Phytolith Carbon Sequestration in Global Terrestrial Biomes

Overview

Journal Sci Total Environ

Date 2017 Jun 24

PMID 28645048

Citations 13

Authors

Zhaoliang Song

Hongyan Liu

Caroline A E Stromberg

Xiaomin Yang

Xiaodong Zhang

Affiliations

Soon will be listed here.

Abstract

Terrestrial biogeochemical carbon (C) sequestration is coupled with the biogeochemical silicon (Si) cycle through mechanisms such as phytolith C sequestration, but the size and distribution of the phytolith C sink remain unclear. Here, we estimate phytolith C sequestration in global terrestrial biomes. We used biome data including productivity, phytolith and silica contents, and the phytolith stability factor to preliminarily determine the size and distribution of the phytolith C sink in global terrestrial biomes. Total phytolith C sequestration in global terrestrial biomes is 156.7±91.6TgCOyr. Grassland (40%), cropland (35%), and forest (20%) biomes are the dominant producers of phytolith-based carbon; geographically, the main contributors are Asia (31%), Africa (24%), and South America (17%). Practices such as bamboo afforestation/reforestation and grassland recovery for economic and ecological purposes could theoretically double the above phytolith C sink. The potential terrestrial phytolith C sequestration during 2000-2099 under such practices would be 15.7-40.5PgCO, equivalent in magnitude to the C sequestration of oceanic diatoms in sediments and through silicate weathering. Phytolith C sequestration contributes vitally to the global C cycle, hence, it is essential to incorporate plant-soil silica cycling in biogeochemical C cycle models.

Citing Articles

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Production of phytolith and PhytOC and distribution of extractable Si Pools in aerobic rice as influenced by different Si sources.

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Phytolith-Occluded Carbon Sequestration Potential of Oil Palm Plantation in Tamil Nadu.

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Silicon in the Soil-Plant Continuum: Intricate Feedback Mechanisms within Ecosystems.

Katz O, Puppe D, Kaczorek D, Prakash N, Schaller J Plants (Basel). 2021; 10(4).

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