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The importance of the terrestrial weathering feedback for multimillennial coral reef habitat recovery (2012)

Katrin J. Meissner, Ben I. McNeil, Michael Eby and Edward C. Wiebe

Wiley

In: Global Biogeochemical Cycles

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Publication Date: 2012-08-23

Description: Modern-day coral reefs have well defined environmental envelopes for light, sea surface temperature (SST) and seawater aragonite saturation state (Ωarag). We examine the changes in global coral reef habitat on multimillennial timescales with regard to SST and Ωarag using a climate model including a three-dimensional ocean general circulation model, a fully coupled carbon cycle, and six different parameterizations for continental weathering (the UVic Earth System Climate Model). The model is forced with emission scenarios ranging from 1,000 Pg C to 5,000 Pg C total emissions. We find that the long-term climate change response is independent of the rate at which CO2 is emitted over the next few centuries. On millennial timescales, the weathering feedback introduces a significant uncertainty even for low emission scenarios. Weathering parameterizations based on atmospheric CO2 only display a different transient response than weathering parameterizations that are dependent on temperature. Although environmental conditions for SST and Ωarag stay globally hostile for coral reefs for millennia for our high emission scenarios, some weathering parameterizations induce a near-complete recovery of coral reef habitat to current conditions after 10,000 years, while others result in a collapse of coral reef habitat throughout our simulations. We find that the multimillennial response in sea surface temperature (SST) substantially lags the aragonite saturation recovery in all configurations. This implies that if corals can naturally adapt over millennia by selecting thermally tolerant species to match warmer ocean temperatures, prospects for long-term recovery of coral reefs are better since Ωarag recovers more quickly than SST.

Print ISSN: 0886-6236

Electronic ISSN: 1944-9224

Topics: Biology , Chemistry and Pharmacology , Geography , Geosciences , Physics

Published by Wiley on behalf of American Geophysical Union (AGU).

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Structure and Variability of the Antilles Current at 26.5°N (2019)

Christopher S. Meinen, William E. Johns, Ben I. Moat, Ryan H. Smith, Elizabeth M. Johns, Darren Rayner, Eleanor Frajka‐Williams, Rigoberto F. Garcia, Silvia L. Garzoli

Wiley

In: Journal of Geophysical Research: Oceans

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Publication Date: 2019

Description: Abstract Observations from five different systems provide a robust picture of the structure and variability of the Antilles Current, an important contributor to the oceanic flux budget, at 26.5°N during 2005–2015. The analysis includes three direct measurement technologies (current meters, shipboard acoustic Doppler current profilers, and lowered acoustic Doppler current profilers) and two geostrophy‐based measurement technologies (conductivity‐temperature‐depth profilers and pressure‐equipped inverted echo sounders). The direct systems are shown to produce weaker, and less variable, Antilles Current transport estimates than the geostrophy‐based systems. The record‐length‐mean geostrophic estimate for the Antilles Current is 4.7 Sverdrups (Sv; 1 Sv = 106 m3/s), and the daily temporal standard deviation is 7.5 Sv. The variations of the Antilles Current transport exceed those of the entire basin‐wide meridional overturning circulation, illustrating the impact of this unusual current. Seasonal variability shows a maximum northward transport in August–September; however, the seasonal component of the variability is weak, and aliasing of higher frequencies is still a problem even with 10.5 years of data. The dominant time scales of variability in the spectra are at 70 and 180 days, and there is indication of westward propagation of Rossby Wave‐like features into the region at a speed of 9 cm/s. There is no significant correlation between the Antilles Current transport variations and those of the Florida Current at 27°N, in phase or at lags/leads of up to 5 years, likely reflecting the varying coastal wave/wall jet time scales for information to pass from the basin interior through the Bahamas Islands.

Print ISSN: 2169-9275

Electronic ISSN: 2169-9291

Topics: Geosciences , Physics

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Impacts of ocean acidification in naturally variable coral reef flat ecosystems (2012)

Emily C. Shaw, Ben I. McNeil and Bronte Tilbrook

Wiley

In: Journal of Geophysical Research JGR - Oceans

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Publication Date: 2012-03-28

Description: Ocean acidification leads to changes in marine carbonate chemistry that are predicted to cause a decline in future coral reef calcification. Several laboratory and mesocosm experiments have described calcification responses of species and communities to increasing CO2. The few in situ studies on natural coral reefs that have been carried out to date have shown a direct relationship between aragonite saturation state (Ωarag) and net community calcification (Gnet). However, these studies have been performed over a limited range of Ωarag values, where extrapolation outside the observational range is required to predict future changes in coral reef calcification. We measured extreme diurnal variability in carbonate chemistry within a reef flat in the southern Great Barrier Reef, Australia. Ωarag varied between 1.1 and 6.5, thus exceeding the magnitude of change expected this century in open ocean subtropical/tropical waters. The observed variability comes about through biological activity on the reef, where changes to the carbonate chemistry are enhanced at low tide when reef flat waters are isolated from open ocean water. We define a relationship between net community calcification and Ωarag, using our in situ measurements. We find net community calcification to be linearly related to Ωarag, while temperature and nutrients had no significant effect on Gnet. Using our relationship between Gnet and Ωarag, we predict that net community calcification will decline by 55% of its preindustrial value by the end of the century. It is not known at this stage whether exposure to large variability in carbonate chemistry will make reef flat organisms more or less vulnerable to the non-calcifying physiological effects of increasing ocean CO2 and future laboratory studies will need to incorporate this natural variability to address this question.

Print ISSN: 0148-0227

Topics: Geosciences , Physics

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Anthropogenic changes to seawater buffer capacity combined with natural reef metabolism induce extreme future coral reef CO2 conditions (2013)

Emily C. Shaw, Ben I. McNeil, Bronte Tilbrook, Richard Matear, Michael L. Bates

Wiley

In: Global Change Biology

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Publication Date: 2013-01-29

Description: Ocean acidification, via an anthropogenic increase in seawater carbon dioxide (CO 2 ), is potentially a major threat to coral reefs and other marine ecosystems. However, our understanding of how natural short-term diurnal CO 2 variability in coral reefs influences longer-term anthropogenic ocean acidification is unclear. Here we combine observed natural carbonate chemistry variability with future carbonate chemistry predictions for a coral reef flat in the Great Barrier Reef based on the RCP8.5 CO 2 emissions scenario. Rather than observing a linear increase in reef flat partial pressure of CO 2 ( p CO 2 ) in concert with rising atmospheric concentrations, the inclusion of in situ diurnal variability results in a highly non-linear 3-fold amplification of the p CO 2 signal by the end of the century. This significant non-linear amplification of diurnal p CO 2 variability occurs as a result of combining natural diurnal biological CO 2 metabolism with long-term decreases in seawater buffer capacity, which occurs via increasing anthropogenic CO 2 absorption by the ocean. Under the same benthic community composition, the amplification in the variability of p CO 2 is likely to lead to exposure to mean maximum daily p CO 2 levels of ~2100 μatm, with corrosive conditions with respect to aragonite by end-century at our study site. Minimum p CO 2 levels will become lower relative to the mean offshore value (~3-fold increase in the difference between offshore and minimum reef flat p CO 2 ) by end-century, leading to a further increase in the p CO 2 range that organisms are exposed to. The biological consequences of short-term exposure to these extreme CO 2 conditions, coupled with elevated long-term mean CO 2 conditions are currently unknown and future laboratory experiments will need to incorporate natural variability to test this. The amplification of p CO 2 that we describe here is not unique to our study location, but will occur in all shallow coastal environments where high biological productivity drives large natural variability in carbonate chemistry. © 2013 Blackwell Publishing Ltd

Print ISSN: 1354-1013

Electronic ISSN: 1365-2486

Topics: Biology , Energy, Environment Protection, Nuclear Power Engineering , Geography

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A new constraint on global air-sea CO2 fluxes using bottle carbon data (2013)

Tristan P. Sasse, Ben I. McNeil, Gab Abramowitz

Wiley

In: Geophysical Research Letters

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Publication Date: 2013-03-14

Description: [1] We develop a new observationally-derived monthly surface-ocean climatology for the partial pressure of CO 2 ( p CO 2 ) that allows an independent data-based constraint on contemporary air-sea CO 2 fluxes. Our approach uses a neural network, trained on ~17,800 bottle-derived measurements of p CO 2 , to diagnose monthly p CO 2 levels from standard ocean hydrographic data. Although the pattern of contemporary air-sea CO 2 fluxes are generally consistent with the independent underway p CO 2 data network, we find a strong shift in the magnitude of oceanic sources and sinks of CO 2 . In particular, we find a contemporary Southern Hemisphere ocean CO 2 uptake of 0.93 PgC/yr, driven by a prominent CO 2 sink in the sub-polar region (25°-60°S), that is five times the magnitude of the Northern Hemisphere oceanic sink (0.18 PgC/yr). Globally, our results suggest a net open-ocean CO 2 sink of 1.55 ± 0.32 PgC/yr for the nominal year of 2000.

Print ISSN: 0094-8276

Electronic ISSN: 1944-8007

Topics: Geosciences , Physics

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The role of CO2 variability and exposure time for biological impacts of ocean acidification (2013)

Emily C. Shaw, Philip L. Munday, Ben I. McNeil

Wiley

In: Geophysical Research Letters

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Publication Date: 2013-08-20

Description: [1] Biological impacts of ocean acidification have mostly been studied using future levels of CO 2 without consideration of natural variability or how this modulates both duration and magnitude of CO 2 exposure. Here we combine results from laboratory studies on coral reef fish with diurnal in situ CO 2 data from a shallow coral reef, to demonstrate how natural variability alters exposure times for marine organisms under increasingly high-CO 2 conditions. Large in situ CO 2 variability already results in exposure of coral reef fish to short-term CO 2 levels higher than laboratory-derived critical CO 2 levels (~600 µatm). However, we suggest the in situ exposure time is presently insufficient to induce negative effects observed in laboratory studies. Our results suggest that both exposure time and the magnitude of CO 2 levels will be important in determining the response of organisms to future ocean acidification, where both will increase markedly with future increases in CO 2 .

Print ISSN: 0094-8276

Electronic ISSN: 1944-8007

Topics: Geosciences , Physics

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Geological and Chemical Factors that Impacted the Biological Utilization of Cobalt in the Archean Eon (2018)

Eli K. Moore, Jihua Hao, Anirudh Prabhu, Hao Zhong, Ben I. Jelen, Mike Meyer, Robert M. Hazen, Paul G. Falkowski

Wiley

In: Journal of Geophysical Research JGR - Biogeosciences

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Publication Date: 2018-01-09

Description: The geosphere and biosphere coevolved and influenced Earth's biological and mineralogical diversity. Changing redox conditions influenced the availability of different transition metals, which are essential components in the active sites of oxidoreductases, proteins that catalyze electron transfer reactions across the tree of life. Despite its relatively low abundance in the environment, cobalt (Co) is a unique metal in biology due to its importance to a wide range of organisms as the metal center of vitamin B 12 (a.k.a. cobalamin, Cbl). Cbl is vital to multiple methyltransferase enzymes involved in energetically favorable metabolic pathways. It is unclear how Co availability is linked to mineral evolution and weathering processes. Here we examine important biological functions of Co, as well as chemical and geological factors that may have influenced the utilization of Co early in the evolution of life. Only 66 natural minerals are known to contain Co as an essential element. However, Co is incorporated as a minor element in abundant rock-forming minerals, potentially representing a reliable source of Co as a trace element in marine systems due to weathering processes. We developed a mineral weathering model that indicates dissolved Co was potentially more bioavailable in the Archean ocean under low S conditions than it is today. Mineral weathering, redox chemistry, Co complexation with nitrogen-containing organics, and hydrothermal environments were crucial in the incorporation of Co in primitive metabolic pathways. These chemical and geological characteristics of Co can inform the biological utilization of other trace metals in early forms of life.

Print ISSN: 0148-0227

Topics: Biology , Geosciences

Published by Wiley on behalf of American Geophysical Union (AGU).

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