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Energy budgeting and carbon footprints of zero-tilled pigeonpea–wheat cropping system under sole or dual crop basis residue mulching and Zn-fertilization in a semi-arid agro-ecology

Author

Listed:
  • Kumar, Adarsh
  • Rana, K.S.
  • Choudhary, Anil K.
  • Bana, R.S.
  • Sharma, V.K.
  • Prasad, Shiv
  • Gupta, Gaurendra
  • Choudhary, Mukesh
  • Pradhan, Amaresh
  • Rajpoot, Sudhir K.
  • Kumar, Abhishek
  • Kumar, Amit
  • Tyagi, Vishal

Abstract

Conventional agriculture is energy and carbon intensive. Single and double-crop basis residue-mulching in zero-tilled crop-sequences may minimize carbon-footprint with improved crop and energy productivity in water-scarce ecologies. Zn-fertilization is also vital for drought-stress tolerance besides enhanced productivity and quality in Zn-deficient arid-soils. Hence, we compared the single and double-crop basis residue-mulching alongwith Hydrogel and Zn-fertilization in zero-tilled pigeonpea-wheat system. Results showed that double-crop residue-mulching + Hydrogel exhibited ∼22.3 and 17.1% higher system-productivity over no-residue and single-crop residue-mulching plots while maintaining higher net-returns (1315 US$/ha). Crop-residue covering consumed considerable energy (77.3–89.1% of total consumption) and carbon (5–10 folds). Thick residue-cover (8 t/ha/year) under double-crop residue-mulching + Hydrogel exhibited significantly higher energy-output (238,328 MJ ha−1), energy-intensiveness (107.3 MJ/US$) and specific energy (20.15 MJ kg−1) compared to single-crop residue-mulching; whereas energy-use efficiency, energy productivity and profitability were higher under no-residue cover. Zn-fertilization (5 kg ha−1) alongwith Zn-solubilizer in both crops also enhanced the biomass and energy productivity over sole-Zn or no-Zn. Interestingly, carbon footprints increased with residue-covering (4–8 t/ha/year) while least under no-residues. Therefore, farmers should preserve a balance while mulching the residues in single or both crops besides necessitating Zn-fertilization in Zn-deficient arid and semi-arid regions where livestock equally competes for residues as quality fodder.

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  • Kumar, Adarsh & Rana, K.S. & Choudhary, Anil K. & Bana, R.S. & Sharma, V.K. & Prasad, Shiv & Gupta, Gaurendra & Choudhary, Mukesh & Pradhan, Amaresh & Rajpoot, Sudhir K. & Kumar, Abhishek & Kumar, Ami, 2021. "Energy budgeting and carbon footprints of zero-tilled pigeonpea–wheat cropping system under sole or dual crop basis residue mulching and Zn-fertilization in a semi-arid agro-ecology," Energy, Elsevier, vol. 231(C).
    • Handle: RePEc:eee:energy:v:231:y:2021:i:c:s0360544221011105
    DOI: 10.1016/j.energy.2021.120862
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    1. Kariyaiah Basavalingaiah & Y. M. Ramesha & Venkatesh Paramesh & G. A. Rajanna & Shankar Lal Jat & Shiva Dhar Misra & Ashok Kumar Gaddi & H. C. Girisha & G. S. Yogesh & S. Raveesha & T. K. Roopa & K. S, 2020. "Energy Budgeting, Data Envelopment Analysis and Greenhouse Gas Emission from Rice Production System: A Case Study from Puddled Transplanted Rice and Direct-Seeded Rice System of Karnataka, India," Sustainability, MDPI, vol. 12(16), pages 1-24, August.
    2. Saad, A.A. & Das, T.K. & Rana, D.S. & Sharma, A.R. & Bhattacharyya, Ranjan & Lal, Krishan, 2016. "Energy auditing of a maize–wheat–greengram cropping system under conventional and conservation agriculture in irrigated north-western Indo-Gangetic Plains," Energy, Elsevier, vol. 116(P1), pages 293-305.
    3. Chaudhary, V.P. & Gangwar, B. & Pandey, D.K. & Gangwar, K.S., 2009. "Energy auditing of diversified rice–wheat cropping systems in Indo-gangetic plains," Energy, Elsevier, vol. 34(9), pages 1091-1096.
    4. Choudhary, Mukesh & Rana, K.S. & Bana, R.S. & Ghasal, P.C. & Choudhary, G.L. & Jakhar, Praveen & Verma, R.K., 2017. "Energy budgeting and carbon footprint of pearl millet – mustard cropping system under conventional and conservation agriculture in rainfed semi-arid agro-ecosystem," Energy, Elsevier, vol. 141(C), pages 1052-1058.
    5. Yilmaz, Ibrahim & Akcaoz, Handan & Ozkan, Burhan, 2005. "An analysis of energy use and input costs for cotton production in Turkey," Renewable Energy, Elsevier, vol. 30(2), pages 145-155.
    6. Haina Wang & Yingsheng Yang & Xiaoyi Zhang & Guangdong Tian, 2015. "Carbon Footprint Analysis for Mechanization of Maize Production Based on Life Cycle Assessment: A Case Study in Jilin Province, China," Sustainability, MDPI, vol. 7(11), pages 1-13, November.
    7. Ozkan, Burhan & Akcaoz, Handan & Fert, Cemal, 2004. "Energy input–output analysis in Turkish agriculture," Renewable Energy, Elsevier, vol. 29(1), pages 39-51.
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    1. Gurdeep Singh Malhi & M. C. Rana & Suresh Kumar & Muhammad Ishaq Asif Rehmani & Abeer Hashem & Elsayed Fathi Abd_Allah, 2021. "Efficacy, Energy Budgeting, and Carbon Footprints of Weed Management in Blackgram ( Vigna mungo L.)," Sustainability, MDPI, vol. 13(23), pages 1-17, November.
    2. Singh, Ranbir & Singh, Ajay & Sheoran, Parvender & Fagodiya, R.K. & Rai, Arvind Kumar & Chandra, Priyanka & Rani, Sonia & Yadav, Rajender Kumar & Sharma, P.C., 2022. "Energy efficiency and carbon footprints of rice-wheat system under long-term tillage and residue management practices in western Indo-Gangetic Plains in India," Energy, Elsevier, vol. 244(PA).
    3. Kumar, Ashok & Singh, Dilip & Mahapatra, S.K., 2022. "Energy and carbon budgeting of the pearl millet-wheat cropping system for environmentally sustainable agricultural land use planning in the rainfed semi-arid agro-ecosystem of Aravalli foothills," Energy, Elsevier, vol. 246(C).

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