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Pflanzenkohle (German Wikipedia)

Analysis of information sources in references of the Wikipedia article "Pflanzenkohle" in German language version.

refsWebsite
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13doi.org
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9ithaka-journal.net
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9zdb-katalog.de
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7redirecter.toolforge.org
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4web.archive.org
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3cornell.edu
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3umweltbundesamt.de
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3european-biochar.org
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3deadurl.invalid
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3mementoweb.org
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2fachverbandpflanzenkohle.org
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2researchgate.net
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2biochar-international.org
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2taz.de
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2diw.de
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2europa.eu
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2wiley.com
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1rnz.de
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1fu-berlin.de
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1springerprofessional.de
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1klimareporter.de
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1sciencedirect.com
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1elsevier.com
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1agrokarbo.info
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1icevirtuallibrary.com
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1carbonauten.com
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1csiro.au
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1bayern.de
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1demeter.de
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1sciencesconf.org
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1biochar-journal.org
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1bund.net
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agrokarbo.info

bayern.de

lfl.bayern.de

biochar-international.org

biochar-journal.org

bund.net

carbonauten.com

cornell.edu

css.cornell.edu

  • Johannes Lehmann: Terra Preta de Indio. In: Soil Biochemistry (internal citations omitted). Abgerufen am 8. Oktober 2013: „Not only do biochar-enriched soils contain more carbon – 150gC/kg compared to 20-30gC/kg in surrounding soils – but biochar-enriched soils are, on average, more than twice as deep as surrounding soils.“
  • Johannes Lehmann: A handful of carbon. (PDF; 1023 kB). In: Nature. 447, 2007, S. 143–144, doi:10.1038/447143a: „…this sequestration can be taken a step further by heating the plant biomass without oxygen (a process known as low-temperature pyrolysis).“
  • Johannes Lehmann: Bio-energy in the black. (PDF; 488 kB). In: Front Ecol Environ. 5 (7): „…pyrolysis produces 3–9 times more energy than is invested in generating the energy. At the same time, about half of the carbon can be sequestered in soil. The total carbon stored in these soils can be one order of magnitude higher than adjacent soils.“

csiro.au

publish.csiro.au

  • Makoto Ogawa, Yasuyuki Okimori: Pioneering works in biochar research, Japan. In: Australian Journal of Soil Research. Band 48, 2010, S. 489–500 (csiro.au [PDF]).

deadurl.invalid

demeter.de

diw.de

doi.org

  • Lu Lu u. a.: Wastewater treatment for carbon capture and utilization. In: Nature Sustainability. Band 1, 2018, S. 750–758, doi:10.1038/s41893-018-0187-9.
  • Sonja Schimmelpfennig, Bruno Glaser: One Step Forward toward Characterization: Some Important Material Properties to Distinguish Biochars. In: Journal of Environmental Quality. Band 41, Nr. 4, 2012, S. 1001–1013, doi:10.2134/jeq2011.0146 (wiley.com).
  • Balwant Singh, Bhupinder Pal Singh, Annette L. Cowie: Characterisation and evaluation of biochars for their application as a soil amendment. In: Australian Journal of Soil Research. Band 48, Nr. 7, 28. September 2010, S. 516–525, doi:10.1071/SR10058.
  • Yang Ding, Yunguo Liu, Shaobo Liu, Zhongwu Li, Xiaofei Tan, Xixian Huang, Guangming Zeng, Lu Zhou, Bohong Zheng: Biochar to improve soil fertility. A review. In: Agronomy for Sustainable Development. Band 36, 30. Mai 2016, S. 36, doi:10.1007/s13593-016-0372-z.
  • Stephen Joseph, Annette L. Cowie, Lukas Van Zwieten, Nanthi Bolan, Alice Budai: How biochar works, and when it doesn't: A review of mechanisms controlling soil and plant responses to biochar. In: GCB Bioenergy. Band 13, Nr. 11, 2021, ISSN 1757-1707, S. 1731–1764, doi:10.1111/gcbb.12885 (wiley.com [abgerufen am 16. November 2021]).
  • Kumuduni Niroshika Palansooriya, Mee Kyung Sang, Avanthi Deshani Igalavithana, Ming Zhang, Deyi Hou: Biochar alters chemical and microbial properties of microplastic-contaminated soil. In: Environmental Research. Band 209, Juni 2022, S. 112807, doi:10.1016/j.envres.2022.112807 (elsevier.com [abgerufen am 10. Juni 2022]).
  • Constanze Werner, Hans-Peter Schmidt, Dieter Gerten, Wolfgang Lucht, Claudia Kammann: Biogeochemical potential of biomass pyrolysis systems for limiting global warming to 1.5° C. In: Environmental Research Letters. 13(4), 2018, S. 044036. doi:10.1088/1748-9326/aabb0e
  • Johannes Lehmann: A handful of carbon. (PDF; 1023 kB). In: Nature. 447, 2007, S. 143–144, doi:10.1038/447143a: „…this sequestration can be taken a step further by heating the plant biomass without oxygen (a process known as low-temperature pyrolysis).“
  • Dominic Woolf, James E. Amonette, F. Alayne Street-Perrott, Johannes Lehmann, Stephen Joseph: Sustainable biochar to mitigate global climate change. In: Nature Communications. Band 1, Nr. 5, August 2010, ISSN 2041-1723, S. 1–9, doi:10.1038/ncomms1053.
  • N. Jafri, W. Y. Wong, V. Doshi, L. W. Yoon, K. H. Cheah: A review on production and characterization of biochars for application in direct carbon fuel cells. In: Process Safety and Environmental Protection. Band 118, August 2018, S. 152–166, doi:10.1016/j.psep.2018.06.036 (researchgate.net).
  • Mandu I. Inyang u. a.: A review of biochar as a low-cost adsorbent for aqueous heavy metal removal. In: Critical Reviews in Environmental Science and Technology. Band 46, Nr. 4, 12. Dezember 2015, S. 406–433, doi:10.1080/10643389.2015.1096880.
  • Daniel Suarez-Riera, Luca Lavagna, Mattia Bartoli, Mauro Giorcelli, Matteo Pavese: The influence of biochar shape on cement-based materials. In: Magazine of Concrete Research. 22. Juni 2022, ISSN 0024-9831, S. 1–6, doi:10.1680/jmacr.21.00237 (icevirtuallibrary.com [abgerufen am 27. Juni 2022]).
  • European Biochar Certificate – Richtlinien für die nachhaltige Produktion von Pflanzenkohle. (PDF) In: EBC (2012), Version 8.2G vom 19. April 2019. European Biochar Foundation (EBC), Arbaz, Schweiz, 19. April 2019, archiviert vom Original (nicht mehr online verfügbar) am 21. Oktober 2020; abgerufen am 18. Juni 2019. doi:10.13140/RG.2.1.4658.7043. Kapitel 9, S. 18–19.

elsevier.com

linkinghub.elsevier.com

  • Kumuduni Niroshika Palansooriya, Mee Kyung Sang, Avanthi Deshani Igalavithana, Ming Zhang, Deyi Hou: Biochar alters chemical and microbial properties of microplastic-contaminated soil. In: Environmental Research. Band 209, Juni 2022, S. 112807, doi:10.1016/j.envres.2022.112807 (elsevier.com [abgerufen am 10. Juni 2022]).

europa.eu

webgate.ec.europa.eu

  • Eintrag zu E 153: Vegetable carbon in der Europäischen Datenbank für Lebensmittelzusatzstoffe, abgerufen am 16. Juni 2020.

ec.europa.eu

european-biochar.org

fachverbandpflanzenkohle.org

fu-berlin.de

refubium.fu-berlin.de

  • Konstantin Terytze, Robert Wagner, René Schatten, Kathrin Rößler, Nadine König et al.: Endbericht zum Forschungsvorhaben „Schließung von Kreisläufen durch Energie- und Stoffstrommanagement bei Nutzung der Terra-Preta-Technologie im Botanischen Garten im Hinblick auf Ressourceneffizienz und Klimaschutz – Modellprojekt Urban farming“ (TerraBoGa). Freie Universität Berlin, Fachbereich Geowissenschaften, AG Geoökologie, November 2015 (fu-berlin.de [PDF]).

icevirtuallibrary.com

  • Daniel Suarez-Riera, Luca Lavagna, Mattia Bartoli, Mauro Giorcelli, Matteo Pavese: The influence of biochar shape on cement-based materials. In: Magazine of Concrete Research. 22. Juni 2022, ISSN 0024-9831, S. 1–6, doi:10.1680/jmacr.21.00237 (icevirtuallibrary.com [abgerufen am 27. Juni 2022]).

ithaka-journal.net

klimareporter.de

mementoweb.org

timetravel.mementoweb.org

redirecter.toolforge.org

researchgate.net

rnz.de

sciencedirect.com

sciencesconf.org

4per1000day2018.sciencesconf.org

springerprofessional.de

taz.de

umweltbundesamt.de

web.archive.org

  • Siehe zum Beispiel: Gerit Herold: Rügens Seetang wird zu Biokohle. In: Ostsee-Zeitung. 7. Juli 2017, archiviert vom Original (nicht mehr online verfügbar) am 16. Juni 2019; abgerufen am 16. Juni 2019.
  • Biokohle: Vielfältige Eigenschaften machen verallgemeinerte Aussagen zur Wirkung auf Bodenfunktionen kaum möglich. BGR, archiviert vom Original (nicht mehr online verfügbar) am 16. Juni 2019; abgerufen am 16. Juni 2016.
  • Peter Winsley: Biochar and Bioenergy Production for Climate Change Mitigation. (PDF; 411 kB) In: New Zealand Science Review, Jg. 64, Nr. 5. 2007, S. 5, archiviert vom Original (nicht mehr online verfügbar) am 4. Oktober 2013; abgerufen am 8. Oktober 2013.
  • European Biochar Certificate – Richtlinien für die nachhaltige Produktion von Pflanzenkohle. (PDF) In: EBC (2012), Version 8.2G vom 19. April 2019. European Biochar Foundation (EBC), Arbaz, Schweiz, 19. April 2019, archiviert vom Original (nicht mehr online verfügbar) am 21. Oktober 2020; abgerufen am 18. Juni 2019. doi:10.13140/RG.2.1.4658.7043. Kapitel 9, S. 18–19.

wiley.com

doi.wiley.com

  • Sonja Schimmelpfennig, Bruno Glaser: One Step Forward toward Characterization: Some Important Material Properties to Distinguish Biochars. In: Journal of Environmental Quality. Band 41, Nr. 4, 2012, S. 1001–1013, doi:10.2134/jeq2011.0146 (wiley.com).

onlinelibrary.wiley.com

  • Stephen Joseph, Annette L. Cowie, Lukas Van Zwieten, Nanthi Bolan, Alice Budai: How biochar works, and when it doesn't: A review of mechanisms controlling soil and plant responses to biochar. In: GCB Bioenergy. Band 13, Nr. 11, 2021, ISSN 1757-1707, S. 1731–1764, doi:10.1111/gcbb.12885 (wiley.com [abgerufen am 16. November 2021]).

zdb-katalog.de