AUTHOR=Chavan S. B. , Dhillon R. S. , Sirohi Chhavi , Saleh Ibrahim A. , Uthappa A. R. , Keerthika A. , Jinger Dinesh , Halli Hanamant M. , Pradhan Aliza , Kakade Vijaysinha , Morade Amrut , Chichaghare A. R. , Rawale G. B. , Okla Mohammad K. , Alaraidh Ibrahim A. , AbdElgawad Hamada , Fahad Shah , Nandgude Sachin , Singh Rupali 

TITLE=Optimizing planting geometries in eucalyptus-based food production systems for enhanced yield and carbon sequestration

JOURNAL=Frontiers in Sustainable Food Systems

VOLUME=Volume 8 - 2024

YEAR=2024

URL=https://www.frontiersin.org/journals/sustainable-food-systems/articles/10.3389/fsufs.2024.1386035

DOI=10.3389/fsufs.2024.1386035

ISSN=2571-581X

ABSTRACT=<p>The integration of trees into diverse land-use systems holds potential for India to meet nationally determined contribution (NDC) targets under the Paris Climate Agreement. With a target of sequestering 2.5–3 billion tons of CO<sub>2</sub> equivalent by 2030, the study focused on the widespread and economically viable eucalyptus-based agroforestry, practiced widely in various planting geometries tailored to meet industrial end-use requirements. In this context, a detailed study was conducted to quantify the influence of five planting geometries [3 m × 3 m, 6 × 1.5 m, 17 × 1 × 1 m (paired row) and two boundary plantations (east–west and north–south directions) at 2 m away from tree to tree] of eucalyptus on intercrops [dhaincha (<italic>Sesbania aculeata</italic>)—barley (<italic>Hordeum vulgare</italic> L.) rotation] biomass, soil properties, and carbon stock of the system during 2009–2016. Results revealed that biomass accumulation of different tree components was 62.50%–74.09% in stem; 6.59%–9.14% in branch; 3.18%–5.73% in leaves; 12.20%–20.44% in stump roots; and 1.71%–3.48% in fine roots across the planting geometries. The mean carbon content of the stem, branch, leaves, and roots was 49.00, 47.00, 43.00, and 49.00%, respectively. Over the 8-year period, geometry of 3 × 3 m performed better in terms of total biomass production (344.60 Mg ha<sup>− 1</sup> by tree biomass and 62.53 Mg ha<sup>−1</sup> by intercrops). The independent parameter, DBH<sup>2</sup>H (DBH: diameter at breast height and H: tree height), was found to be a very good predictor of dry weight, followed by DBH alone. Among various functions (linear, allometric, logistic, Gompertz, Chapman, and exponential), the best-fit equation was allometric, i.e., B = 300.96 × DBH<sup>2</sup>H<sup>0.93</sup> (adjusted <italic>R</italic><sup>2</sup> = 0.96) for eucalyptus based on universal model adequacy and validation criteria. The carbon sequestration rate was maximum (20.79 Mg C ha<sup>−1</sup> year<sup>−1</sup>) in 3 × 3 m followed by 17 × 1 × 1 m. The total carbon stock of eucalyptus-based system (tree + crop + soil) varied significantly under different planting geometries and sole crop rotation (dhaincha–barley). The higher carbon stock (237.27 Mg ha<sup>−1</sup>) was obtained from 3 × 3 m spacing and further partitioning carbon stock in trees—166.29 Mg ha<sup>−1</sup>, crops—25.01 Mg ha<sup>−1</sup> and soil—45.97 Mg ha<sup>−1</sup>. The paired row spacing (17 × 1 × 1 m) yielded higher crop yield and net returns (Rs. 600,475 ha<sup>−1</sup>), underscoring wide spacing’s role in system productivity and sustainability. Tree-based systems were valuable components of agriculture, advocating for their widespread adoption to reduce CO<sub>2</sub> emissions and generate income through carbon credits. These findings will provide crucial insights into sustainable land-use practices and advance India’s commitment toward adaptation of climate change mitigation strategies.</p>