Increase System Productivity Research Articles

Impact of conservation agriculture and weed management on carbon footprint, energy efficiency, and sustainability in maize-wheat cropping systems

This study assesses the impact of conservation agriculture (CA) and weed management practices on the productivity, profitability, energy use, and carbon sustainability of a maize-wheat cropping system. Fifteen treatment combinations, incorporating five tillage methods (conventional-till maize and wheat [CT-CT], conventional-till maize and zero-till wheat [CT-ZT], zero-till maize and zero-till wheat [ZT-ZT], zero-till maize and zero-till plus residue in wheat [ZT-ZTR], and zero-till plus residue maize and wheat [ZTR-ZTR]) and three weed management practices (recommended herbicide [H-H], integrated weed management [IWM-IWM], and hand weeding [HW-HW]), were tested in a strip plot design. The results showed that ZTR-ZTR significantly increased system productivity (6.90 Mg ha−1), net returns, and benefit-cost ratio (BCR; 2.69), compared to CT. However, CT systems had 173 % higher energy use efficiency (EUE) and 170 % higher energy intensity (EI) than CA systems. CA-based treatments used about 15 % direct renewable energy and 85 % indirect renewable energy, while CT systems used 15–20 % direct non-renewable energy and 85–86 % indirect non-renewable energy. Among weed management practices, recommended herbicides (H-H) led to the highest productivity (6.71 Mg ha−1), EUE (9.80), net returns (3003 US$ ha−1), and BCR (3.08), but also higher carbon footprints. This underscores the balance between productivity, energy efficiency, and carbon in agriculture.

Enhancing Manufacturing Excellence with Digital-Twin-Enabled Operational Monitoring and Intelligent Scheduling

This research examines the potential of digital twin (DT) technology for reformation within China’s traditional solid-wood-panel processing industry, which currently suffers from production inefficiencies and the slow adoption of digital technology. The research centers around developing a digital twin system, elucidating improvements in manufacturing efficiency, waste management, process simulation, and real-time monitoring. These capabilities facilitate immediate problem solving and offer transparency in the process. The digital twin system is comprised of physical, transport, virtual, and application layers, employing a MySQL database and using the Open Platform Communications Unified Architecture (OPC UA) protocol for communication. The application of this system has led to heightened production efficiency and better material use in the solid-wood-panel manufacturing line. Integrating the dynamic selection adaptive genetic algorithm (DSAGA) into the virtual layer drives the system’s efficiency forward. This evolved approach has allowed for an enhancement of 8.93% in the scheduling efficiency of DSAGA compared to traditional genetic algorithms (GAs), thereby contributing to increased system productivity. Real-time mapping and an advanced simulation interface have strengthened the system’s monitoring aspect. These additions enrich data visualization, leading to better comprehension and a holistic process view. This research has ignited improvements in solid-wood-panel production, illustrating the tangible benefits and representing progress in incorporating digital technology into traditional industries. This research sets a path for transforming these industries into smart manufacturing by effectively bridging the gap between physical production and digital monitoring. Furthermore, the adjustability of this approach extends beyond solid-wood-panel production, indicating the capability to expedite movement towards intelligent production in various other manufacturing sectors.

Intercropping of Sesame with Mungbean Increased System Productivity and Farm Profit in Coastal Region of Bangladesh

Intercropping of Sesame with Mungbean Increased System Productivity and Farm Profit in Coastal Region of Bangladesh

Relationships Between Plankton Size Spectra, Net Primary Production, and the Biological Carbon Pump

AbstractPhotosynthesis in the surface ocean and subsequent export of a fraction of this fixed carbon leads to carbon dioxide sequestration in the deep ocean. Ecological relationships among plankton functional groups and theoretical relationships between particle size and sinking rate suggest that carbon export from the euphotic zone is more efficient when communities are dominated by large organisms. However, this hypothesis has never been tested against measured size spectra spanning the >5 orders of magnitude found in plankton communities. Using data from five ocean regions (California Current Ecosystem, North Pacific subtropical gyre, Costa Rica Dome, Gulf of Mexico, and Southern Ocean subtropical front), we quantified carbon‐based plankton size spectra from heterotrophic bacteria to metazoan zooplankton (size class cutoffs varied slightly between regions) and their relationship to net primary production and sinking particle flux. Slopes of the normalized biomass size spectra (NBSS) varied from −1.6 to −1.2 (median slope of −1.4 equates to large 1–10 mm organisms having a biomass equal to only 7.6% of the biomass in small 1–10 μm organisms). Net primary production was positively correlated with the NBSS slope, with a particularly strong relationship in the microbial portion of the size spectra. While organic carbon export co‐varied with NBSS slope, we found only weak evidence that export efficiency is related to plankton community size spectra. Multi‐variate statistical analysis suggested that properties of the NBSS added no explanatory power over chlorophyll, primary production, and temperature. Rather, the results suggest that both plankton size spectra and carbon export increase with increasing system productivity.

Alternate tillage and crop-establishment techniques in rice (Oryza sativa)–wheat (Triticum aestivum) system for increased system productivity and profitability in eastern sub-Himalayan plains of India

This study was undertaken from the rainy season 2015 to winter season 2016–17 at the Uttar Banga Krishi Viswavidyalaya, Pundibari, West Bengal. The aim of the study was to arrive at optimal tillage requirement in rice (Oryza sativa L.)–wheat (Triticum aestivum L.) system to economize on energy, labour and time, and to work out the production economics of rice–wheat system as a whole under various crop-establishment techniques. Unpuddled rice (UPTR) followed by zero tillage (ZT) wheat recorded superior yield performances to conventional tillage-based systems over the years. Fuel and labour requirement was reduced by 86.93 and 51.85%, 66.28 and 45.67% and 77.84 and 48.97% under rice (direct seeding)–wheat (surface seeding), rice (UPTR)–wheat (ZT) and rice (bed planting)–wheat (bed planting), respectively. Rice (UPTR)–wheat (ZT) also recorded the maximum energy efficiency (12.15) and energy productivity (0.94 kg/MJ) with lowest specific energy (31.67) which was reflective of the better system output. Despite lesser cost of cultivation under rice (direct seeding)–wheat (surface seeding) system, the monetary returns as well as benefit: cost ratio were much lesser under this system due to poor crop stand owing to high pre-monsoon and monsoon shower. The maximum net returns (`33,888 and `42,835/ha during 2015–16 and 2016–17 respectively) and benefit: cost ratio (1.68 and 1.85 during 2015–16 and 2016–17 respectively) under rice (UPTR)–wheat (ZT) system reflected its superiority to the other establishment techniques.

Productivity variation and stability of intensive forage‐winter wheat cropping systems on the Loess Plateau, China

AbstractIntegrating forage crops into the continuous winter wheat (Triticum aestivum L.) cropping system can be used for increasing rural population income and maintaining grain production on the Loess Plateau. The objective of this study was to comprehensively evaluate economic yield (EYyield), dry matter yield (DMyield), crude protein yield (CPyield), wheat equivalent yield (WEyield), and food equivalent yield (FEUyield) when incorporating annual forages (oat [Avena sativa L.], soybean [Glycine max L.], and vetch [Vicia sativa L.]) into the traditional fallow‐winter wheat system from a 4‐year (2016–2020) experiment on the Loess Plateau of China. Results showed that incorporating annual forages into the continuous wheat system significantly increased system productivity. Among the four growing seasons, average system DMyield values for fallow‐winter wheat (F‐W), oat‐winter wheat (O‐W), soybean‐winter wheat (S‐W), and vetch‐winter wheat (V‐W) were 10348.52, 13854.15, 14679.94, and 12185.29 kg ha−1, respectively. The average wheat EYyield values were 3777.82, 3115.19, 4020.76, and 3180.71 kg ha−1, respectively. The average forage DMyield values were 0.00, 5497.19, 4284.64, and 2817.50 kg ha−1, respectively. The S‐W system had the highest DMyield and CPyield (1350.10 kg ha−1), and also had DMyield with the smallest variation (CV = 15.21%). The O‐W, S‐W, and V‐W systems produced FEUyield values that were 48.67%, 68.46%, and 30.53%, respectively, greater than the F‐W system. When considering market prices and yields, the S‐W system increased wheat gain yield and had the highest WEyield (6607.90 kg ha−1). Therefore, in consideration of forage quality, winter wheat production, and system productivity, we recommend the S‐W system for local farmers on the Loess Plateau.

Plant facilitation improves carbon production efficiency while reducing nitrogen input in semiarid agroecosystem

It is critical to reduce carbon (C) emission and nitrogen (N) input in agroecosystems under a changing climate. If crop diversification is introduced, interspecific plant–plant interactions as an effective pathway may achieve this goal. However, the related process and its mechanism are poorly understood. A two-year field study was conducted to explore the effects of intercropping systems including soybean-maize, soybean- wheat and maize-wheat on the land equivalent ratio (LER), nitrogen use efficiency (NUE), seasonal carbon emission, and soil properties in a typical semiarid environment. Three N rates (N1: 150 kg ha−1, N2: 225 kg ha−1, N3: 300 kg ha−1) were applied. The result indicated that the intercropping with soybean significantly increased system productivity with LER > 1, showing a typical plant–plant facilitation. However, the LER of maize–wheat intercropping was significantly lower than 1, representing interspecific competition. With the increasing N rate, the productivity of monoculture wheat or maize was evidently promoted. Particularly, the productivity under N2 and N3 remained at a similar level due to interspecific facilitation. This trend was mechanically driven by the improved N uptake (NLER > 1) and NUE under the presence of interspecific facilitation. Critically, interspecific facilitation was observed to promote carbon emissions (CE) by 4.0%-6.3%, since root input, microbial activities and the C&N decomposition enzyme activities were significantly enhanced. To say, interspecific facilitation evidently enhanced carbon emission efficiency (Yield/CE) whereas interspecific competition turned to lower it. To sum up, plant facilitation improved crop productivity and carbon emission efficiency by reducing N input. Our findings provided a new insight into the exploration of green solution in terms of reducing emissions and increasing efficiency, as well as lowering N fertilizer application in the natural and agricultural ecosystems.

System-Based Integrated Nutrient Management Improves Productivity, Profitability, Energy Use Efficiency and Soil Quality in Peanut-Wheat Cropping Sequence in Light Black Soils

Peanut (Arachis hypogaea L.), being an energy-rich crop, is sensitive to nutrient deficiencies and a scavenger of nutrients from the soil. Optimum and integrated nutrient management (INM) improves productivity and the quality of seeds. The objective of this study was to identify suitable system-based INM (S-INM) options for peanut–wheat cropping sequence in the Saurashtra region of India. Results showed that peanut growth, yield attributing parameters, pod, and haulm yield, and NPK uptake were higher when 100% recommended fertilizer doses (RDFs) + farmyard manure (FYM) @5 t/ha + plant growth-promoting rhizobacteria (PGPR) were applied. However, application of 75% RDFs + FYM @5 t/ha + PGPR in peanut and 100% RDF in wheat was most effective to improve growth and yield attributes, yields and nutrient uptake by wheat. Further, this FYM- and PGPR-amended treatment was found to increase system productivity by 15.3 and 17.1%, system profitability by 17.0 and 22.6%, and net energy gain by 10.0 and 17.9% over the reference treatment and over farmers’ practice (FF), respectively. This sustainable system approach will be helpful for agronomists and farmers in identifying and practicing suitable field practices with further study on the residual effect of organic manures on the peanut–wheat based cropping system in the western region of India with light black soils.

Development of Potato-Boro-T. Aman Rice Cropping Pattern Against Fallow-Boro-T. Aman Rice Cropping Pattern at Mymensingh

The experiment was conducted at Multiplication Testing Site (MLT) Trishal of On-Farm Research Division, Bangladesh Agricultural Research Institute, Mymensingh during 2017-18 and 2018-19 to evaluate the agro-economic performance of improved cropping pattern for increasing cropping intensity and system productivity as compared to farmers’ existing cropping pattern. The experiment was laid out in randomized complete block design with six dispersed replications. Two cropping patterns viz. improved pattern Potato (BARI Alu- 25)-Boro (BRRI dhan28)-T. Aman rice (BRRI dhan49) and farmers existing cropping pattern Fallow-Boro (BRRI dhan29)- T. Aman rice (BRRI dhan49) were treatments variables of the experiment. Two years mean data showed that Potato-Boro-T. Aman rice cropping pattern produced higher tuber/grain yield as well as higher rice equivalent yield (30.53 t ha-1yr-1), production efficiency (149 kg ha-1 day-1), land utilization index (74 %) and labour employment (367mandays ha-1 yr-1) than Fallow-Boro-T. Aman rice cropping pattern. This pattern also increased system productivity, production efficiency, land utilization index and labour employment by 158, 166, 26 and 51% higher over exiting pattern. The mean gross return (Tk. 481800 ha-1) and gross margin (Tk.235329 ha-1) of improved cropping pattern were 139 and 237% higher, respectively compared to existing pattern with 87% extra cost. The mean marginal benefit cost ratio (2.45) indicated superiority to improved cropping pattern over existing pattern. Experimental findings revealed that there is potential for greater adoption of intensified cropping systems with increased productivity and profitability as compared to rice–rice systems in Mymensingh.
 Bangladesh J. Agril. Res. 45(3): 279-292, September 2020

Superior Haplotypes for Early Root Vigor Traits in Rice Under Dry Direct Seeded Low Nitrogen Condition Through Genome Wide Association Mapping.

Water and land resources have been aggressively exploited in the recent decades to meet the growing demands for food. The changing climate has prompted rice scientists and farmers of the tropics and subtropics to adopt the direct seeded rice (DSR) system. DSR system of rice cultivation significantly reduces freshwater consumption and labor requirements, while increasing system productivity, resource use efficiency, and reducing greenhouse gas emissions. Early root vigor is an essential trait required in an ideal DSR system of rice cultivation to ensure a good crop stand, adequate uptake of water, nutrients and compete with weeds. The aus subpopulation which is adapted for DSR was evaluated to understand the biology of early root growth under limited nitrogen conditions over two seasons under two-time points (14 and 28 days). The correlation study identified a positive association between shoot dry weight and root dry weight. The genome-wide association study was conducted on root traits of 14 and 28 days with 2 million single-nucleotide polymorphisms (SNPs) using an efficient mixed model. QTLs over a significant threshold of p < 0.0001 and a 10% false discovery rate were selected to identify genes involved in root growth related to root architecture and nutrient acquisition from 97 QTLs. Candidate genes under these QTLs were explored. On chromosome 4, around 30 Mbp are two important peptide transporters (PTR5 and PTR6) involved in mobilizing nitrogen in the root during the early vegetative stage. In addition, several P transporters and expansin genes with superior haplotypes are discussed. A novel QTL from 21.12 to 21.46 Mb on chromosome 7 with two linkage disequilibrium (LD) blocks governing root length at 14 days were identified. The QTLs/candidate genes with superior haplotype for early root vigor reported here could be explored further to develop genotypes for DSR conditions.

Modification of Nutrient Requirements for a Four Crop-Based Cropping System to Increase System Productivity, Maintain Soil Fertility, and Achieve Sustainable Intensification

Sustainable and resilient cropping intensity is now a global focus to address the food demand and nutrition security of the growing population. For sustainable intensification, maintaining soil fertility is a key concern. The nutrient management for the recently developed four crop-based cropping system in Bangladesh has not yet been studied. Hence, field experiments were conducted on the nutrient management of the four crop-based cropping system [Aus (pre-monsoon rice), Aman (monsoon rice), lentil, and mungbean] in calcareous soil in Bangladesh during the years of 2016/17 and 2017/18 to determine the appropriate fertilizer management package to improve crop productivity and sustain soil fertility. The experiment had six treatments assigned in a randomized complete block design with three replications. The treatments included T1 = control (without synthetic fertilizer), T2 = 50% recommended dose of fertilizer (RDF), T3 = 75% RDF, T4 = 100% RDF, T5 = 125% RDF, and T6 = farmers’ practice (FP). The results revealed that the 125% RDF significantly contributed to higher yields of all four crops. The rice equivalent yield (REY) was the highest for the fertilizer management of 125% RDF, which was 45.5%, 9.4%, and 12.2% higher than the control (T1), 100% RDF (T4), and FP, respectively. Considering the uptake of nutrients (N, P, K, S, Zn, and B) by the crops in the cropping system, the 125% RDF was superior to the other treatments. The nutrient management practices had a positive influence on the apparent nutrient recovery (ANR) efficiency of the cropping system. The fertilizer management of 125% RDF was also economically more profitable due to the increment in the cost–benefit ratio of 26.8%, 4.4%, and 4.9% over the control, 100% RDF, and FP, respectively. The results indicate that the current fertilizer recommendations and FP for aus, aman, lentil, and mungbean are not adequate for the change from the three crop to the four crop-based pattern, and an increased dose of fertilizer is required to increase the yield of each individual crop as well as the total system’s productivity. The fertilizer use efficiency is also higher for 125% RDF than the 100% RDF and FP indicating that to sustain the soil fertility in the four crop-based system, the current RDF and FP are not sufficient. This finding will help intensive cropping areas in preventing nutrient deficiencies that would lead to a reduction in the crop yield.

Performance evaluation of PCM based solar concentrator type desalination device

Thar desert of Rajasthan is one of the most water-stressed states in India and has limited surface water resources, and available groundwater is brackish water; therefore, it must be distillate or purified. In the present paper, we develop a concentrating solar thermal desalination device. This system was assembled by dish concentrator, vessel, SS-based condensing unit, stand and jar for distillate water. Also, paraffin wax of melting temperature 58–60 °C was used in this study as a phase change material to increase the water temperature and heat the water. A year-round performance analysis was carried out during 2020 at ICAR-Central Arid Zone Research Institute, Jodhpur, India. The maximum productivity with PCM is 7.12 lit day−1, and without PCM is 6.52 lit day−1 during May 2020. The monthly average distillate obtained from the PCM-based desalination unit is 4.51 lit.month−1, and without PCM, the distillate yield is 3.84 lit.month−1.Incorporating paraffin as a PCM to the concentrating desalination system increased system working hours and increased system productivity by about 109%. The maximum average daily efficiency of the parabolic concentrating solar thermal desalination device varied from 13.5 percent in January to 34.8 percent in May. The economic analysis of the concentrating solar thermal desalination device revealed that the high value of the internal rate of return IRR (87.2 percent) and low value of the payback period (1.40 Years) makes the unit very cost-efficient. Therefore, this solar desalination device can be successfully used to desalinate the saline water in rural areas of the Thar desert of Rajasthan to meet the requirement of potable water. This present study contains valuable information, particularly for researchers, industrialists, and investors interested in solar-based water desalination system investment in hot arid areas of India.

Tropical root-and tuber crops-based cropping systems — A review

Multiple cropping is the best way of sustainable intensification of crop production, from the limited resources. More flexibility in planting and harvesting of tropical root and tuber crops provide ample scope for various crop production systems. Intercropping of legumes, cereals, and vegetables in root and tuber crops increased system productivity with land-use efficiency, though yields of sole crop of roots and tubers decreased. Intercropping root and tuber crops in plantation and fruit tree crops gave additional returns. Weed suppression, pest and disease reduction and improvement in soil nutrient status are the additional benefits of root and tuber crops involved in multiple cropping systems. In rice (Oryza sativa L.)-based cropping system in the coastal plains of Odisha, West Bengal, Karnataka, Tamil Nadu and Andhra Pradesh, sweet potato (Ipomoea batatas L. Lam.) is planted after harvesting of rice to take advantage of the residual soil moisture and fertilizers. Multiple cropping also reduces severity of pests and diseases. The climate smart root and tuber crops generate assured income under various cropping systems.

Integrated Nutrient Management Enhances Productivity and Nitrogen Use Efficiency of Crops in Acidic and Charland Soils.

Integrated Plant Nutrient System (IPNS) is practiced worldwide to maintain soil quality. Two field experiments were conducted in 2019 and 2020 in acidic and charland soils to assess the impact of different manures, viz., poultry manure (PM), vermicompost (VC), compost (OF), rice husk biochar (RHB), poultry manure biochar (PMB)-based IPNS, and dolomite over control on productivity and nitrogen use efficiency (NUE) of the Mustard-Boro-Transplanted Aman and Maize-Jute-Transplanted Aman cropping patterns, and on soil properties. The experiments were laid out in a randomized complete block design with four replications. The results showed that IPNS treatments significantly improved soil aggregate properties and total nitrogen in acidic soil, and bulk density in charland soil. In both years, IPNS treatments increased system productivity from 55.4 to 82.8% in acidic soil and from 43.3 to 115.4% in charland soil over that of control. IPNS and dolomite treatments increased nitrogen uptake from 35.5 to 105.7% over that of control and NUE in both soils in 2019 and 2020. PMB- and OF-based INPS treatments exhibited superior performances in both soils, and the impact was more prominent in 2020. Therefore, PMB- and OF-based IPNS can be recommended for maximizing system productivity and NUE with concurrent improvement of physicochemical properties of acidic and charland soils.

Energy budgeting and carbon footprint in long-term integrated nutrient management modules in a cereal- legume (Zea mays – Cicer arietinum) cropping system

Agriculture produces a large amount of greenhouse gases (GHGs), for instance overuse of synthetic fertilizer and pesticides in agriculture may lead to tremendous GHGs emission, which poses a serious threat to sustainability of agriculture, environmental quality and human health. Integrated nutrient management (INM) practices have been advised to farmers with the aim to boost agricultural productivity and soil quality. A long-term fertilizer experiment (LTFE) was undertaken from 2012 to 2020 to evaluate the energy budget, carbon footprint (CF) and economic audit under INM modules in maize–chickpea system over organic and inorganic modules for developing cleaner production technology. In this study, twelve organic, inorganic and INM modules that consisted of various combinations of soil test crop response (STCR) based NPK, general recommended dose (GRD) of NPK and organic manures (OM's) viz., farmyard manure (FYM), poultry manure (PM), urban compost (UC), maize residue mulch (MRM) and Gliricidia sepium mulch (GLM) were evaluated in maize–chickpea system. Uniqueness of this research work is that the effect of INM modules on GHGs emission was evaluated along with crop productivity, energy use efficiency (EUE) and carbon footprint (CF) jointly as environment friendly approach for sustainable and safe food grain production. Adoption of STCR based INM module (FYM+75%NPK of STCR) minimized the energy requirement by 14%, cost of cultivation by 6.5% and besides that CF on a spatial scale was 17% lower than GRD. Thus, STCR based INM module enhanced the EUE, energy productivity (EP) and energy profitability (EPF) by 28.5%, 31.5% and 31.8% respectively, over GRD. The CF (CO2-e) was greater in organic module (FYM 20 Mgha-1 every year) (2422 CO2-e kg ha−1) and GRD (2230 CO2-e kg ha−1) than STCR based INM module (2152 CO2-e kg ha−1). The saving of fossil fuels from judicious use of fertilizers/manures, lower input energy and higher crop yields under INM modules were significant. Nitrous oxide (N2O) emission was also increased by integration of OM's, and the higher quantity of organic inputs used, more was the emission. INM module (FYM+75%NPK of STCR) also increased system productivity by 17.0%, carbon efficiency (CE) by 19.3% and carbon sustainability index (CSI) by 21% than GRD. Thus, the study supports and suggests that the STCR based INM module is an economically viable, environmentally secure and clean production technology for improving crop yield and energy use, while decreasing the CFs and production cost of cereal–legume cropping system.

Conservation agriculture enhances the rice-wheat system of the Eastern Gangetic Plains in some environments, but not in others

• Intensification of the rice-wheat system increased system productivity. • CA further enhanced the baseline system though CA benefits are environment-specific. • In fine-textured soil (silt-loam), CA enhanced system productivity and resource use efficiency. • In course-textured soil (sandy-loam), the system benefit (productivity and resource use efficiency) of full CA seems limited. Increasing productivity of the rice-wheat system (RW) in the Eastern Gangetic Plains (EGP) is a major challenge in the context of the various economic (increasing cost of labour, irrigation water, and energy) and bio-physical (water scarcity, depletion of soil fertility, and climatic variability) constraints. We evaluated the performance of three RW system intensification options with different management interventions over two years, comparing a conventional RW rotation (CS 1 ), with two stages of conservation agriculture (CA) interventions, (i) the simple inclusion of mungbean (CS 2 ), and (ii) the inclusion of mungbean together with full CA implementation (CS 3 ) at two sites in the EGP that differed with respect to soil type, water table dynamics, and agro-climatic conditions. Our evaluation focussed on improving system productivity and resource use efficiency. The addition of mungbean into the conventional RW rotation produced significantly higher system productivity (rice equivalent yield, REY) compared with the existing double-crop rotation across sites. The baseline system was enhanced further when CA-based management practices were adopted, however, the magnitude of system benefit from CA was site and situation-specific. At the fine-textured soil site, gains were observed in system production (by 5.4 %), irrigation water productivity (WP I , by 40 %), and N use efficiency (NUE, by 5%) for the CA-based intensified system (CS 3 ) in comparison with the CT-based intensified system (CS 2 ). The average wheat yield and WP I in the zero-till (ZT) system (CS 3 ) was always higher than in the conventional (CT) systems (CS 1 and CS 2 ), mainly due to enhanced wheat rooting after unpuddled rice across the sites. At the fine-textured soil site, the cessation of puddling in rice cropping maintained rice grain yield, while increasing WP I . However, in the coarse-textured soil site, the cessation of puddling resulted in lower rice grain production (by 14 %), coupled with much higher (1.3 times) irrigation water requirement than the conventional puddled rice systems (CS 1 and CS 2 ) in the second year due to increased percolation rate, which negatively impacted the overall performance of the CA-based system (CS 3 ). Therefore, the modification of the traditional CT-based system to an intensified CA-based approach can improve the productivity of the RW system in terms of yield of the component crops as well as better NUE and WP I in fine-textured soil, while the feasibility of the full CA system in coarse-textured soil seems limited due to poor performance of rice, and requires further research focusing on the best rice establishment option.

Can yield, soil C and aggregation be improved under long-term conservation agriculture in the eastern Indo-Gangetic plain of India?

Deteriorating soil health, diminishing soil organic carbon (SOC), development of subsurface hard compact layer and declining system productivity are barriers to achieving sustainable production in the traditional rice–wheat cropping system (TA) in the eastern Indo‐Gangetic Plain of India. Conservation agriculture (CA), which favours minimum soil disturbance, crop residue retention and crop diversification could be a viable alternative to the TA to address most of those major problems. With that in mind, a long‐term experiment is being implemented at ICAR‐RCER, Patna, Bihar, India, with four treatments: (a) TA, (b) full CA (fCA) and (c and d) partial CA (pCA1 and pCA2), differing in crop establishment methods, cropping system and crop residue management in a randomized complete block design. Measurement of soil health parameters was carried out in the 11th year of the experiment. The results revealed a beneficial effect of CA and 46 and 40% increase in SOC concentration and stock, respectively, under fCA over TA in the 0–7.5‐cm soil layer. The effect of partial CA (pCA1 and pCA2) was variable, but an increasing trend was always observed under pCA compared to TA. There was an enrichment in SOC content of aggregates under CA irrespective of size class; however, no relation was found between SOC content and aggregate diameter. The contribution of macroaggregates to SOC stock was larger (36–66%) under CA in the 0–7.5‐cm soil layer. Adoption of CA improved the macroaggregate content, MWD and GMD of aggregates, and aggregation ratio. Soil macropore content was greater under fCA, whereas other parameters were similar among treatments. The impact of CA was mostly limited to 0–7.5 cm soil layer and a maximum up to 15 cm soil depth while evaluation until 60 cm soil depth was realized. The yield of rice in CA was comparable to or higher than in TA, whereas the system rice equivalent yield was always higher (38–53%) under CA than under the conventional practices. Therefore, a CA‐based cropping system must be encouraged, to increase SOC status, improve aggregation stability and, consequently, sustain or increase system productivity, in order to achieve food and nutritional security in the eastern Indo‐Gangetic Plain of India.Highlights Effects of long‐term conservation agriculture (CA) on soil C, aggregation and yield were evaluated.CA improved SOC concentration and stock by 46 and 40%, as well as macroaggregate SOC stock by 36–66%.Macro‐aggregation and mean weight diameter improved in CA but was mostly limited to a shallow soil depth.CA can be promoted for sustainability of a rice–wheat system due to higher productivity (38–53%).

Portfolios of Climate Smart Agriculture Practices in Smallholder Rice-Wheat System of Eastern Indo-Gangetic Plains—Crop Productivity, Resource Use Efficiency and Environmental Foot Prints

The conventional tillage based rice-wheat system (RWS) in Indo-genetic plains (IGP) of South Asia is facing diverse challenges like increase in production cost and erratic climatic events. This results in stagnated crop productivity and declined farm profitability with increased emission of greenhouse gases. Therefore, 3-year multi-location farmer’s participatory research trial was conducted to assess the impact of crop establishment and residue management techniques on crop productivity, economic profitability and environmental footprints in RWS. The aim of this study was to analyze the effect of combinations of improved agronomic technologies compared to farmer’s practices (FP) on crop productivity, profitability, resource use efficiency and environmental footprints. The experiment had six scenarios that is, S1-Farmer’s practice; Conventional tillage (CT) without residue; S2-CT with residue, S3- Reduced tillage (RT) with residue + Recommended dose of fertilizer (RDF); S4-RT/zero tillage (ZT) with residue + RDF, S5-ZT with residue + RDF + green seeker + tensiometer + information &amp; communication technology + crop insurance and S6- S5 + site specific nutrient management. Climate smart agriculture practices (CSAPs; mean of S4, S5 and S6) increase system productivity and farm profitability by 10.5% and 29.4% (on 3 yrs’ mean basis), whereas, improved farmers practices (mean of S2 and S3) resulted in only 3.2% and 5.3% increments compared to farmer’s practice (S1), respectively. On an average, CSAPs saved 39.3% of irrigation water and enhanced the irrigation and total water productivity by 53.9% and 18.4% than FP, respectively. In all the 3-years, CSAPs with high adaptive measures enhanced the energy-use-efficiency (EUE) and energy productivity (EP) by 43%–54% and 44%–61%, respectively than FP. In our study, global warming potential (GWP), GHG emission due to consumption energy and greenhouse gas intensity were recorded lower by 43%, 56% and 59% in Climate Smart Agriculture (CSA) with high adaptive measures than farmers practices (3652.7 kg CO2 eq. ha−1 yr−1, 722.2 kg CO2 eq. ha−1 yr−1 and 718.7 Mg kg−1 CO2 eq. ha−1 yr−1). The findings of the present study revealed that CSA with adaption of innovative measures (S6) improved 3-year mean system productivity by 10.5%, profitability by 29.4%, water productivity and energy productivity by 18.3% and 48.9%, respectively than FP. Thus, the results of our 3-year farmer’s participatory study suggest that in a RW system, climate smart agriculture practices have better adaptive capacity and could be a feasible option for attaining higher yields, farm profitability, energy-use efficiency and water productivity with sustained/improved environmental quality in smallholder production systems of Eastern IGP of India and other similar agro-ecologies of South Asia. Finally, the adoption of these CSAPs should be promoted in the RW rotation of IGP to ensure food security, restoration of soil health and to mitigate climate change, the key sustainable development goals (SDGs).

Millet-Jute-T. Aman Cropping Pattern for Increasing System Productivity in the Active Brahmaputra-Jamuna Floodplain Chars

Increasing system productivity in a planned way is an important base for attaining food security, where bringing marginal land like Charland under intensive crop cultivation is highly desirable. The field trial was conducted in the Charland of the Jamuna River under Saghataupazilla of Gaibandha during 2017- 18 &amp; 2018-19 to increase the productivity and profitability through the development of three crops-based improved cropping patterns instead of the local practice (double-crop). Three crops based improved cropping pattern namely Millet (BARI Kaon-2)-Jute (O-9897)-T. Aman (Gainja) was compared with the existing cropping pattern of Millet (Local)-Fallow-T. Aman (Gainja). The experiment was laid out in six dispersed replications maintaining RCB design. The introduced improved cropping pattern produced the higher system productivity based on rice equivalent yield, REY (12.95 t ha-1), than the existing cropping pattern (4.20 t ha-1), which is three times higher than the existing pattern. Total field duration and turnaround time were 323 and 42 days, respectively in improved pattern and 215 and 150 days, respectively in the existing pattern, which revealed that 108 days more could be made productive through the introduction of improved cropping pattern. The alternate pattern increased production efficiency and land-use efficiency by 35% and 30%, respectively than that of the existing cropping system. The gross margin was also three times higher in the improved cropping pattern (1, 41,600 Tk ha-1 yr-1) compared to the farmers’ existing cropping pattern (38,350 Tk ha-1 yr-1). The marginal benefit-cost ratio (MBCR) was calculated 2.44 in an improved cropping pattern over the existing cropping pattern. The inclusion of an extra one crop (Jute) in the existing cropping pattern and replacement of the local millet variety by high yielding variety (BARI Kaon-2) could play a significant role to increase the system productivity as well as profitability in the Charland of Saghata, Gaibandha.&#x0D; The Agriculturists 2020; 18(1) 129-136

Effects of Seven Diversified Crop Rotations on Selected Soil Health Indicators and Wheat Productivity

Diversified cropping systems can enhance soil condition and increase system productivity worldwide. To reduce the negative effects that accompany the continuous winter wheat–summer maize (WM) double-cropping in the North China Plain (NCP), diversified crop rotation (DCR) needs to be considered. The objective of this study is to evaluate the effect of DCR on soil health and wheat productivity as compared to a continuous WM double-cropping. A field experiment (37°41′ N, 116°37′ E) was established in the NCP including a traditional WM double-cropping as a baseline. During 2016/2017–2017/2018, the control is winter wheat–summer maize→winter wheat–summer maize (WM→WM) and seven DCRs as follow: fallow→winter wheat–summer maize (F→WM); spring maize→winter wheat–summer maize (Ms→WM); winter wheat→winter wheat–summer maize (W→WM); sweet potato→winter wheat–summer maize (Psw→WM); spring peanut→winter wheat–summer maize (Pns→WM); winter wheat–summer peanut→winter wheat–summer maize (WPn→WM) and potato–silage maize→winter wheat–summer maize (PMl→WM). Our results indicated that DCRs significantly changed certain soil health indicators in 2016/2017 compared with the control, where F→WM rotation significantly decreased soil pH by 2.7%. The DCRs, especial Psw→WM and Pns→WM rotations showed a potential positive effect on soil health indicators at the end of the second year (2017/2018) compared with the control, where sweet potato increased soil organic carbon (SOC), total nitrogen (TN), available phosphorus (AP), urease activity (UA) and alkaline phosphatase activity (APA) in 2017/2018 by 5.1%, 5.3%, 13.8%, 9.4%, and 13.5%, respectively. With the spring peanut, TN, AP, and soil APA were increased by 2.1%, 13.2%, and 7.7%, respectively. Although fertilizer and irrigation input of DCRs were lower than the control, no significant decrease was observed on actual wheat yield as compared to the control (7.79 Mg/ha). The finding of this study highlights the value of DCRs, especially, Psw→WM and Pns→WM rotations over WM double-cropping in the NCP.