Your search keyword '"nutrient recycling"' showing total 5 results

1. A New Species of the Genus Solva (Diptera: Xylomyidae) and First Report of Solva javana (Meijere, 1907) from the Tropical Forest of Andaman Island.

Author

PRAMANIK, Debdeep, NASKAR, Atanu, and BANERJEE, Dhriti

Subjects

*TROPICAL forests, *DIPTERA, *INSECT anatomy, *SPECIES, *ISLANDS, *HIP joint

Abstract

A new species of wood-soldier fly under the genus Solva Walker, 1859 (Diptera: Xylomyidae) (Solva andamanensis sp. n. Pramanik, Naskar & Banerjee) is described from the tropical forest of Andaman Island, India. Males can be distinguished from other species by a combination of characters, specifically the ochre yellow antenna; snow-white cylindrical palpi; yellow fore coxa, one antero-dorsal bristle in fore femur, black scutellum and black hind coxa. Male terminalia is illustrated here. Furthermore, Solva javana (Meijere, 1907) (Diptera: Xylomyidae) is reported for the first time from Andaman Island as well as India. The difference in habitus characters between these two species is also illustrated in this study. [ABSTRACT FROM AUTHOR]

Published

2024

2. Impact of levels of residue retention on soil properties under conservation agriculture in Vertisols of central India.

Author

Kumawat, Anita, Vishwakarma, A.K., Wanjari, R.H., Sharma, N.K., Yadav, Devideen, Kumar, Dinesh, and Biswas, A.K.

Subjects

*VERTISOLS, *BLACK cotton soil, *SOILS, *NO-tillage, *CROP residues, *CORN, *CHICKPEA, *AGRICULTURAL intensification

Abstract

Residue management is one of the most difficult tasks in the modern-mechanized agriculture with the intensification of cropping systems, which leads to reduced sowing window between two crops and farmers prefer in-situ burning of crop residues. Therefore, the present study was conducted to assess the effect of zero tillage (ZT) based residue management on soil health parameters in maize (Zea mays L.)–chickpea (Cicer arietinum L.) rotation in black soils of central India. After 4 years of study, the soil bulk density was reduced by 3.0–10.2% and volumetric moisture content was improved by 10.2–19.3% at 0–10 cm soil depth in ZT with residue over conventional tillage (CT). The soil organic carbon and labile carbon were increased by 13.6–61.7% and 6.0–22.0%, respectively, at 0–10 cm soil depths. Similarly, ZT with residue increased the KMnO4-N, Olsen-P and NH4OAc-K, and total fungal and actinomycetes density in surface soil as compared to CT. Thus, our study advocates that ZT with residue retention (1.8–5.4 Mg ha–1 maize and 0.8–2.4 Mg ha–1 chickpea residue) should be implemented for sustainable soil health in Vertisols (Typic Haplustert) of central India and other similar agro-ecological systems. [ABSTRACT FROM AUTHOR]

Published

2022

3. Anaerobic digestion as a sustainable technology for efficiently utilizing biomass in the context of carbon neutrality and circular economy.

Author

Subbarao, Paruchuri M.V., D' Silva, Tinku Casper, Adlak, Komalkant, Kumar, Subodh, Chandra, Ram, and Vijay, Virendra Kumar

Subjects

*CIRCULAR economy, *ANAEROBIC digestion, *CROP residues, *CARBON offsetting, *ORGANIC wastes, *RENEWABLE energy sources, *ANIMAL waste

Abstract

Carbon emissions and associated global warming have become a threat to the world, the major contributor being the extensive use of fossil fuels and uncontrolled generation of solid wastes. Energy generation from renewable energy sources is considered an alternative to achieving carbon neutrality. Anaerobic digestion (AD) is a sustainable technology that has been endorsed as a low-carbon technology complimenting both waste management and renewable energy sectors. The AD technology recovers the volatile matter from waste biomass as much as possible to produce biogas, thus reducing carbon emission as compared to open dumping or burning. However, there is a need of compilation of information on how each subsystem in AD contributes to the overall carbon neutrality of the entire system and chances of achieving a circular economy along with it. Therefore, this article aims to clarify the associated internal and external factors that determine the low carbon characteristic of anaerobic digestion technology. From this review, the potential of AD system for energy-atmosphere-agriculture nexus has been explored. Carbon emission mapping of the potential entities involved in AD were identified and perspective to life cycle assessment and future research direction has been pointed out. Climate change impact and acidification potential are the two entities that can influence the overall environmental sustainability of an AD system. It was recognized that each stage of AD system starting from substrate supply chain, biogas production, upgradation, utilization, and digestate application had a remarkable effect on the overall carbon emission potential based on its design, operation, and maintenance. Selection of suitable substrates and co-digesting them together for improved biogas production rate with high methane content and proper digestate post-processing and storage can vastly reduce the carbon emission potential of the AD technology. Further, a case scenario of India was assessed considering the utilization of major surplus biomass available through AD. Re-routing the three major substrates such as agricultural crop residues, animal wastes and organic fraction of municipal solid wastes through AD can reduce at least 3.5–3.8 kg CO 2-eq per capita of annual carbon emission load in India. Furthermore, the pathways in which the policy and legislations over establishment of AD technology and how to explore linkages between achieving circular economy and low carbon economy for Indian scenario has been highlighted. • The carbon recovery potential of anaerobic digestion (AD) technology is reviewed. • The benefits of AD for energy-agriculture-atmosphere nexus are discussed. • Coverage area and digestate handling segments significantly influences the low carbon nature of AD. • With the current research, AD has the potential to reduce up to 4 kg per capita of CO2-eq. • The role of AD for creating a low carbon circular economy model is highlighted. [ABSTRACT FROM AUTHOR]

Published

2023

4. Time‐Continuous Phosphorus Flows in the Indian Agri‐Food Sector: Long‐Term Drivers and Management Options.

Author

Keil, Leonie, Folberth, Christian, Jedelhauser, Michael, and Binder, Claudia R.

Subjects

*PHOSPHATE fertilizers, *AGRICULTURE, *PHOSPHORUS in soils, *FERTILIZER application, *WASTE recycling

Abstract

Summary: Phosphorus (P) is a major agricultural nutrient and, in its mineable form, a potentially scarce resource. Countries with limited physical access to P should hence develop an effective national P governance. This requires analyses of trends and variations in P flows and stocks over time. Here, we present a long‐term P flow analysis for the Indian agri‐food sector from 1988 to 2011. Major P flows are imports of mineral P, fertilizer application, and uptake of animal fodder. The mineral P import dependency ratio is constant at around 93%. On average, 20% of P inputs to soils are lost through erosion. Key drivers of changes in P flows include population growth, dietary change, and agricultural intensification. To reduce its P fertilizer import dependence, India could, for example, substitute up to 19% of the presently applied mineral P if manure used as a household fuel were recycled, and up to 21% if P was fully recovered from wastewater and household waste. Comparing selected indicators for P use in agriculture with China and the European Union (EU) reveals that there are structural similarities, such as increasing fertilizer application rates and P accumulation in soils, with the first but large differences compared to the latter. The analyses highlight that in contrast to static indicators, the time‐continuous tracking of P flows provides substantial advantages, such as the identification of long‐term trends, drivers, and intervention options for sustainable P management, given that it allows for the interpretation of present indicators in the context of past trends and legacies. [ABSTRACT FROM AUTHOR]

Published

2018

5. Exploring the feasibility of thermal digestion process: A novel technique, for the rapid treatment and reuse of solid organic waste as organic fertilizer.

Author

Kumar, Nitin and Gupta, Sunil Kumar

Subjects

*ORGANIC fertilizers, *SOLID waste, *ORGANIC wastes, *SOLID waste management, *RESPONSE surfaces (Statistics), *DIGESTION, *WASTE management, *GERMINATION

Abstract

The study developed a holistic approach based on the thermal digestion (TD) technique for the rapid conversion of solid organic waste (SOW) into nutrient-rich organic fertilizer. The effect of digestion temperatures (110oC–170 °C) on the weight reduction from the SOW and the availability of the nutrients were thoroughly investigated. The potential weight reduction of 75.2% was achieved at a temperature of 150 °C for 135 min, as illustrated by response surface methodology (RSM). Scanning electron microscope (SEM) study was carried out to analyze the changes into surface morphology of the sample before and after the digestion. Fourier transform infrared (FTIR) analysis was conducted to study the mineralization process. Thermogravimetric-Differential thermal analysis (TG-DTA) was conducted to study the thermal decomposition behavior of the untreated and digested SOW. The digested SOW resulted high nutrient-rich end product (N-2.08 ± 0.01%, P-0.42 ± 0.00%, & K-1.65 ± 0.06%), which have potential to be used as organic fertilizer. Fertilizing potential of the digested SOW complied with the delineated norms of the organic fertilizer given by the Fertilizer Association of India (2019). Maturity and phytotoxicity of the digested SOW were explored on the basis of C:N ratio (18.07 ± 0.17), humification index (3.43 ± 0.02), heavy metals content, as well as through seed germination index (>90%). The proposed technology may lead to the paradigm shift in waste management and provides an efficient alternative for the recycling of nutrients. [Display omitted] • A cleaner technology for sustainable management of solid organic waste. • Rapid conversion of solid organic waste into nutrient rich organic fertilizer. • 150 °C was found to be the most optimum temperature for thermal digestion. • Phytotoxin free organic fertilizer suitable for agricultural sustainability. [ABSTRACT FROM AUTHOR]

Published

2021