Stable isotopes track the ecological and biogeochemical legacy of mass mangrove forest dieback in the Gulf of Carpentaria, Australia

Harada, Yota; Connolly, Rod M.; Fry, Brian; Maher, Damien T.; Sippo, James Z.; Jeffrey, Luke C.; Bourke, Adam J.; Lee, Joe

doi:10.5194/bg-2019-468

Cited by 2 publications

(4 citation statements)

References 63 publications

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“…Lower water availability in the dead mangrove forest area was also evident in the lower plant growth rates and higher plant water use efficiency. Mangrove plant isotope data at the same sites from a study by Harada et al (2020) also show a similar trend: more enriched 13 C values in the dead mangrove zone.…”

Section: Evidence Of Differences In Water Availability Between Livingmentioning

confidence: 54%

“…Sippo et al: Reconstructing extreme climatic and geochemical conditions during mangrove dieback coincided with extreme drought and low regional sea levels. This extreme climatic event drove the largest recorded mangrove mortality event (∼ 1000 km coastline, ∼ 7400 ha) attributed to natural causes (Duke et al, 2017;Harris et al, 2017;Sippo et al, 2018) and led to extensive changes in the coastal carbon cycle (Sippo et al, 2019(Sippo et al, , 2020 and coastal food webs (Harada et al, 2020). Two other large-scale mangrove dieback events occurred at the same time: one in Exmouth (Lovelock et al, 2017) and the other in Kakadu National Park, Australia (Asbridge et al, 2019).…”

Section: Introductionmentioning

confidence: 99%

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Reconstructing extreme climatic and geochemical conditions during the largest natural mangrove dieback on record

et al. 2020

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Abstract. A massive mangrove dieback event occurred in 2015–2016 along ∼1000 km of pristine coastline in the Gulf of Carpentaria, Australia. Here, we use sediment and wood chronologies to gain insights into geochemical and climatic changes related to this dieback. The unique combination of low rainfall and low sea level observed during the dieback event had been unprecedented in the preceding 3 decades. A combination of iron (Fe) chronologies in wood and sediment, wood density and estimates of mangrove water use efficiency all imply lower water availability within the dead mangrove forest. Wood and sediment chronologies suggest a rapid, large mobilization of sedimentary Fe, which is consistent with redox transitions promoted by changes in soil moisture content. Elemental analysis of wood cross sections revealed a 30- to 90-fold increase in Fe concentrations in dead mangroves just prior to their mortality. Mangrove wood uptake of Fe during the dieback is consistent with large apparent losses of Fe from sediments, which potentially caused an outwelling of Fe to the ocean. Although Fe toxicity may also have played a role in the dieback, this possibility requires further study. We suggest that differences in wood and sedimentary Fe between living and dead forest areas reflect sediment redox transitions that are, in turn, associated with regional variability in groundwater flows. Overall, our observations provide multiple lines of evidence that the forest dieback was driven by low water availability coinciding with a strong El Niño–Southern Oscillation (ENSO) event and was associated with climate change.

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Section: Evidence Of Differences In Water Availability Between Livingmentioning

confidence: 54%

Section: Introductionmentioning

confidence: 99%

Reconstructing extreme climatic and geochemical conditions during the largest natural mangrove dieback on record

et al. 2020

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“…While we consider the γ-irradiation treatment as a potential reason for these differences, there may be additional secondary factors that can exacerbate these changes, e.g., sample preservationwhere irradiation results in more thorough sterilisation than air drying alone. 27 Bacterial decomposition of analytical samples can lead to stable isotope fractionation and isotopic enrichment in heavier isotopes in both marine producers 28 and decomposing animal tissues. 29 The mechanism underpinning such changes is worthy of further investigation, as it has been shown to affect both nitrogen and carbon to a similar degree (i.e., see changes between fresh and decomposed mangrove leaves 28 ).…”

Section: Discussionmentioning

confidence: 99%

“…27 Bacterial decomposition of analytical samples can lead to stable isotope fractionation and isotopic enrichment in heavier isotopes in both marine producers 28 and decomposing animal tissues. 29 The mechanism underpinning such changes is worthy of further investigation, as it has been shown to affect both nitrogen and carbon to a similar degree (i.e., see changes between fresh and decomposed mangrove leaves 28 ). Nevertheless, γ-irradiation sterilises samples and prevents bacterial decomposition, thereby enhancing preservation of the original stable isotope signature.…”

Section: Discussionmentioning

confidence: 99%

Gamma‐irradiation of common biological samples for stable carbon and nitrogen isotope and elemental analyses

Gorman

Skrzypek

McLaughlin

et al. 2021

Rapid Comm Mass Spectrometry

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Around the world biosecurity measures are being strengthened to prevent the spread of pests and diseases across national and international borders.Quarantine protocols that involve sample sterilisation have potential effects on sample integrity. The consequences of sterilisation methods such as gamma (γ)-irradiation on the elemental and chemical properties of biological samples have not been widely examined.Methods: We tested the effect of γ-irradiation (50 kGy) on the stable carbon and nitrogen isotope compositions (δ 13 C and δ 15 N values) and elemental concentrations (C % and N %) of common biological samples (fish, plants and bulk soils). The analysis used a continuous flow system consisting of a Delta V Plus isotope ratio mass spectrometer connected with a Thermo Flash 1112 elemental analyser via a ConFlo IV interface. Results were compared using two one-sided tests (TOST) to test for statistical similarity between paired samples.Results: There was no change in the δ 15 N values or N % of γ-irradiated samples, and only small changes to the δ 13 C values of consumers (range: 0.01‰ to 0.04‰), producers (À0.02‰ to 0.04‰) and sediments (0‰ to 0.07‰). The magnitude of change in δ 13 C values was greatest at low carbon concentrations but appeared negligible when measured against replicated sample analysis and the combined analytical uncertainty (i.e., 0.10‰). The C % values of irradiated samples were higher for consumers (0.23%) and lower for producers and sediments (0.04% and 0.05%, respectively) which may have implications for certain types of biological material.Conclusions: Routine γ-irradiation has little effect on the stable carbon and nitrogen isotope compositions of common biological samples and marginal effects on carbon elemental concentrations. This is unlikely to warrant concerns since the observed difference is typically of a magnitude lower than other sources of potential uncertainty.

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Stable isotopes track the ecological and biogeochemical legacy of mass mangrove forest dieback in the Gulf of Carpentaria, Australia

Cited by 2 publications

References 63 publications

Reconstructing extreme climatic and geochemical conditions during the largest natural mangrove dieback on record

Reconstructing extreme climatic and geochemical conditions during the largest natural mangrove dieback on record

Gamma‐irradiation of common biological samples for stable carbon and nitrogen isotope and elemental analyses

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