only a driving force for other biotic reactions but are furthermore necessary for initiating a number of geochemically relevant abiotic redox conversions. Although widespread and ecologically influential, electron transfer onto metals like ferric iron or manganese is biochemically challenging. The challenge is to transfer respiratory electrons onto metals that occur in nature at neutral pH in the form of metal oxides or oxihydroxides that are effectively insoluble. Obviously, it is necessary that the microbes specially adapt in order to catalyze the electron transfer onto insoluble electron acceptors. The elucidation of these adaptations is an exciting ongoing process. To sum it up, dissimilatory metal reduction has wide-spread implications in the field of microbiology, biochemistry and geochemistry and its discovery was one of the major reasons to establish a novel scientific field called geomicrobiology. Recently, the discovery of potential applications of dissimilatory metal reducers in bioremediation or current production in a microbial fuel cell further increased the interest in studying microbial metal reduction.Springer-Verlag GmbH, Tiergartenstr. 17, 69121 Heidelberg 244 pp. Englisch.