Browsing by Author "Connolly, Rod M."
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- Climate effects on belowground tea litter decomposition depend on ecosystem and organic matter types in global wetlands.Publication . Trevathan-Tackett, Stacey M.; Kepfer-Rojas, Sebastian; Malerba, Martino; Macreadie, Peter I.; Djukic, Ika; Zhao, Junbin; Young, Erica B.; York, Paul H.; Yeh, Shin-Cheng; Xiong, Yanmei; Winters, Gidon; Whitlock, Danielle; Weaver, Carolyn A.; Watson, Anne; Visby, Inger; Tylkowski, Jacek; Trethowan, Allison; Tiegs, Scott; Taylor, Ben; Szpikowski, Jozef; Szpikowska, Grażyna; Strickland, Victoria L; Stivrins, Normunds; Sousa, Ana I.; Sinutok, Sutinee; Scheffel, Whitney A.; Sanderman, Jonathan; Sánchez-Carrillo, Salvador; Sanchez-Cabeza, Joan-Albert; Rymer, Krzysztof G.; Ruiz-Fernandez, Ana Carolina; Robroek, Bjorn J. M.; Roberts, Tessa; Ricart, Aurora M.; Reynolds, Laura K.; Rachlewicz, Grzegorz; Prathep, Anchana; Pinsonneault, Andrew J; Pendall, Elise; Payne, Richard; Ozola, Ilze; Onufrock, Cody; Ola, Anne; Oberbauer, Steven F; Numbere, Aroloye O.; Novak, Alyssa B.; Norkko, Joanna; Norkko, Alf; Mozdzer, Thomas J.; Morgan, Pam; Montemayor, Diana I.; Martin, Charles W.; Malone, Sparkle L.; Major, Maciej; Majewski, Mikołaj; Lundquist, Carolyn J.; Lovelock, Catherine E; Liu, Songlin; Lin, Hsing-Juh; Lillebo, Ana; Li, Jinquan; Kominoski, John S.; Khuroo, Anzar Ahmad; Kelleway, Jeffrey J.; Jinks, Kristin I.; Jerónimo, Daniel; Janousek, Christopher; Jackson, Emma L.; Iribarne, Oscar; Hanley, Torrance; Hamid, Maroof; Gupta, Arjun; Guariento, Rafael D.; Grudzinska, Ieva; da Rocha Gripp, Anderson; González Sagrario, María A.; Garrison, Laura M.; Gagnon, Karine; Gacia, Esperança; Fusi, Marco; Farrington, Lachlan; Farmer, Jenny; de Assis Esteves, Francisco; Escapa, Mauricio; Domańska, Monika; Dias, André T. C.; Daffonchio, Daniele; Czyryca, Paweł M.; Connolly, Rod M.; Cobb, Alexander; Chudzińska, Maria; Christiaen, Bart; Chifflard, Peter; Castelar, Sara; Carneiro, Luciana S.; Cardoso-Mohedano, José Gilberto; Camden, Megan; Caliman, Adriano; Bulmer, Richard H.; Bowen, Jennifer; Boström, Christoffer; Bernal, Susana; Berges, John A.; Benavides, Juan C.; Barry, Savanna C.; Alatalo, Juha M.; Al-Haj, Alia N.; Adame, Maria Fernanda; Barrena de los Santos, Carmen; Santos, RuiPatchy global data on belowground litter decomposition dynamics limit our capacity to discern the drivers of carbon preservation and storage across inland and coastal wetlands. We performed a global, multiyear study in over 180 wetlands across 28 countries and 8 macroclimates using standardized litter as measures of "recalcitrant" (rooibos tea) and "labile" (green tea) organic matter (OM) decomposition. Freshwater wetlands and tidal marshes had the highest tea mass remaining, indicating a greater potential for carbon preservation in these ecosystems. Recalcitrant OM decomposition increased with elevated temperatures throughout the decay period, e.g., increase from 10 to 20 °C corresponded to a 1.46-fold increase in the recalcitrant OM decay rate constant. The effect of elevated temperature on labile OM breakdown was ecosystem-dependent, with tidally influenced wetlands showing limited effects of temperature compared with freshwater wetlands. Based on climatic projections, by 2050 wetland decay constants will increase by 1.8% for labile and 3.1% for recalcitrant OM. Our study highlights the potential for reduction in belowground OM in coastal and inland wetlands under increased warming, but the extent and direction of this effect at a large scale is dependent on ecosystem and OM characteristics. Understanding local versus global drivers is necessary to resolve ecosystem influences on carbon preservation in wetlands.
- Climate effects on belowground tea litter decomposition depend on ecosystem and organic matter types in global wetlands.Publication . Trevathan-Tackett, Stacey M.; Kepfer-Rojas, Sebastian; Malerba, Martino; Macreadie, Peter I.; Djukic, Ika; Zhao, Junbin; Young, Erica B.; York, Paul H.; Yeh, Shin-Cheng; Xiong, Yanmei; Winters, Gidon; Whitlock, Danielle; Weaver, Carolyn A.; Watson, Anne; Visby, Inger; Tylkowski, Jacek; Trethowan, Allison; Tiegs, Scott; Taylor, Ben; Szpikowski, Jozef; Szpikowska, Grażyna; Strickland, Victoria L.; Stivrins, Normunds; Sousa, Ana I.; Sinutok, Sutinee; Scheffel, Whitney A.; Santos, Rui; Sanderman, Jonathan; Sánchez-Carrillo, Salvador; Sanchez-Cabeza, Joan-Albert; Rymer, Krzysztof G.; Ruiz-Fernandez, Ana Carolina; Robroek, Bjorn J. M.; Roberts, Tessa; Ricart, Aurora M.; Reynolds, Laura K.; Rachlewicz, Grzegorz; Prathep, Anchana; Pinsonneault, Andrew J.; Pendall, Elise; Payne, Richard; Ozola, Ilze; Onufrock, Cody; Ola, Anne; Oberbauer, Steven F.; Numbere, Aroloye O.; Novak, Alyssa B.; Norkko, Joanna; Norkko, Alf; Mozdzer, Thomas J.; Morgan, Pam; Montemayor, Diana I.; Martin, Charles W.; Malone, Sparkle L.; Major, Maciej; Majewski, Mikołaj; Lundquist, Carolyn J.; Lovelock, Catherine E.; Liu, Songlin; Lin, Hsing-Juh; Lillebo, Ana; Li, Jinquan; Kominoski, John S.; Khuroo, Anzar Ahmad; Kelleway, Jeffrey J.; Jinks, Kristin I.; Jerónimo, Daniel; Janousek, Christopher; Jackson, Emma L.; Iribarne, Oscar; Hanley, Torrance; Hamid, Maroof; Gupta, Arjun; Guariento, Rafael D.; Grudzinska, Ieva; da Rocha Gripp, Anderson; González Sagrario, María A.; Garrison, Laura M.; Gagnon, Karine; Gacia, Esperança; Fusi, Marco; Farrington, Lachlan; Farmer, Jenny; Esteves, Francisco de Assis; Escapa, Mauricio; Domańska, Monika; Dias, André T. C.; Barrena de los Santos, Carmen; Daffonchio, Daniele; Czyryca, Paweł M.; Connolly, Rod M.; Cobb, Alexander; Chudzińska, Maria; Christiaen, Bart; Chifflard, Peter; Castelar, Sara; Carneiro, Luciana S.; Cardoso-Mohedano, José Gilberto; Camden, Megan; Caliman, Adriano; Bulmer, Richard H.; Bowen, Jennifer; Boström, Christoffer; Bernal, Susana; Berges, John A.; Benavides, Juan C.; Barry, Savanna C.; Alatalo, Juha M.; Al-Haj, Alia N.; Adame, Maria FernandaPatchy global data on belowground litter decomposition dynamics limit our capacity to discern the drivers of carbon preservation and storage across inland and coastal wetlands. We performed a global, multiyear study in over 180 wetlands across 28 countries and 8 macroclimates using standardized litter as measures of "recalcitrant" (rooibos tea) and "labile" (green tea) organic matter (OM) decomposition. Freshwater wetlands and tidal marshes had the highest tea mass remaining, indicating a greater potential for carbon preservation in these ecosystems. Recalcitrant OM decomposition increased with elevated temperatures throughout the decay period, e.g., increase from 10 to 20 °C corresponded to a 1.46-fold increase in the recalcitrant OM decay rate constant. The effect of elevated temperature on labile OM breakdown was ecosystem-dependent, with tidally influenced wetlands showing limited effects of temperature compared with freshwater wetlands. Based on climatic projections, by 2050 wetland decay constants will increase by 1.8% for labile and 3.1% for recalcitrant OM. Our study highlights the potential for reduction in belowground OM in coastal and inland wetlands under increased warming, but the extent and direction of this effect at a large scale is dependent on ecosystem and OM characteristics. Understanding local versus global drivers is necessary to resolve ecosystem influences on carbon preservation in wetlands.
- Ecosystem type drives tea litter decomposition and associated prokaryotic microbiome communities in freshwater and coastal wetlands at a continental scalePublication . Trevathan-Tackett, Stacey M.; Kepfer-Rojas, Sebastian; Engelen, Aschwin; York, Paul H.; Ola, Anne; Li, Jinquan; Kelleway, Jeffrey J.; Jinks, Kristin I.; Jackson, Emma L.; Adame, Maria Fernanda; Pendall, Elise; Lovelock, Catherine E.; Connolly, Rod M.; Watson, Anne; Visby, Inger; Trethowan, Allison; Taylor, Ben; Roberts, Tessa N.B.; Petch, Jane; Farrington, Lachlan; Djukic, Ika; Macreadie, Peter I.Wetland ecosystems are critical to the regulation of the global carbon cycle, and there is a high demand for data to improve carbon sequestration and emission models and predictions. Decomposition of plant litter is an important component of ecosystem carbon cycling, yet a lack of knowledge on decay rates in wetlands is an impediment to predicting carbon preservation. Here, we aim to fill this knowledge gap by quantifying the decomposition of standardised green and rooibos tea litter over one year within freshwater and coastal wetland soils across four climates in Australia. We also captured changes in the prokaryotic members of the tea-associated microbiome during this process. Ecosystem type drove differences in tea decay rates and prokaryotic microbiome community composition. Decomposition rates were up to 2-fold higher in mangrove and seagrass soils compared to freshwater wetlands and tidal marshes, in part due to greater leaching-related mass loss. For tidal marshes and freshwater wetlands, the warmer climates had 7-16% less mass remaining compared to temperate climates after a year of decomposition. The prokaryotic microbiome community composition was significantly different between substrate types and sampling times within and across ecosystem types. Microbial indicator analyses suggested putative metabolic pathways common across ecosystems were used to breakdown the tea litter, including increased presence of putative methylotrophs and sulphur oxidisers linked to the introduction of oxygen by root in-growth over the incubation period. Structural equation modelling analyses further highlighted the importance of incubation time on tea decomposition and prokaryotic microbiome community succession, particularly for rooibos tea that experienced a greater proportion of mass loss between three and twelve months compared to green tea. These results provide insights into ecosystem-level attributes that affect both the abiotic and biotic controls of belowground wetland carbon turnover at a continental scale, while also highlighting new decay dynamics for tea litter decomposing under longer incubations.
- The future of Blue Carbon sciencePublication . Macreadie, Peter I.; Anton, Andrea; Raven, John A.; Beaumont, Nicola; Connolly, Rod M.; Friess, Daniel A.; Kelleway, Jeffrey J.; Kennedy, Hilary; Kuwae, Tomohiro; Lavery, Paul S.; Lovelock, Catherine E.; Smale, Dan A.; Apostolaki, Eugenia T.; Atwood, Trisha B.; Baldock, Jeff; Bianchi, Thomas S.; Chmura, Gail L.; Eyre, Bradley D.; Fourqurean, James W.; Hall-Spencer, Jason; Huxham, Mark; Hendriks, Iris; Krause-Jensen, Dorte; Laffoley, Dan; Luisetti, Tiziana; Marbà, Núria; Masque, Pere; McGlathery, Karen J.; Megonigal, J. Patrick; Murdiyarso, Daniel; Russell, Bayden D.; Santos, Rui; Serrano, Oscar; Silliman, Brian R.; Watanabe, Kenta; Duarte, Carlos M.The term Blue Carbon (BC) was first coined a decade ago to describe the disproportionately large contribution of coastal vegetated ecosystems to global carbon sequestration. The role of BC in climate change mitigation and adaptation has now reached international prominence. To help prioritise future research, we assembled leading experts in the field to agree upon the top-ten pending questions in BC science. Understanding how climate change affects carbon accumulation in mature BC ecosystems and during their restoration was a high priority. Controversial questions included the role of carbonate and macroalgae in BC cycling, and the degree to which greenhouse gases are released following disturbance of BC ecosystems. Scientists seek improved precision of the extent of BC ecosystems; techniques to determine BC provenance; understanding of the factors that influence sequestration in BC ecosystems, with the corresponding value of BC; and the management actions that are effective in enhancing this value. Overall this overview provides a comprehensive road map for the coming decades on future research in BC science.