Literature DB >> 18439628

Ocean urea fertilization for carbon credits poses high ecological risks.

Patricia M Glibert1, Rhodora Azanza, Michele Burford, Ken Furuya, Eva Abal, Adnan Al-Azri, Faiza Al-Yamani, Per Andersen, Donald M Anderson, John Beardall, G Mine Berg, Larry Brand, Deborah Bronk, Justin Brookes, Joann M Burkholder, Allan Cembella, William P Cochlan, Jackie L Collier, Yves Collos, Robert Diaz, Martina Doblin, Thomas Drennen, Sonya Dyhrman, Yasuwo Fukuyo, Miles Furnas, James Galloway, Edna Granéli, Dao Viet Ha, Gustaaf Hallegraeff, John Harrison, Paul J Harrison, Cynthia A Heil, Kirsten Heimann, Robert Howarth, Cécile Jauzein, Austin A Kana, Todd M Kana, Hakgyoon Kim, Raphael Kudela, Catherine Legrand, Michael Mallin, Margaret Mulholland, Shauna Murray, Judith O'Neil, Grant Pitcher, Yuzao Qi, Nancy Rabalais, Robin Raine, Sybil Seitzinger, Paulo S Salomon, Caroline Solomon, Diane K Stoecker, Gires Usup, Joanne Wilson, Kedong Yin, Mingjiang Zhou, Mingyuan Zhu.   

Abstract

The proposed plan for enrichment of the Sulu Sea, Philippines, a region of rich marine biodiversity, with thousands of tonnes of urea in order to stimulate algal blooms and sequester carbon is flawed for multiple reasons. Urea is preferentially used as a nitrogen source by some cyanobacteria and dinoflagellates, many of which are neutrally or positively buoyant. Biological pumps to the deep sea are classically leaky, and the inefficient burial of new biomass makes the estimation of a net loss of carbon from the atmosphere questionable at best. The potential for growth of toxic dinoflagellates is also high, as many grow well on urea and some even increase their toxicity when grown on urea. Many toxic dinoflagellates form cysts which can settle to the sediment and germinate in subsequent years, forming new blooms even without further fertilization. If large-scale blooms do occur, it is likely that they will contribute to hypoxia in the bottom waters upon decomposition. Lastly, urea production requires fossil fuel usage, further limiting the potential for net carbon sequestration. The environmental and economic impacts are potentially great and need to be rigorously assessed.

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Year:  2008        PMID: 18439628      PMCID: PMC5373553          DOI: 10.1016/j.marpolbul.2008.03.010

Source DB:  PubMed          Journal:  Mar Pollut Bull        ISSN: 0025-326X            Impact factor:   5.553


  12 in total

Review 1.  Mesoscale iron enrichment experiments 1993-2005: synthesis and future directions.

Authors:  P W Boyd; T Jickells; C S Law; S Blain; E A Boyle; K O Buesseler; K H Coale; J J Cullen; H J W de Baar; M Follows; M Harvey; C Lancelot; M Levasseur; N P J Owens; R Pollard; R B Rivkin; J Sarmiento; V Schoemann; V Smetacek; S Takeda; A Tsuda; S Turner; A J Watson
Journal:  Science       Date:  2007-02-02       Impact factor: 47.728

2.  Environment. Ocean iron fertilization--moving forward in a sea of uncertainty.

Authors:  Ken O Buesseler; Scott C Doney; David M Karl; Philip W Boyd; Ken Caldeira; Fei Chai; Kenneth H Coale; Hein J W de Baar; Paul G Falkowski; Kenneth S Johnson; Richard S Lampitt; Anthony F Michaels; S W A Naqvi; Victor Smetacek; Shigenobu Takeda; Andrew J Watson
Journal:  Science       Date:  2008-01-11       Impact factor: 47.728

3.  Release of Dissolved Organic Nitrogen by Marine Diazotrophic Cyanobacteria, Trichodesmium spp.

Authors:  P M Glibert; D A Bronk
Journal:  Appl Environ Microbiol       Date:  1994-11       Impact factor: 4.792

4.  Prochlorococcus marinus strain PCC 9511, a picoplanktonic cyanobacterium, synthesizes the smallest urease.

Authors:  K A Palinska; T Jahns; R Rippka; N Tandeau De Marsac
Journal:  Microbiology       Date:  2000-12       Impact factor: 2.777

5.  The marine cyanobacterium Synechococcus sp. WH7805 requires urease (urea amidohydrolase, EC 3.5.1.5) to utilize urea as a nitrogen source: molecular-genetic and biochemical analysis of the enzyme.

Authors:  Jackie L Collier; Bianca Brahamsha; Brian Palenik
Journal:  Microbiology       Date:  1999-02       Impact factor: 2.777

6.  Rapid and early export of Phaeocystis antarctica blooms in the Ross Sea, Antarctica.

Authors:  G R DiTullio; J M Grebmeier; K R Arrigo; M P Lizotte; D H Robinson; A Leventer; J P Barry; M L VanWoert; R B Dunbar
Journal:  Nature       Date:  2000-04-06       Impact factor: 49.962

7.  Modeling the increase of nodularin content in Baltic Sea Nodularia spumigena during stationary phase in phosphorus-limited batch cultures.

Authors:  Willem Stolte; Chatarina Karlsson; Per Carlsson; Edna Granéli
Journal:  FEMS Microbiol Ecol       Date:  2002-09-01       Impact factor: 4.194

8.  Variability in toxicity of the dinoflagellate Alexandrium tamarense in response to different nitrogen sources and concentrations.

Authors:  Sandric Chee Yew Leong; Ai Murata; Yuji Nagashima; Satoru Taguchi
Journal:  Toxicon       Date:  2004-03-15       Impact factor: 3.033

Review 9.  Ammonia toxicity in fish.

Authors:  D J Randall; T K N Tsui
Journal:  Mar Pollut Bull       Date:  2002       Impact factor: 5.553

10.  The dead zones: oxygen-starved coastal waters.

Authors:  S Joyce
Journal:  Environ Health Perspect       Date:  2000-03       Impact factor: 9.031
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  2 in total

1.  Harmful algal blooms and climate change: Learning from the past and present to forecast the future.

Authors:  Mark L Wells; Vera L Trainer; Theodore J Smayda; Bengt S O Karlson; Charles G Trick; Raphael M Kudela; Akira Ishikawa; Stewart Bernard; Angela Wulff; Donald M Anderson; William P Cochlan
Journal:  Harmful Algae       Date:  2015-09-22       Impact factor: 4.273

2.  Controls on Dissolved Organic Carbon Bioreactivity in River Systems.

Authors:  Ana R A Soares; Jean-François Lapierre; Balathandayuthabani P Selvam; Göran Lindström; Martin Berggren
Journal:  Sci Rep       Date:  2019-10-17       Impact factor: 4.379
  2 in total

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