Fingerprinting macrophyte Blue Carbon by pyrolysis-GC-compound specific isotope analysis (Py-CSIA)

Joeri Kaal; José A González-Pérez; Layla Márquez San Emeterio; Oscar Serrano

doi:10.1016/j.scitotenv.2022.155598

Fingerprinting macrophyte Blue Carbon by pyrolysis-GC-compound specific isotope analysis (Py-CSIA)

Sci Total Environ. 2022 Aug 25:836:155598. doi: 10.1016/j.scitotenv.2022.155598. Epub 2022 Apr 29.

Authors

Joeri Kaal¹, José A González-Pérez², Layla Márquez San Emeterio³, Oscar Serrano⁴

Affiliations

¹ Pyrolyscience, Santiago de Compostela, Spain. Electronic address: joeri@pyrolyscience.com.
² Instituto de Recursos Naturales y Agrobiología de Sevilla, Consejo Superior de Investigaciones Científicas (IRNAS-CSIC), MOSS Group, Seville, Spain.
³ Instituto de Recursos Naturales y Agrobiología de Sevilla, Consejo Superior de Investigaciones Científicas (IRNAS-CSIC), MOSS Group, Seville, Spain; Med_Soil Research Group, University of Seville, Seville, Spain.
⁴ Centro de Estudios Avanzados de Blanes, Consejo Superior de Investigaciones Cientificas (CEAB-CISC), Blanes, Spain; School of Science & Centre for Marine Ecosystems Research, Edith Cowan University, Joondalup, Western Australia, Australia.

PMID: 35500709
DOI: 10.1016/j.scitotenv.2022.155598

Abstract

There is a need for tools to determine the origin of organic matter (OM) in Blue Carbon Ecosystems (BCE) and marine sediments to (1) facilitate the implementation of Blue Carbon strategies into carbon accounting and crediting schemes and (2) decipher changes in ecosystem condition over decadal to millennial time scales and thus to understand and predict the stability of BCE in a changing world. Pyrolysis-GC-compound specific isotope analysis (Py-CSIA) is applied for the first time in marine environments and BCE research. We studied Australian mangrove, tidal marsh and seagrass sediments, in addition to potential sources of OM (Avicennia, Posidonia, Zostera, Sarcocornia, Ecklonia and Ulva species and seagrass epiphytes), to identify precursors of different biomacromolecule constituents (lignin, polysaccharides and aliphatic structures). Firstly, the link between bulk δ¹³C and δ¹³C reconstructed from compound-specific δ¹³C showed that the pyrolysis approach allows for the isotopic screening of a representative portion of the OM. Secondly, for all samples, the C isotope fingerprint of the carbohydrate products (plant polysaccharides) was the heaviest (¹³C enriched), followed by lignin and aliphatic products. The differences in δ¹³C among macromolecules and the overlap in δ¹³C among putative sources reflect the limitations of bulk δ¹³C analyses for deciphering OM provenance. Thirdly, phanerogams specimen had the heaviest carbohydrate and lignin, confirming that seagrass-derived lignocellulose can be traced based on δ¹³C. Consistent differences for individual compounds were identified between seagrasses and between Avicennia and Sarcocornia using Py-CSIA. Fourth, ecosystem shifts (colonization of seagrass habitats by mangrove) on millenary time scales, hypothesized in previous studies on the basis of bulk δ¹³C and Py-GC-MS, were confirmed by Py-CSIA. We conclude that Py-CSIA is useful in Blue Carbon research to decipher OM sources in marine sediments, identify ecosystem transitions in palaeoenvironmental records, and to understand the role of different OM compounds in Blue Carbon storage.

Keywords: Carbon sequestration; Coastal wetland; Mangrove; Organic matter provenance; Seagrass; Tidal marsh.

MeSH terms

Australia
Carbohydrates
Carbon Isotopes / analysis
Carbon* / analysis
Ecosystem*
Isotopes / analysis
Lignin / analysis
Pyrolysis

Substances

Carbohydrates
Carbon Isotopes
Isotopes
Carbon
Lignin