Articles citing this paper
Bryozoans as southern sentinels of ocean acidification: a major role for a minor phylum
Abigail M. Smith A
+ Author Affiliations
- Author Affiliations
A Department of Marine Science, University of Otago, PO Box 56, Dunedin 9054, New Zealand. Email: abby.smith@otago.ac.nz
Marine and Freshwater Research 60(5) 475-482 https://doi.org/10.1071/MF08321
Submitted: 25 November 2008 Accepted: 28 January 2009 Published: 25 May 2009
38 articles found in Crossref database.
Observed and predicted effects of climate on Australian seabirds
Chambers Lynda E.,
Devney Carol A.,
Congdon Bradley C.,
Dunlop Nic,
Woehler Eric J., Dann Peter
Emu - Austral Ornithology. 2011 111(3). p.235
Seasonal variation in the effects of ocean warming and acidification on a native bryozoan, Celleporaria nodulosa
Durrant Halley M. S.,
Clark Graeme F.,
Dworjanyn Symon A.,
Byrne Maria, Johnston Emma L.
Marine Biology. 2013 160(8). p.1903
Seawater chemistry and biomineralization: did trepostome bryozoans become hypercalcified in the ‘calcite sea’ of the Ordovician?
Taylor Paul David, Kuklinski Piotr
Palaeobiodiversity and Palaeoenvironments. 2011 91(3). p.185
Bryozoans in climate and ocean acidification research: A reappraisal of an under-used tool
Fortunato Helena
Regional Studies in Marine Science. 2015 2 p.32
Bryozoan Studies 2010 (2013)
Bryozoan Studies 2010 (2013)
Growing up in the temperate zone: Age, growth, calcification and carbonate mineralogy of Melicerita chathamensis (Bryozoa) in southern New Zealand
Smith Abigail M., Lawton Emily I.
Palaeogeography, Palaeoclimatology, Palaeoecology. 2010 298(3-4). p.271
Ocean acidification in New Zealand waters: trends and impacts
Law Cliff S.,
Bell James J.,
Bostock Helen C.,
Cornwall Chris E.,
Cummings Vonda J.,
Currie Kim,
Davy Simon K.,
Gammon Malindi,
Hepburn Christopher D.,
Hurd Catriona L.,
Lamare Miles,
Mikaloff-Fletcher Sara E.,
Nelson Wendy A.,
Parsons Darren M.,
Ragg Norman L. C.,
Sewell Mary A.,
Smith Abigail M., Tracey Dianne M.
New Zealand Journal of Marine and Freshwater Research. 2018 52(2). p.155
Summertime calcium carbonate undersaturation in shelf waters of the western Arctic Ocean – how biological processes exacerbate the impact of ocean acidification
Bates N. R.,
Orchowska M. I.,
Garley R., Mathis J. T.
Biogeosciences. 2013 10(8). p.5281
Understanding a bimineralic bryozoan: Skeletal structure and carbonate mineralogy of Odontionella cyclops (Foveolariidae: Cheilostomata: Bryozoa) in New Zealand
Smith Abigail M., Girvan Elizabeth
Palaeogeography, Palaeoclimatology, Palaeoecology. 2010 289(1-4). p.113
Bryozoa from the continental shelf off Tierra del Fuego (Argentina): Species richness, colonial growth-forms, and their relationship with water depth
Liuzzi María G.,
López-Gappa Juan, Salgado Lucía
Estuarine, Coastal and Shelf Science. 2018 214 p.48
Biomineralization in bryozoans: present, past and future
Taylor Paul D.,
Lombardi Chiara, Cocito Silvia
Biological Reviews. 2015 90(4). p.1118
Global Change in Atlantic Coastal Patagonian Ecosystems (2022)
Marine Biodiversity of Aotearoa New Zealand
Gordon Dennis P.,
Beaumont Jennifer,
MacDiarmid Alison,
Robertson Donald A.,
Ahyong Shane T., Goldstien Sharyn Jane
PLoS ONE. 2010 5(8). p.e10905
A genome-skimmed phylogeny of a widespread bryozoan family, Adeonidae
Orr Russell J. S.,
Haugen Marianne N.,
Berning Björn,
Bock Philip,
Cumming Robyn L.,
Florence Wayne K.,
Hirose Masato,
Di Martino Emanuela,
Ramsfjell Mali H.,
Sannum Maja M.,
Smith Abigail M.,
Vieira Leandro M.,
Waeschenbach Andrea, Liow Lee Hsiang
BMC Evolutionary Biology. 2019 19(1).
On the potential for ocean acidification to be a general cause of ancient reef crises
KIESSLING WOLFGANG, SIMPSON CARL
Global Change Biology. 2011 17(1). p.56
Long-term fluctuations in epibiotic bryozoan and hydroid abundances in an Irish sea lough
Little Colin,
Trowbridge Cynthia D.,
Pilling Graham M.,
Cottrell Dylan M.,
Plowman Caitlin Q.,
Stirling Penny,
Morritt David, Williams Gray A.
Estuarine, Coastal and Shelf Science. 2018 210 p.142
Bryozoan Studies 2010 (2013)
Not all sponges will thrive in a high-CO2 ocean: Review of the mineralogy of calcifying sponges
Smith Abigail M.,
Berman Jade,
Key Marcus M., Winter David J.
Palaeogeography, Palaeoclimatology, Palaeoecology. 2013 392 p.463
Skeletal alterations and polymorphism in a Mediterranean bryozoan at natural CO2 vents
Lombardi Chiara,
Gambi Maria Cristina,
Vasapollo Claudio,
Taylor Paul, Cocito Silvia
Zoomorphology. 2011 130(2). p.135
Ocean Acidification: The Newest Threat to the Global Environment
Abbasi Tasneem, Abbasi S. A.
Critical Reviews in Environmental Science and Technology. 2011 41(18). p.1601
Bryozoan carbonate skeletal geochemical composition in the White Sea compared with neighbouring seas
Krzemińska Małgorzata,
Piwoni-Piórewicz Anna,
Shunatova Natalia,
Duczmal-Czernikiewicz Agata,
Muszyński Andrzej,
Kubiak Michał, Kukliński Piotr
Marine Environmental Research. 2022 173 p.105542
Effects of climate change on fish reproduction and early life history stages
Pankhurst Ned W., Munday Philip L.
Marine and Freshwater Research. 2011 62(9). p.1015
Individual and population level effects of ocean acidification on a predator-prey system with inducible defenses: bryozoan-nudibranch interactions in the Salish Sea
Seroy SK, Grünbaum D
Marine Ecology Progress Series. 2018 607 p.1
Patterns of magnesium content in Arctic bryozoan skeletons along a depth gradient
Borszcz Tomasz,
Kukliński Piotr, Taylor Paul D.
Polar Biology. 2013 36(2). p.193
Structural and geochemical alterations in the Mg calcite bryozoan Myriapora truncata under elevated seawater pCO2 simulating ocean acidification
Lombardi Chiara,
Rodolfo-Metalpa Riccardo,
Cocito Silvia,
Gambi Maria Cristina, Taylor Paul David
Marine Ecology. 2011 32(2). p.211
Effects of ocean acidification on growth, organic tissue and protein profile of the Mediterranean bryozoan Myriapora truncata
Lombardi C,
Cocito S,
Gambi MC,
Cisterna B,
Flach F,
Taylor PD,
Keltie K,
Freer A, Cusack M
Aquatic Biology. 2011 13(3). p.251
Bryozoan-dominated benthos of Otago shelf, New Zealand: its associated fauna, environmental setting and anthropogenic threats
Wood ACL, Probert PK
Journal of the Royal Society of New Zealand. 2013 43(4). p.231
Conservation status of New Zealand marine invertebrates, 2009
Freeman DJ,
Marshall BA,
Ahyong ST,
Wing SR, Hitchmough RA
New Zealand Journal of Marine and Freshwater Research. 2010 44(3). p.129
Depth patterns in Antarctic bryozoan skeletal Mg-calcite: Can they provide an analogue for future environmental changes?
Figuerola B,
Kuklinski P, Taylor PD
Marine Ecology Progress Series. 2015 540 p.109
Generality in multispecies responses to ocean acidification revealed through multiple hypothesis testing
Barner Allison K.,
Chan Francis,
Hettinger Annaliese,
Hacker Sally D.,
Marshall Kelsey, Menge Bruce A.
Global Change Biology. 2018 24(10). p.4464
The Mediterranean Sea (2014)
Bimineralic bryozoan skeletons: a comparison of three modern genera
Benedix G.,
Jacob D. E., Taylor P. D.
Facies. 2014 60(2). p.389
Skeletal Mineralogy Patterns of Antarctic Bryozoa
Krzeminska Malgorzata,
Kuklinski Piotr,
Najorka Jens, Iglikowska Anna
The Journal of Geology. 2016 124(3). p.411
Bryozoan communities off Franz Josef Land (northern Barents Sea, Russia): Distribution patterns and environmental control
Evseeva Olga Yu., Dvoretsky Alexander G.
Journal of Marine Systems. 2024 242 p.103944
Skeletal resorption in bryozoans: occurrence, function and recognition
Batson Peter B.,
Tamberg Yuta,
Taylor Paul D.,
Gordon Dennis P., Smith Abigail M.
Biological Reviews. 2020 95(5). p.1341
Growth and Calcification of Marine Bryozoans in a Changing Ocean
Smith Abigail M.
The Biological Bulletin. 2014 226(3). p.203
Sedimentological characteristics of key sea turtle rookeries: potential implications under projected climate change
Fuentes M. M. P. B.,
Dawson J. L.,
Smithers S. G.,
Hamann M., Limpus C. J.
Marine and Freshwater Research. 2010 61(4). p.464
