Interplay between Plant Functional Traits and Soil Carbon Sequestration under Ambient and Elevated CO<sub>2</sub> Levels: Fid-Bau Portal

Interplay between Plant Functional Traits and Soil Carbon Sequestration under Ambient and Elevated CO₂ Levels

Siddhartha Shankar Bhattacharyya / Pedro Mondaca / Oloka Shushupti / Sharjeel Ashfaq

Unique plant functional traits (morpho-physio-anatomical) may respond to novel environmental conditions to counterbalance elevated carbon dioxide (eCO₂) concentrations. Utilizing CO₂, plants produce photoassimilates (carbohydrates). A mechanistic understanding of partitioning and translocation of carbon/photoassimilates into different plant parts and soils under ambient and eCO₂ is required. In this study, we examine and present the intrinsic relationship between plant functional traits and eCO₂ and seek answers to (i) how do plant functional traits (morpho-physio-anatomical features) affect C storage and partitioning under ambient and eCO₂ in different plant parts? (ii) How do plant functional traits influence C transfer to the soil and rhizosphere services? Our study suggests that morpho-physio-anatomical features are interlinked, and under eCO₂, plant functional traits influence the quantity of C accumulation inside the plant biomass, its potential translocation to different plant parts, and to the soil. The availability of additional photoassimilates aids in increasing the above- and belowground growth of plants. Moreover, plants may retain a predisposition to build thick leaves due to reduced specific leaf area, thicker palisade tissue, and higher palisade/sponge tissue thickness. eCO₂ and soil-available N can alter root anatomy, the release of metabolites, and root respiration, impacting potential carbon transfer to the soil.