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Review

Surface Seeding of Wheat: A Sustainable Way towards Climate Resilience Agriculture

by
Satish Kumar Singh
1,†,
Abhik Patra
1,2,†,
Ramesh Chand
3,
Hanuman Singh Jatav
4,*,
Yang Luo
5,*,
Vishnu D. Rajput
6,
Shafaque Sehar
7,
Sanjay Kumar Attar
8,
Mudasser Ahmed Khan
9,
Surendra Singh Jatav
1,
Tatiana Minkina
6 and
Muhammad Faheem Adil
7
1
Department of Soil Science and Agricultural Chemistry, Institute of Agricultural Sciences, Banaras Hindu University, Varanasi 221005, Uttar Pradesh, India
2
Krishi Vigyan Kendra, Narkatiaganj 845455, West Champaran, India
3
Department of Plant Pathology, Institute of Agricultural Sciences, Banaras Hindu University, Varanasi 221005, Uttar Pradesh, India
4
Department of Soil Science and Agriculture Chemistry, Sri Karan Narendra Agriculture University-Jobner, Jobner 303329, Rajasthan, India
5
Empa, Swiss Federal Laboratories for Materials Science and Technology, ETH Domain, 8600 Dübendorf, Switzerland
6
Academy of Biology and Biotechnology, Southern Federal University, 344090 Rostov-on-Don, Russia
7
Zhejiang Key Laboratory of Crop Germplasm Resource, Department of Agronomy, College of Agriculture and Biotechnology, Zhejiang University, Hangzhou 310058, China
8
Department of Horticulture, Sri Karan Narendra Agriculture University-Jobner, Jobner 303329, Rajasthan, India
9
Department of Plant Pathology, Sri Karan Narendra Agriculture University-Jobner, Jobner 303329, Rajasthan, India
*
Authors to whom correspondence should be addressed.
These authors contributed equally to this work.
Sustainability 2022, 14(12), 7460; https://doi.org/10.3390/su14127460
Submission received: 10 May 2022 / Revised: 14 June 2022 / Accepted: 16 June 2022 / Published: 18 June 2022
(This article belongs to the Special Issue Agrifood Production and Conservation Agriculture)
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Abstract

:
Conventional tillage (CT)-based agriculture is known to be ecologically indiscreet, economically and environmentally unsustainable, and leads to the degradation of soil and the environment in the Indo-Gangetic Plain (IGP). The surface seeding (SS) method was introduced to manage agro-ecosystems for sustaining productivity and increasing farmers’ profits, while sustaining the natural resources. Here, we conducted a systematic literature review on SS of wheat reported in the IGP, with the aim to cover the concept of SS, its impact on wheat yield, soil properties, and the environment, with the potential benefits and constraints. The major findings are: (i) an SS-based rice–wheat system improves productivity (∼10%) and profitability (20–30%),while employing a lesser amount of irrigation water (15–30%) and energy input (20–25%) compared to a conventional system; (ii) an SS-based system is more adaptive to extreme climatic conditions, reduces the carbon footprint, and increases crop production; (iii) an SS approach enhances soil health by virtue of increased soil organic carbon and improved soil aggregation, as well as soil, water, and energy conservation; (iv) SS consisting of no-tillage with substantial crop residue retention offers an alternative to crop residue burning. Strong policies/legislation are required to encourage SS of wheat, in order to limit residue burning, and provide farmers with carbon credits in exchange for carbon sequestration and reduced greenhouse gas emissions.

1. Introduction

To address the global food exigency, enhanced agricultural production systems must be exercised via the adoption of technology that is economically viable and socially acceptable by 2050. It is likely that the food scarcity problem will be aggravated, due to the rapid degradation of the environment, and substandard options for cropping. Extreme climatic events deteriorate productive capacity, pushing towards greater instability in agricultural production systems (i.e., crop, livestock, fisheries, and forestry). In most of the cultivated soil in India, the soil organic carbon concentration (SOC) is <5 g kg−1, whereas in uncultivated virgin soils it ranges between 15 to 20 g kg−1 [1]. The probable cause of the decline in SOC and soil degradation in cultivated soils is faulty agricultural practices, i.e., excessive soil tillage, intensive mono-cropping systems, and the burning of crop debris [2]. Inadvertently, the fertilizer response ratio dropped from ∼14 during the 1970s Green Revolution to only ∼4 in 2010 [3]. In any government, producing ample food for the growing population, without compromising the soil health and environment, takes precedence over all other policies [4]. Soil degradation adversely affects the processes of food production, which materializes through the interaction of certain biological and physico–chemical properties of the soil. For that reason, a fresh stance is needed apropos of resource management, contingent on local pedoclimatic conditions, not merely to execute the benefits of improved germplasm, but also to counteract the crop yield barriers. To date, zero till is considered as the most fructifying technology for resource conservation in the rice–wheat (RW) systems of the IGP.
Even though the productivity of cereals, such as rice (Oryza sativa), wheat (Triticum aestivum), and maize (Zea mays L.), increased with time, the quantum of increment declined. The underlying culprit is the deterioration of natural resources caused by unscientific methods of resource management, and intensive tillage-based exploitative farming [2]. Rice and wheat are regarded as the basic pillars of the human diet, and millions of south Asian people rely on the RW cropping system for their livelihood, which is currently being practiced over 13.5 million ha [5]. The Green Revolution triggered a quantum increase in the productivity of RW systems, through the introduction of the seeds of high-yielding varieties, irrigation, fertilizer, and a conducive policy environment. In spite of that, recent studies reveal stagnation in productivity growth [6], and long-term experiments validate the latent/quiescent crop yield trends [5]. Soil quality is strictly governed by the tillage practices that negatively affect physical–hydrological soil parameters that are crucial for wheat and rice cultivation [5,7]. The existing policies encourage inappropriate use of land and input [8]; meanwhile, current crop establishment methods result in a decline in fertilizer response ratios. Resource-conserving, production-cost-minimizing, and productivity-maximizing agricultural technologies that actively sustain a healthy environment are, therefore, becoming imperative [9].
Surface seeding (SS) of wheat is one such kind of technology that has the potential to improve crop productivity on a sustainable basis, without causing environmental damage. Compared to existing crop establishment methods, it has certain benefits with respect to crop productivity, soil health, environment, and socio-economic issues (shown in Figure 1), which recuperate the degraded RW cropping system. SS is an alternative planting technique, through which wheat seeds are manually broadcast in a wet field, before or after the rice harvest [10]. It is a simple technology for resource-poor farmers that requires zero capital for machinery or land preparation; still, its use is largely limited to marshy low-lying fields of the eastern IGP where tractors cannot gain access. SS, as applied to the RW systems, has three distinctive features that make it stand out from the rest [11]; first, SS is applied mostly for sowing wheat crop in a double-cropped system, with the preceding rice crop still being vigorously tilled. Second, SS of wheat following rice does not imply increased herbicide dependence, reflecting that puddled rice fields tend to be weed-free at the time of harvest. Third, SS of wheat does not necessarily entail the retention of crop debris as mulch.
The viability of the rice–wheat cropping systems (RWCS) is threatened as a result of challenges posed by phreatic water depletion, plummeting economic returns, and productivity stagnation in south Asia [12,13]. Promoting SS-based management practices, especially the use of improved seeds, optimum fertilization, integrated soil- and crop-management, besides increased investment in agricultural R&D, is the key to a sustainable production system [14]. SS can also capture revenue synergies among prevailing management activities for rural development and sustainable agriculture, which would substantively contribute to attaining the Sustainable Development Goals (SDGs) (Figure 2). Nutrient transformation/mineralization in soil depends on the biological and physico–chemical characteristics, and, by adopting SS, all these traits improve significantly, enhancing crop productivity in return [4,13]. In the light of the increasing popularity of SS among the farmers of the eastern IGP as a resource conservation technology, we compiled this review paper covering the concept of the SS of wheat, environmental impact of its adoption, and the potentials and constraints of SS-based technologies in the IGP of India.

2. Data Extraction

Experiments on SS are relatively scarce, as it is a newer technology, and popularized only in limited districts of eastern Uttar Pradesh and Bihar. The comparison study (Table 1) between various crop establishment methods i.e., conventional tillage (CT), conservation agriculture (CA), and SS, reveals that zero tillage (ZT) practices with residue (R) retention have a convenient resemblance to SS. Therefore, we comprehensively searched the peer-reviewed publications investigating the effects of ZT with R retention in relation to the CT practices on soil physico–chemical properties, using the Web of Science (Elsevier) indexing service, Google Scholar, and other academic websites. Conference proceedings and non-English language publications were excluded. Studies were selected exclusively based on the following criteria:
  • Only picking up the experiments conducted in the IGP with RWCS;
  • Mostly considered the experimental findings reported in 2016 and onwards in peer-reviewed publications/journals. Some experiments with good fundamental knowledge are also included that are published before 2016;
  • Only field experiments were selected with side-by-side comparisons of ZT and CT practices;
  • Experiments conducted for at least 2 years were considered;
  • If R applied, CT taken as CT without R (CT − R), and ZT taken as ZT with R (ZT + R);
  • If other factors such as irrigation, fertilizer application rate, varieties, etc. are implemented in a combination with tillage practices, then common irrigation, fertilizer application rate, varieties, etc. (package and practices) were selected during the comparison between CT and ZT;
  • The only difference in the herbicidal application was considered during the comparison between CT and ZT;
  • In case the mean value is not available, for comparison between CT and ZT, the most significant one throughout the years of the experiment was selected. Otherwise, the mean value was considered for comparison between CT and ZT;
  • For soil properties, only upper soil layer differences were considered among CT and ZT.
In a nutshell, we can say that under CA, the sowing of wheat is performed through a Turbo Happy Seeder or zero-tillage machines; however, in SS, wheat seeds are broadcast manually. Therefore, SS causes minimal harm to the environment by way of GHGs emission in comparison to CA.

3. Crop Productivity in Surface Seeding

The late planting of wheat strings along with rice–wheat systems. Except for Punjab, 25–35% of the wheat area in the Indian IGP is estimated to be sown late, which markedly dwindles wheat productivity. Terminal heat entails a decrease in wheat yield potential by 1–1.5% per day if planting ensues after 15 November [9]. The delay in the planting of the wheat crop is a consequence of late rice harvesting, which corresponds to both the late establishment of rice, and the long duration of this crop. As a matter of fact, farmers grow fine-quality basmati rice in some parts of the IGP, which requires a longer duration to reach maturity. However, in the eastern IGP, long-duration and short-grain rice varieties are preferred, due to water lodging resulting in late wheat sowing. Other reasons for the late sowing of wheat in this region are long turnaround periods, which often imply intensive tillage operations, inadequate draft and mechanical power for ploughing, soil moisture problems (soil either too wet or too dry), and the urgency to store the harvested rice before preparing the land for wheat cultivation. Surface seeding promotes timely wheat establishment, as sowing wheat crop in a standing rice field greatly minimizes the turnaround time.
A brief review comparing the work conducted on the effects of SS implementation on wheat productivity is presented in Table 2. Contrasting results are demonstrated regarding wheat productivity, varying froma0.3 to 25% increase [15,16,17,18]. Generally, increased crop yields under SS are attributed to the improved soil properties, including water infiltration rate, higher SOC, soil aggregation, moisture- and nutrient-availability, and microbial activity [12,16,19,20,21,22,23]. However, it is also reported [24] that positive effects of SS on wheat yield under RW systems are predominantly the outcome of: (a) timely sowing, (b) increased input use efficiency, and (c) weed control. Adopting SS helps to increase long-term farm profitability, as it reduces the number of operations and fuel cost. One of the prime merits of SS, which popularizes it among the farming community, is that it reduces input cost and ensures timely sowing, resulting in higher wheat yields.
A number of studies emphasize the adoption of ZT with crop R retention in IGP for the perpetuation of crop yields and system productivity [25,26,27]. Correspondingly, Bangladeshi farms using SS practices register higher yields, with more profitability [28]. In fact, yield levels of the ZT with crop R retention are proportionate to CT in a long-term experiment conducted in central India, although the energy and labor savings are much greater under the former [29]. The gradual adoption of SS practices for wheat sowing in the RWCS has a direct yield advantage in the eastern IGP, and with the improvement in soil quality, the other beneficial effects are expected to eventually burgeon [30].

4. Resource Use Efficiency in Surface Seeding

Water scarcity is becoming a binding constraint to real agriculture in the IGP; fulfilling the domestic and industrial requirements is similar to walking a tightrope in the current poor water-use efficiency scenario [9]. Over-exploitation of below ground aquifers, when combined with poor water management, exacerbates the predicament of water logging and salinity in some areas, and declining water tables in others [8,51]. Depletion of groundwater resources at an alarming rate is major topic of concern. Management practices based on SS utilize residual moisture, reduce pre-sowing irrigation, and present an immense capability to resolve the issue, as it enhances water-use efficiency (Table 3). This could prove to be advantageous for the IGP, where farmlands are facing acute water shortages, and the lowering of the water table in some of the RW areas as a repercussion of extreme groundwater pumping [12,18,33]. Progress in crop water productivity (CWP) holds the promise of food security, as well as water sustainability in RW cropping systems of the IGP [13,34,50,52]. Crop establishment technologies, with an emphasis on resource conservation, are normally reported to preserve 20–35% of irrigation water in the wheat against conventional practices [9]. A zero-tillage-based rice–wheat–maize system (RWMS) shows enhanced water productivity over a conventional RW system [20]. The irrigation WP under the RW system demonstrates an augmentation of145% under SS compared to farmers’ practice [53]. Moreover, SS can improve soil structure and facilitate buildup of crop debris, which directly correlates with an increase in water retention and better infiltration, along with a decrease in overall water use elsewhere [24]. Additionally, the faster turnaround time effectuated by SS allows for the early planting and harvesting of wheat crops, which, in some regions, potentially eliminates the need for one or more late-season irrigations. The availability of nutrients to the plant is substantially influenced by water availability. Plants absorb nutrients predominantly through transportation and diffusion processes that are governed by water. As a result, high WUE not only saves water, but also improves nutrient availability to plants.
Irrigation boosts agricultural productivity by expanding cultivable land far more than is possible with rain-fed agriculture, and increasing crop yields. Irrigation boosts yields not just by reducing or preventing crop water stress, but also by reaping the additional benefits of combining irrigation with high-yielding cultivars, fertilizer, and herbicides. In developing nations, irrigation is a critical component of agricultural productivity. In the years 1997–1999, irrigated land supplied two-fifths of agricultural yields in developing nations, accounting for around one-fifth of cultivated areas. Irrigated cereal yields out-performed rain-fed yields by 115% in developing nations [54]. Increased food production from irrigated agriculture can provide nutritional benefits to farmers, their families, and the local community. Irrigation allows for multiple cropping, which can help to relieve seasonal food supply gaps, and stimulate the development of crops that contribute to a more diversified and healthy diet. Improved nutrition can improve quality of life, reduce disease, raise labor productivity, and boost children’s academic achievement [55]. Sun et al. [56] report that increased irrigation significantly increases the bulk density (BD) of soil by 5% to 8% in the upper 20 cm, and decreases salt concentrations [57]. Irrigation enhances the nutrients availability to the crop. However, the irrigable water resources are depleted continuously, as a result of environmental pollution and over-exploitation of groundwater resources. Hence, rural communities are eager to adopt such technologies that enhance water productivity and water-use efficiency. However, the adoption of micro-sprinkler and drip irrigation is not so popular among farmers, due to its high cost and maintenance.

5. Weed Management under Surface Seeding

In SS, weed problems are identified as a major issue for management [33,50]. In conventional approaches, tillage operations are performed mainly for weed control, firming seedbeds, and uniform germination [58]. However, the matter of weed control under SS is largely dealt with using herbicides (Table 4). Glyphosate [N-(phosphor no methyl) glycine], a broad-spectrum herbicide, is mainly used in the absence of extensive tillage to manage weed infestation [38,44,49]. In addition to glyphosate, other herbicides, such as 2,4-D (2,4–dichlorophenoxy acetic acid), clodinafop-ethyl, metsulfuron, sulfosulfuron, etc., are applied to control the weeds [18,32]. Indisputably, countries that previously used relatively higher amounts of herbicides are already experiencing retribution, in the form of environmental hazards and the emergence of herbicide-resistant weeds [59]. Therefore, under the SS system, it is duly advised to use the optimum dose of an appropriate herbicides, at the right time, for an efficient weed control [60]. Likewise, repeated herbicide usage under SS sometimes leads to weed shift, a herbicide-resistant weed population [61], and the dominance of a certain weed species as opposed to in conventional farming practices [62]. In an attempt to manage this problem efficiently, devising an integrated weed management approach, including the selection of appropriate cropping systems and cultivars with SS principles’ reinforcement, would be worthwhile [63,64]. In the eastern IGP, SS is mostly practiced in the standing rice crop, and farmers harvest the rice crop generally 7–10 days after sowing. During harvesting, germinated seeds are covered by the rice straw for 4–5 days until it properly dries, and is then collected manually. Thus, the 10 days of straw coverage reduce the germination of many winter weeds. Use of broad-spectrum weedicides, i.e., glyphosate, is not possible in this practice. The reduction in the weed population is observed in SS under puddled rice.

6. Soil Health under Surface Seeding

6.1. Physical Properties

Tillage is usually considered by farmers as a practice in which soil is physically manipulated for the better crop establishment. Keeping this in perspective, the modifications in the soil’s physical properties deliberately affect the soil and ecosystem [67,68]; moreover, extensive tillage operations may eventually ravage the soil health. Farming communities in the IGP zones also practice excessive tillage, which significantly deteriorates the physical properties of soil, such as bulk density (BD), water-holding capacity (WHC), aggregate stability, porosity, etc. [69]. Apropos to this, Alakukku et al. [70] describe the consequent formation of subsurface hardpan after continuous ploughing at the same depth, resulting in reduced nutrient and WUE, as well as root growth. On the flip side, SS aids in inhibiting the deterioration in soil quality due to CT practices, through the revival of soil’s physio–chemo–biological properties (Table 5, Table 6 and Table 7). A brief account of the work performed by researchers in the IGP under the RW system (Table 5) clearly demonstrates a reduction in soil bulk density, and increases in mean weight–diameter (MWD), aggregate stability, and infiltration rate in loam to sandy loam soils under SS over CT. Intensive tillage, non-recycling of crop residue to soil systems, and mono-culture systems-mediated degradation of soil structure and aggregation contribute to a decline in the rate of infiltration under intensively irrigated rice–wheat agro-ecosystems. It inversely affects soil hydraulic conductivity and groundwater recharge, resulting in a consequent depletion of groundwater in such instances [13,20,65,71,72]. When sandy loam soils are exposed to SS rather than CT, the infiltration rate is accelerated by ∼50%, owing to the formation of stable aggregates [12,16,73,74]. The higher infiltration rates in the SS-based RW cropping system facilitate speedy water percolation, and reduce the quantity of run-off that might end up as groundwater recharge [44,75].
The major crop growth benefits of SS manifest through reduced soil erosion, crusting, compaction, and moderated soil hydrothermal regimes [15,18,23,33]. This practice leads to a supportive soil physical environment, which not only promotes root growth and nutrient recycling, but also SOC sequestration [2,17,18,76]. Experimental evidence involving SS shows a substantial decrease in BD and penetration resistance (PR) [34], with a significant increase in soil moisture content, water-stable aggregates (WSA) (>0.25 mm), and MWD, mainly in the topsoil (0–15 cm) layer [2]. Furthermore, soil type and climatic conditions implicitly control the quantum of the impact of SS on the soil’s physical properties. Under the semi-arid conditions, sandy loam soil exhibits a higher WSA (16.1–32.5%), with a significantly decreased PR and BD [27]. Singh et al. [77] document similar results in their five year-long study on sandy loam soil; in accordance with which, Somasundaram et al. [2] observe an increase in WSA (10%) and MWD (20%) in clay soil under the hot sub-humid condition compared to CT four years post-experimentation; meanwhile no significant pattern is observed relative to BD in clayey soil during that time period. Multiple reports advocate the combined implementation of R with a ZT system to yield greater benefits concerning soil’s physical properties [2]; contradictorily, Meena et al. [78] report a 12% and 33% higher MWD for ZT + R and NT − R than CT + R and CT − R, respectively, which implies that the effect of ploughing is more prominent over the addition of R.

6.2. Chemical Properties

The effects of SS practices on the chemical properties of soil are briefly summarized in Table 6. Evidently, favorable impacts are noticed with the ZT operations, i.e., retention and recycling of crop residues on the soil surface in SS [12,18]; the pH is reduced, and the content of available N, P, K, and micronutrients increases in soil over CT. Additionally, the stratification of nutrients and their accumulation near the root zone are detected under SS [16,39,40,49]. Several researchers gathered evidence regarding increased SOC and total nitrogen (N) stocks with the adoption of SS practices involving ZT and crop residue retention, along with optimum nutrient application [39,75,76]. By increasing the quantity of C, soil C sequestration is enhanced, and/or the rate of soil C loss reduced, which primarily depends on the local soil and climate conditions [79]. Yadav et al. [66], in their work encompassing the north–eastern region of India, report that by employing SS practices, such as ZT + integrated plant nutrient management (IPNM) + 30% R incorporation in RWCS, higher SOC sequestration (427.9 kg ha−1 yr−1) is achieved. The soil nutrient availability is evaluated by Jat et al. [16] under the SS practices in north–west India, where the highest SOC (7.7 g kg−1) is found under SS, compared to that under CT (4.5 g kg−1). At the depth of 0–15 cm, the available N is higher in SS-based RWMS (33%) and SS-based maize–wheat–mungbean (MWM; 68%) than a conventionally grown RW cropping system. With respect to available P, a 25% and 38% higher concentration is detected under SS-based MWM and SS-based RWMS, respectively, relative to the conventional system. A plausible explanation for this could be the higher R retention and moderation of the soil moisture and temperature by water absorption, where R acts as an insulating material to resist the change in heat, which is conducive for growth at or near the soil surface. As crop debris contains high concentrations of total K, it could contribute to a higher available K level in soil [18,40]. Apart from these, in other research work conducted in the north–western IGP, the adoption of ZT proves to be beneficial in terms of SOC accumulation and N uptake [80]. In central India, Hati et al. [81] and Kushwa et al. [82] witness that ZT soils display more SOC and P concentration in the surface layers than at depth, in contrast to those exposed to CT under a soybean–wheat system. Similarly, a comparative study conducted by Mohammad et al. [75] in Pakistan shows a higher SOM, and mineralizable C and N, along with total N, P, K, in a minimum tillage (MT) experiment, as compared to that of CT and deep tillage at 0–30 cm soil depths.
Table
Table 6. Effects of surface seeding on soil chemical properties in wheat grown in different regions of India.
Table 6. Effects of surface seeding on soil chemical properties in wheat grown in different regions of India.
LocationSoil TypeEffect on Soil PropertiesChange over Conventional Practices (%)Reference
HaryanaLoampH: 7.6−3.5[35]
LoampH: 7.8−2.7[16]
LoamAvailable N: 156 kg ha−133[16]
-Available N: 216 kg ha−139[12]
Madhya PradeshCLAvailable N: 221 kg ha−17.3[36]
PunjabSLAvailable N: 60 mg kg−154[39]
West BengalSLMineralizable N: 149 kg ha−19.6[49]
HaryanaLoamTotal N: 0.2%36[16]
LoamAvailable P: 21.5 kg ha−138[16]
-Available P: 23 kg ha−141[12]
Madhya PradeshCLAvailable P: 9.9 kg ha−119[36]
PunjabSLAvailable P: 11 mg kg−114[39]
SLAvailable P: 21 mg kg−19.2[40]
West BengalSLAvailable P: 42 kg ha−17.8[49]
HaryanaLoamAvailable K: 236 kg ha−129[16]
-Available K: 312 kg ha−140[12]
Madhya PradeshCLAvailable K: 197 kg ha−17.7[36]
PunjabSLAvailable K: 74 mg kg−13.6[40]
West BengalSLAvailable K: 226 kg ha−13.2[49]
HaryanaLoamAvailable S: 19 mg kg−1−8.2[16]
LoamDTPA-extractable Zn: 9.2 mg kg−193[16]
LoamDTPA-extractable Fe: 136 mg kg−13.0[16]
LoamDTPA-extractable Mn: 99 mg kg−121[16]
Note: SL: sandy loam; CL: clay loam.

6.3. Biological Properties

The ZT in combination with R effectively diminishes the oxidation rate of SOC and crop residue, which improves the SOC content. The effect of SS on soil biological properties (Table 7) reveals a significant increase compared to CT with respect to microbial biomass carbon (MBC), and the activity of soil enzymes such as dehydrogenase, alkaline phosphatase, urease, and phytase. The higher SOC leads to higher MBC, and microbial and mineralization quotients that are the biological indicators under the SS-based system. A significantly higher correlation is witnessed by Bera et al. [39], in relation to SOC: MBC (0.93), SOC: BSR (basal soil respiration) (0.84), and SOC: Qm (carbon mineralization quotient) (0.70) in an RW system while employing various tillage management practices in India. Significant improvements in MBC, basal soil respiration, and microbial and mineralization quotients are observed in the ZT plot as opposed to CT [83]. This is presumably due to the limited microbial decomposition of SOC under ZT which, in contrast to CT, results in greater stabilization of micro-and macro-aggregates, and provides a physical barrier between organic matter and decomposers [84]. Surface seeding also provides a suitable environment for microbial proliferation, due to the retention of crop residue compared to the removal of residue or burning [85]. Diverse microbial communities regulate specific functions associated with the decomposition of crop residues. The soil bacteria instigate the process, while later phases of crop residue decomposition is dominated by fungi [86,87]. The agricultural management practices also influence the soil microbial community structure [88]. Indeed, a study conducted in central Mexico documents that ZT practice coupled with crop R retention augments fungal abundance, and significantly affects the bacterial community structure, thereby promoting the abundance of Bacteroidetes, Betaproteobacteria, and Gemmatimonadetes [89]. These microorganisms take part in several biogeochemical processes, such as C and N cycles, alongside their function of being a storehouse of plant nutrients [90]. Intensive tillage negatively impacts the distribution and abundance of soil microbes, by influencing soil moisture and thermal regimes, as well as nutrient dynamics [91]. Moreover, this practice destroys soil structure, which portends alteration in the abundance and diversity of microbes when compared to the SS system [35,92].
The previous literature suggests that a reduction in tillage accompanies enhanced chemical and microbial activity, microbial biomass, and enzymatic actives such as dehydrogenase, alkaline phosphatase, etc. [19,35,44,93] (Table 7). Parihar et al. [94] report an increase in soil MBC by 45–48.9% under SS-based systems in sandy loam (Typic Haplustept) soil profiles (0–30 cm deep) in the north–western IGP. Concurrently, an SS-based maize–wheat cropping system (MWCS) improves soil MBC (208%), MBN (263%), and dehydrogenase (210%), and alkaline phosphatase activity (48%), when compared with the conventional practice of the RW system [35]. However, the SS-based RW system enhances the soil MBC and MBN up to 40%, as well as the dehydrogenase and alkaline phosphatase activity by up to 15% [12,53]. In cereal systems predicated on SS, a higher micro-arthropod population is witnessed under RW compared to the MW system. Also, an SS-based MW system secures the uppermost soil quality index (SQI) score of 1.45, while with a CA-based RW system, it is 0.58, with the lowermost score of 0.29 comes from the conventional RW system [35].
Table
Table 7. Effects of surface seeding on soil biological properties in wheat grown in different regions of India.
Table 7. Effects of surface seeding on soil biological properties in wheat grown in different regions of India.
LocationSoil TypeEffect on Soil PropertiesChange over Conventional Practices (%)Reference
HaryanaLoamMBC: 207 μg g−1 dry soil22[35]
-MBC: 1113 μg g−1 dry soil122[16]
SLMBC: 257 μg g−1 soil29[88]
New DelhiSLMBC: 145 mg kg−1 soil27[19]
SLMBC: 65 mg kg−1 soil-[95]
SLMBC: 140 μg g−1 soil20[38]
PunjabSLMBC: 333 μg g−1 soil57[23]
SLMBC: 138 μgCmic g−1 soil39[83]
Uttar PradeshSLMBC: 164 mg kg−1 dry soil47[44]
UttarakhandSCLMBC: 0.3 g kg−123[13]
HaryanaLoamMBN: 80 μg g−1 dry soil36[35]
-MBN: 433 μg g−1 dry soil171[16]
SLMBN: 61 μg g−1 soil56[88]
SLBacterial PLFA: 82 nmol g−152[88]
SLFungal PLFA: 7.3 nmol g−1135[88]
West BengalEntisolActinomycetes population: 95 × 105 CFU g−117[93]
HaryanaLoamDehydrogenase: 51 µg TPF g−1 24h−137[35]
New DelhiSLDehydrogenase: 247 µg TPF g−1 24 h−1-[95]
PunjabSLDehydrogenase: 18 µg TPF g−1 h−121[39]
SLDehydrogenase: 14 µg TPF g−1 h−139[21]
New DelhiSLFluorescein di-acetate: 18 μg fluorescein g−1 hr−1-[95]
PunjabSLFluorescein di-acetate: 1.3 μg fluorescein g−1 dry soil13[39]
SLFluorescein di-acetate: 1.1 μg fluorescein g−1 h−119[21]
HaryanaLoamAlkaline phosphatase activity: 52 µg p-nitrophenol g–1 h–153[35]
PunjabSLAlkaline phosphatase activity: 86 µg p-nitrophenol g–1 h–148[39]
SLAlkaline phosphatase activity: 53 µg p-nitrophenol g–1 h–129[21]
New DelhiSLAcid phosphatase: 127 μmol p-nitrophenol g−1 h−1-[95]
PunjabSLAcid phosphatase activity: 33 µg p-nitrophenol g–1 h–15.9[39]
SLAcid phosphatase activity: 25 µg p-nitrophenol g–1 h–137[21]
HaryanaLoamβ-glycosidase activity: 43 µg p-nitrophenol g–1 h–119[35]
PunjabSLβ-glycosidase activity: 36 µg p-nitrophenol g–1 h–196[39]
PunjabSLβ-glucosidase activity: 16 μg PNP g−1 hr−125[21]
SLUrease activity: 4.6 µg urea g–1 min–11.1[39]
SLUrease activity: 3.9 µg urea g–1 min–11.3[21]
SLPhytase activity: 0.7 µg g–1 h–124[21]
SLPhytase activity: 0.5 µg g–1 h–135[21]
SLAsparaginase activity: 39 μg g−1 hr−143[21]
SLXylanase activity: 33 μg glucose g−1 hr−134[21]
SLCellulase activity: 16 μg glucose g−1 hr−171[21]
SLPhenol oxidase activity: 0.4 μg DOPA g−1 hr−1−38[21]
SLPeroxidase activity: 5.5 μg DOPA g−1 hr−1−23[21]
SLMetabolic quotient: 1.2 μg C-CO2 cumulative μg total organic carbon−116[21]
New DelhiSLFluorescein di-acetate, urease, and total phosphatase activities13, 13l and 25%, respectively[38]
PunjabSLDehydrogenase, urease, acid, and alkaline phosphatase activity13, 5, 25l and 16, respectively[23]
Note: SL: sandy loam; CL: clay loam; SCL: sandy clay loam; MBC: microbial biomass carbon; MBN: microbial biomass nitrogen.

7. Environmental Impact on Surface Seeding

Surface seeding is a climate-resilient resource-conserving technology (Figure 3). It has the potential to increase cost and yield with a minimal carbon footprint, as it tends to sequester organic carbon in soil (Table 8), with lesser expenditure of energy and irrigation water, thus, reducing the total global warming potential (GWP) (Table 9). With respect to the comparative GHGs emissions from SS and CT practices, Sapkota et al. [33] detect a 32% reduction in N2O emissions in ZT and direct seeding. Similarly, Gupta et al. [37] estimate a minute decrease in N2O emissions (2.2%) under ZT, which equates to a similar extent of reduction in the GWP. However, Kumar et al. [20] evaluate four wheat management strategies, and report that in an attempt to reduce the GWP of wheat, a soil matric potential (SMP) criteria must be used in place of applying irrigation water at certain intervals at critical crop growth stages. Irrespective of CO2 emission, Nath et al. [19] observe a 17% decline in CO2–C flux under SS, whereas Gathala et al. [14] note that, under RT, CO2 equivalent emission is reduced by 8.4% in comparison to farmers’ practices. Along the same lines, evaluation of different tillage rotation practices are performed by Gupta et al. [37], where ZT alone and ZT+R-based wheat display significantly lower GWP and GHGs emissions compared to CT wheat, signifying that the adoption of SS practices could reduce the GWP of the conventional RW system by 44 to 47%, without compromising the yield. Similar findings are documented by Tirol-Padre et al. [22], Kakraliya et al. [34], Kar et al. [93], and Singh et al. [95]. Aryal et al. [96] employ the Cool Farm Tool (CFT) to estimate GHG emission, which utilizes data regarding total production area, productivity, and management input with pedo-climatic conditions, and the results suggest that CO2 emissions in CT wheat are significantly higher (0.6 Mg of CO2 eq ha−1 yr−1) in contrast to ZT wheat, where 0.084 Mg of CO2 eq ha−1 yr−1 is sequestered. When the collective emissions from a ZT-based wheat production system are converted intoaCO2 equivalent, the resultant produce is nearly carbon-neutral, as N2O emissions are counterbalanced by C sequestration [93]. As tillage management practices significantly influence soil C stock, variations in GHGs emissions could certainly be attributed to the SS and CT practices. Any reduction in GHG emissions while practicing SS might also result from the restricted disposal of crop debris through burning, which is quite common in conventional practices; moreover, it is worth mentioning that burning each ton of crop residue can emit 40 g of N2O, which is equivalent to 12.4 kg of CO2, along with 2.3 kg of CH4, which equals 48.3 kg of CO2 [97].

8. Cost Savings and Profitability of Surface Seeding

Rice–wheat cropping systems need to upgrade their cost competitiveness in the perspective of trade liberalization and swift non-agricultural growth. Surface seeding plausibly involves cost-effectiveness in terms of energy, water, labor, and other inputs. This system significantly reduces machinery usage for the tillage operation and the associated cost, which is a major contributor to the cost of crop production in the IGP. Available studies collectively highlight the profitability of SS-based wheat cultivation over CT (Table 10). There are two factors that inherently contribute to the overall profitability of SS: (i) the value of the yield increase, and (ii) the savings in production cost. In the RW systems of the IGP [9], practicing ZT wheat cultivation reduces the production cost by about USD32 ha−1, particularly due to the use of less labor, less pumping of water, and, ultimately, lower diesel fuel consumption [101]. According to Mousques and Friedrich [96,97,100], the net income under SS is reportedly twice that of under CT, primarily due to the reduced cost of inputs [102,103]. The net benefit of ZT surpasses CT gross income by 11–17% [11]. Surveys encompassing farmers’ fields adopting ZT wheat systems in India [22,31,34,48] show that those who opt for ZT planting of wheat following rice yield obvious economic and social perks. The children of the farmers get extra time for their study and sports activities. Small and marginal farmers also pursue some technical and menial jobs in the nearby cities to earn extra income for their families. It becomes necessary to further increase the profitability of farmers by adopting SS, if provisions are made for giving carbon credits to them for additional SOC sequestration into the soil.

9. Future Researchable Priorities and Institutional Support

The adaptation and popularization of SS are mostly based upon more benefits than constraints, which are depicted in Table 11 and Table 12. The above-presented literature review specifies a few researchable themes and strategies for the wide-ranging adoption of SS practices in the IGP, which are outlined below:
  • Screening of wheat genotypes suitable for the SS could help in the proper crop establishment under sub-optimal soil moisture;
  • Development of proper package of practices specifically for SS. Research and long-term field experiments on the methodology of nutrient application, weed management, and irrigation scheduling are the need of the hour;
  • Development of light-weight harvesting machineries suited for SS, and its supply on subsidized rates to the marginal and small farmers;
  • Development of handheld and field-specific machines for small and marginal farmers that promote SS and residue management, which are easy to operate and accepted by the farming community;
  • Setting up training and demonstration campaigns by different public and private organizations for creating awareness and feasibility of SS;
  • Suitable integrated weed and pest management (IWPM) strategies should be promoted via field demonstrations, as well as through active extension services;
  • Surface seeding has a lack of institutional support and linkages. A close relationship among farmers and stakeholders in a participatory manner involving scientists, farmers, and farm machinery manufacturers should be initiated.

10. Conclusions

The spread of SS is mainly concentrated in the IGP of India, more particularly in eastern Uttar Pradesh and Bihar. The adoption of SS practices has the potential to increase the production of wheat, and mitigate the effects of global warming, due to less GHG emission. Additional benefits include soil health improvement, nutrient recycling, reduction in energy cost, enhanced soil WHC, reduction in run-off and erosion losses, as well as soil temperature regulation, which assists the planting of crops in rotation as per schedule. Thus, efforts are needed to change the mindset of the farmers’ through demonstrations of SS technology. This could be accomplished by extending robust technology dissemination programs, accentuating crop residue/carbon-credit retention incentives, as well as distributing suitable location-specific farm implements to procure the maximum advantages of SS techniques for the sustainable sustenance of soil health and food security. Furthermore, strong policies and legislation are essential to promote the SS technology of wheat, in order to avoid residue burning and reduce GHGs emission and other ecosystem services for a sustainable environment and healthy future. Moreover, long-term experiments on the SS of wheat should be setup under different agro-climatic regions, to find out the benefits, suitability, and impacts on the environment.

Author Contributions

Conceptualization of the article structure and content: A.P., S.K.S. and R.C.; defined the literature search criteria: A.P. and S.K.S.; fata handling, tables, and figures preparation: A.P. and H.S.J.; writing—original draft: A.P.; writing—review and editing: A.P., S.K.S., R.C., S.S., S.S.J., M.F.A., Y.L., V.D.R., S.K.A., M.A.K. and T.M. All authors have read and agreed to the published version of the manuscript.

Funding

V.D.R. and T.M. would like to recognize the financial support from the Strategic Academic Leadership Program of the Southern Federal University (“Priority 2030”).

Institutional Review Board Statement

Not applicable.

Informed Consent Statement

Not applicable.

Data Availability Statement

The data and materials will be made available from the corresponding author(s) upon reasonable request.

Conflicts of Interest

The authors declare no conflict of interest.

References

  1. Bhattacharyya, T.; Pal, D.K.; Mandal, C.; Velayutham, M. Organic carbon stock in Indian soils and their geographical distribution. Curr. Sci. 2000, 79, 655–660. [Google Scholar]
  2. Somasundaram, J.; Chaudhary, R.S.; Kumar, D.A.; Biswas, A.K.; Sinha, N.K.; Mohanty, M.; Hati, K.M.; Jha, P.; Sankar, M.; Patra, A.K.; et al. Effect of contrasting tillage and cropping systems on soil aggregation, carbon pools and aggregate-associated carbon in rainfed Vertisols. Eur. J. Soil Sci. 2018, 69, 879–891. [Google Scholar] [CrossRef]
  3. Biswas, P.P.; Sharma, P.D. A new approach for estimating fertiliser response ratio-the Indian scenario. Indian J. Fertil. 2008, 4, 59. [Google Scholar]
  4. Jat, H.S.; Datta, A.; Choudhary, M.; Sharma, P.C.; Jat, M.L. Conservation Agriculture: Factors and drivers of adoption and scalable innovative practices in Indo-Gangetic plains of India—A review. Int. J. Agric. Sustain. 2021, 19, 40–55. [Google Scholar] [CrossRef]
  5. Ladha, J.K.; Dawe, D.; Pathak, H.; Padre, A.T.; Yadav, R.L.; Singh, B.; Singh, Y.; Singh, Y.; Singh, P.; Kundu, A.L. How extensive are yield declines in long-term rice-wheat experiments in Asia? Field Crop. Res. 2003, 81, 159–180. [Google Scholar] [CrossRef]
  6. Byerlee, D.; Ali, M.; Siddiq, A. Sustainability of the rice-wheat system in Pakistan’s Punjab: How large is the problem? Improv. Product. Sustain. Rice-Wheat Syst. 2003, 65, 77–95. [Google Scholar]
  7. Mohanty, M.; Painuli, D.K.; Misra, A.K.; Ghosh, P.K. Soil quality effects of tillage and residue under rice-wheat cropping on a Vertisol in India. Soil Tillage Res. 2007, 92, 243–250. [Google Scholar] [CrossRef]
  8. Pingali, P.L.; Shah, M. Policy re-directions for sustainable resource use: The rice-wheat cropping system of the Indo-Gangetic Plains. J. Crop Prod. 2001, 3, 103–118. [Google Scholar] [CrossRef]
  9. Hobbs, P.R.; Gupta, R.K. Rice-wheat cropping systems in the Indo-Gangetic plains: Issues of water productivity in relation to new resource-conserving technologies. In Water Productivity in Agriculture: Limits and Opportunities for Improvement; CABI: Wallingford, UK, 2003; Volume 1, Chapter 15; p. 239. [Google Scholar]
  10. Tripathi, J.; Adhikari, C.; Duxbury, J.M.; Lauren, J.G.; Hobbs, P.R. Assessment of Farmer Adoption of Surface Seeded Wheat in the Nepal Terai: Rice-Wheat Consortium Paper Series 19; Rice-Wheat Consortium for the Indo-Gangetic Plains: New Delhi, India, 2006; p. 50. [Google Scholar]
  11. Erenstein, O.; Farooq, U.; Malik, R.K.; Sharif, M. On-farm impacts of zero tillage wheat in South Asia’s rice-wheat systems. Field Crop. Res. 2008, 105, 240–252. [Google Scholar] [CrossRef]
  12. Jat, H.S.; Datta, A.; Choudhary, M.; Yadav, A.K.; Choudhary, V.; Sharma, P.C.; Gathala, M.K.; Jat, M.L.; McDonald, A. Effects of tillage, crop establishment and diversification on soil organic carbon, aggregation, aggregate associated carbon and productivity in cereal systems of semi-arid Northwest India. Soil Tillage Res. 2019, 190, 128–138. [Google Scholar] [CrossRef]
  13. Choudhary, M.; Panday, S.C.; Meena, V.S.; Singh, S.; Yadav, R.P.; Pattanayak, A.; Mahanta, D.; Bisht, J.K.; Stanley, J. Long-term tillage and irrigation management practices: Strategies to enhance crop and water productivity under rice-wheat rotation of Indian mid-Himalayan Region. Agric. Water Manag. 2020, 232, 106067. [Google Scholar] [CrossRef]
  14. Gathala, M.K.; Laing, A.M.; Tiwari, T.P.; Timsina, J.; Islam, S.; Bhattacharya, P.M.; Dhar, T.; Ghosh, A.; Sinha, A.K.; Chowdhury, A.K.; et al. Energy-efficient, sustainable crop production practices benefit smallholder farmers and the environment across three countries in the Eastern Gangetic Plains, South Asia. J. Clean. Prod. 2020, 246, 118982. [Google Scholar] [CrossRef]
  15. Mishra, G.; Kushwaha, H.S. Winter wheat yield and soil physical properties responses to different tillage and irrigation. Eur. J. Biol. Res. 2016, 6, 56–63. [Google Scholar]
  16. Jat, H.S.; Jat, H.S.; Datta, A.; Datta, A.; Sharma, P.C.; Sharma, P.C.; Kumar, V.; Kumar, V.; Yadav, A.K.; Yadav, A.K.; et al. Assessing soil properties and nutrient availability under conservation agriculture practices in a reclaimed sodic soil in cereal-based systems of North-West India. Arch. Agron. Soil Sci. 2018, 64, 531–545. [Google Scholar] [CrossRef]
  17. Nandan, R.; Singh, V.; Singh, S.S.; Kumar, V.; Hazra, K.K.; Nath, C.P.; Poonia, S.; Malik, R.K.; Bhattacharyya, R.; McDonald, A. Impact of conservation tillage in rice–based cropping systems on soil aggregation, carbon pools and nutrients. Geoderma 2019, 340, 104–114. [Google Scholar] [CrossRef]
  18. Singh, Y.P.; Singh, S.; Singh, A.K.; Panwar, B. Influence of Wheat Establishment Techniques and Previous Kharif Season Crops on Productivity, Profitability, Water Use Efficiency, Energy Indices and Soil Properties in Central India. Agric. Res. 2020, 9, 203–212. [Google Scholar] [CrossRef]
  19. Nath, C.P.; Das, T.K.; Rana, K.S.; Bhattacharyya, R.; Pathak, H.; Paul, S.; Meena, M.C.; Singh, S.B. Greenhouse gases emission, soil organic carbon and wheat yield as affected by tillage systems and nitrogen management practices. Arch. Agron. Soil Sci. 2017, 63, 1644–1660. [Google Scholar] [CrossRef]
  20. Kumar, V.; Jat, H.S.; Sharma, P.C.; Singh, B.; Gathala, M.K.; Malik, R.K.; Kamboj, B.R.; Yadav, A.K.; Ladha, J.K.; Raman, A.; et al. Can productivity and profitability be enhanced in intensively managed cereal systems while reducing the environmental footprint of production? Assessing sustainable intensification options in the breadbasket of India. Agric. Ecosyst. Environ. 2018, 252, 132–147. [Google Scholar] [CrossRef]
  21. Saikia, R.; Sharma, S.; Thind, H.S.; Sidhu, H.S.; Singh, Y. Temporal changes in biochemical indicators of soil quality in response to tillage, crop residue and green manure management in a rice-wheat system. Ecol. Indic. 2019, 103, 383–394. [Google Scholar] [CrossRef]
  22. Singh, M.; Kumar, P.; Kumar, V.; Solanki, I.S.; McDonald, A.J.; Kumar, A.; Poonia, S.P.; Kumar, V.; Ajay, A.; Kumar, A. Intercomparison of crop establishment methods for improving yield and profitability in the rice-wheat system of Eastern India. Field Crop. Res. 2020, 250, 107776. [Google Scholar] [CrossRef]
  23. Dhaliwal, J.K.; Singh, M.J.; Sharma, S.; Gupta, N.; Kukal, S.S. Medium-term impact of tillage and residue retention on soil physical and biological properties in dry-seeded rice-wheat system in north-west India. Soil Res. 2020, 58, 468–477. [Google Scholar] [CrossRef]
  24. Erenstein, O.; Laxmi, V. Zero tillage impacts in India’s rice-wheat systems: A review. Soil Tillage Res. 2008, 100, 1–14. [Google Scholar] [CrossRef]
  25. Das, T.K.; Bandyopadhyay, K.K.; Bhattacharyya, R.; Sudhishri, S.; Sharma, A.R.; Behera, U.K.; Saharawat, Y.S.; Sahoo, P.K.; Pathak, H.; Vyas, A.K.; et al. Effects of conservation agriculture on crop productivity and water-use efficiency under an irrigated pigeonpea–wheat cropping system in the western Indo-Gangetic Plains. J. Agric. Sci. 2016, 154, 1327–1342. [Google Scholar] [CrossRef]
  26. Samal, S.K.; Rao, K.K.; Poonia, S.P.; Kumar, R.; Mishra, J.S.; Prakash, V.; Mondal, S.; Dwivedi, S.K.; Bhatt, B.P.; Naik, S.K. Evaluation of long-term conservation agriculture and crop intensification in rice-wheat rotation of Indo-Gangetic Plains of South Asia: Carbon dynamics and productivity. Eur. J. Agron. 2017, 90, 198–208. [Google Scholar] [CrossRef]
  27. Parihar, C.M.; Yadav, M.R.; Singh, A.K.; Kumar, B.; Pooniya, V.; Pradhan, S.; Verma, R.K.; Parihar, M.D.; Nayak, H.S.; Saharawat, Y.S. Long-Term Conservation Agriculture and Intensified Cropping Systems: Effects on Growth, Yield, Water, and Energy-use Efficiency of Maize in Northwestern India. Pedosphere 2018, 28, 952–963. [Google Scholar] [CrossRef]
  28. Dhar, A.R.; Islam, M.; Jannat, A.; Ahmed, J.U. Adoption prospects and implication problems of practicing conservation agriculture in Bangladesh: A socioeconomic diagnosis. Soil Tillage Res. 2018, 176, 77–84. [Google Scholar] [CrossRef]
  29. Subba Rao, A.; Biswas, A.K.; Sammi Reddy, K.; Hati, K.M.; Ramana, S. IISS: Two Decades of Soil Research; ICAR-Indian Institute of Soil Science: Bhopal, India, 2009. [Google Scholar]
  30. Tomar, S.S. Conservation Agriculture for Rice-Wheat Cropping System. J. Indian Soc. Soil Sci. 2008, 56, 358–366. [Google Scholar]
  31. Keil, A.; Mitra, A.; McDonald, A.; Malik, R.K. Zero-tillage wheat provides stable yield and economic benefits under diverse growing season climates in the Eastern Indo-Gangetic Plains. Int. J. Agric. Sustain. 2020, 18, 567–593. [Google Scholar] [CrossRef]
  32. Gathala, M.K.; Kumar, V.; Sharma, P.C.; Saharawat, Y.S.; Jat, H.S.; Singh, M.; Kumar, A.; Jat, M.L.; Humphreys, E.; Sharma, D.K.; et al. Optimizing intensive cereal-based cropping systems addressing current and future drivers of agricultural change in the northwestern Indo-Gangetic Plains of India. Agric. Ecosyst. Environ. 2013, 177, 85–97. [Google Scholar] [CrossRef]
  33. Sapkota, T.B.; Shankar, V.; Rai, M.; Jat, M.L.; Stirling, C.M.; Singh, L.K.; Jat, H.S.; Grewal, M.S. Reducing Global Warming Potential through Sustainable Intensification of Basmati Rice-Wheat Systems in India. Sustainability 2017, 9, 1044. [Google Scholar] [CrossRef] [Green Version]
  34. Kakraliya, S.K.; Jat, H.S.; Singh, I.; Sapkota, T.B.; Singh, L.K.; Sutaliya, J.M.; Sharma, P.C.; Jat, R.D.; Choudhary, M.; Lopez-Ridaura, S.; et al. Performance of portfolios of climate smart agriculture practices in a rice-wheat system of western Indo-Gangetic plains. Agric. Water Manag. 2018, 202, 122–133. [Google Scholar] [CrossRef]
  35. Choudhary, M.; Sharma, P.C.; Jat, H.S.S.; McDonald, A.S.; Jat, M.L.S.; Choudhary, S.S.; Garg, N.S. Soil biological properties and fungal diversity under conservation agriculture in Indo-Gangetic Plains of India. J. Soil Sci. Plant Nutr. 2018, 18, 1142–1156. [Google Scholar] [CrossRef] [Green Version]
  36. Singh, P.; Singh, G.; Sodhi, G.P.S. Energy and carbon footprints of wheat establishment following different rice residue management strategies vis-à-vis conventional tillage coupled with rice residue burning in north-western India. Energy 2020, 200, 117554. [Google Scholar] [CrossRef]
  37. Gupta, D.K.; Bhatia, A.; Kumar, A.; Das, T.K.; Jain, N.; Tomer, R.; Malyan, S.K.; Fagodiya, R.K.; Dubey, R.; Pathak, H. Mitigation of greenhouse gas emission from rice–wheat system of the Indo-Gangetic plains: Through tillage, irrigation and fertilizer management. Agric. Ecosyst. Environ. 2016, 230, 1–9. [Google Scholar] [CrossRef]
  38. Nath, C.P.; Das, T.K.; Bhattacharyya, R.; Pathak, H.; Paul, S.; Chakraborty, D.; Hazra, K.K. Nitrogen Effects on Productivity and Soil Properties in Conventional and Zero Tilled Wheat with Different Residue Management. Proc. Natl. Acad. Sci. India Sect. B Biol. Sci. 2019, 89, 123–135. [Google Scholar] [CrossRef]
  39. Bera, T.; Sharma, S.; Thind, H.S.; Sidhu, H.S.; Jat, M.L. Soil biochemical changes at different wheat growth stages in response to conservation agriculture practices in a rice-wheat system of north-western India. Soil Res. 2017, 56, 91–104. [Google Scholar] [CrossRef]
  40. Thind, H.S.; Sharma, S.; Singh, Y.; Sidhu, H.S. Rice-wheat productivity and profitability with residue, tillage and green manure management. Nutr. Cycl. Agroecosyst. 2019, 113, 113–125. [Google Scholar] [CrossRef]
  41. Jat, M.L.; Gathala, M.K.; Ladha, J.K.; Saharawat, Y.S.; Jat, A.S.; Kumar, V.; Sharma, S.K.; Kumar, V.; Gupta, R. Evaluation of precision land leveling and double zero-till systems in the rice-wheat rotation: Water use, productivity, profitability and soil physical properties. Soil Tillage Res. 2009, 105, 112–121. [Google Scholar] [CrossRef]
  42. Gathala, M.K.; Ladha, J.K.; Saharawat, Y.S.; Kumar, V.; Kumar, V.; Sharma, P.K. Effect of Tillage and Crop Establishment Methods on Physical Properties of a Medium-Textured Soil under a Seven-Year Rice-Wheat Rotation. Soil Sci. Soc. Am. J. 2011, 75, 1851–1862. [Google Scholar] [CrossRef]
  43. Kumar, N.; Nath, C.P.; Hazra, K.K.; Das, K.; Venkatesh, M.S.; Singh, M.K.; Singh, S.S.; Praharaj, C.S.; Singh, N.P. Impact of zero-till residue management and crop diversification with legumes on soil aggregation and carbon sequestration. Soil Tillage Res. 2019, 189, 158–167. [Google Scholar] [CrossRef]
  44. Kumar, R.; Singh, U.; Mahajan, G. Performance of Zero-till Wheat (Triticum aestivum L.) and Weed Species as Influenced by Residue and Weed Management Techniques in Rice based Cropping System. Int. J. Curr. Microbiol. Appl. Sci. 2019, 8, 270–277. [Google Scholar] [CrossRef]
  45. Zuddin, S.; Singh, V.P.; Chandra, S.; Singh, S.; Guru, S.; Pareek, N.; Sarvadamana, A.K.; Paliwal, A. Growth and Productivity of Wheat under Tillage Systems and Residue Loads in Tarai Region of Uttarakhand, India. Int. J. Curr. Microbiol. Appl. Sci. 2019, 8, 11–19. [Google Scholar] [CrossRef]
  46. Singh, M.; Singh, O.; Singh, R. Impact of Wheat Establishment Methods and Weed Management Practices on Weed Flora, Yield and Nutrient Uptake of Wheat in Rice-Wheat Cropping System: Establishment methods and weed management practices on weed dynamics nutrient uptake of wheat. J. AgriSearch 2019, 6, 73–77. [Google Scholar] [CrossRef]
  47. Chatterjee, S.; Biswas, B.; Saha, P.K.; Chakrabarti, U.; Chand, S.P. Long-term impact of conventional and zero tillage on wheat (Triticum aestivum) in red and lateritic zone of West Bengal. Indian J. Agron. 2016, 61, 102–109. [Google Scholar]
  48. Mukherjee, D. Enhancement of productivity potential of wheat (Triticum aestivum) under different tillage and nitrogen-management strategies. Indian J. Agron. 2019, 64, 348–353. [Google Scholar]
  49. Mitra, B.; Majumdar, K.; Dutta, S.K.; Mondal, T.; Das, S.; Banerjee, H.; Ray, K.; Satyanarayana, T. Nutrient management in wheat (Triticum aestivum) production system under conventional and zero tillage in eastern sub-Himalayan plains of India. Indian J. Agric. Sci. 2019, 89, 775–784. [Google Scholar]
  50. Islam, S.; Gathala, M.K.; Tiwari, T.P.; Timsina, J.; Laing, A.M.; Maharjan, S.; Chowdhury, A.K.; Bhattacharya, P.M.; Dhar, T.; Mitra, B.; et al. Conservation agriculture based sustainable intensification: Increasing yields and water productivity for smallholders of the Eastern Gangetic Plains. Field Crop. Res. 2019, 238, 1–17. [Google Scholar] [CrossRef]
  51. Qureshi, A.S.; Shah, T.; Akhtar, M. The Groundwater Economy of Pakistan; IWMI: Lahore, Pakistan, 2003; Volume 64, ISBN 9290905301. [Google Scholar]
  52. Kashyap, P.L.; Xiang, X.; Heiden, P. Chitosan nanoparticle based delivery systems for sustainable agriculture. Int. J. Biol. Macromol. 2015, 77, 36–51. [Google Scholar] [CrossRef]
  53. Jat, H.S.; Kumar, P.; Sutaliya, J.M.; Kumar, S.; Choudhary, M.; Singh, Y.; Jat, M.L. Conservation agriculture based sustainable intensification of basmati rice-wheat system in North-West India. Arch. Agron. Soil Sci. 2019, 65, 1370–1386. [Google Scholar] [CrossRef]
  54. Faurès, J.M.; Hoogeveen, J.; Bruinsma, J. The FAO Irrigated Area Forecast for 2030; FAO: Rome, Italy, 2002; pp. 1–14. [Google Scholar]
  55. Wisser, D.; Frolking, S.; Douglas, E.M.; Fekete, B.M.; Vörösmarty, C.J.; Schumann, A.H. Global irrigation water demand: Variability and uncertainties arising from agricultural and climate data sets. Geophys. Res. Lett. 2008, 35, L24408. [Google Scholar] [CrossRef] [Green Version]
  56. Sun, H.; Zhang, X.; Liu, X.; Ju, Z.; Shao, L. The long-term impact of irrigation on selected soil properties and grain production. J. Soil Water Conserv. 2018, 73, 310–320. [Google Scholar] [CrossRef]
  57. Al-Ghobari, H.M. The effect of irrigation water quality on soil properties under center pivot irrigation systems in central Saudi Arabia. WIT Trans. Ecol. Environ. 2011, 145, 507–516. [Google Scholar] [CrossRef] [Green Version]
  58. Zimdahl, R.L. Fundamentals of Weed Science; Academic Press: Cambridge, MA, USA, 2018; ISBN 0128111445. [Google Scholar]
  59. Ramesh, K. Weed problems, ecology, and management options in conservation agriculture: Issues and perspectives. In Advances in Agronomy; Elsevier: Amsterdam, The Netherlands, 2015; Volume 131, pp. 251–303. ISBN 0065-2113. [Google Scholar]
  60. Mishra, J.S.; Singh, V.P. Effect of tillage and weed control on weed dynamics, crop productivity and energy-use efficiency in rice (Oryza sativa)-based cropping systems in Vertisols. Indian J. Agric. Sci. 2011, 81, 129–133. [Google Scholar]
  61. Ramesh, K.; Matloob, A.; Aslam, F.; Florentine, S.K.; Chauhan, B.S. Weeds in a Changing Climate: Vulnerabilities, Consequences, and Implications for Future Weed Management. Front. Plant Sci. 2017, 8, 95. [Google Scholar] [CrossRef]
  62. Dang, Y.P.; Moody, P.W.; Bell, M.J.; Seymour, N.P.; Dalal, R.C.; Freebairn, D.M.; Walker, S.R. Strategic tillage in no-till farming systems in Australia’s northern grains-growing regions: II. Implications for agronomy, soil and environment. Soil Tillage Res. 2015, 152, 115–123. [Google Scholar] [CrossRef]
  63. Singh, M.; Bhullar, M.S.; Chauhan, B.S. Influence of tillage, cover cropping, and herbicides on weeds and productivity of dry direct-seeded rice. Soil Tillage Res. 2015, 147, 39–49. [Google Scholar] [CrossRef]
  64. Raliya, R.; Nair, R.; Chavalmane, S.; Wang, W.-N.; Biswas, P. Mechanistic evaluation of translocation and physiological impact of titanium dioxide and zinc oxide nanoparticles on the tomato (Solanum lycopersicum L.) plant. Metallomics 2015, 7, 1584–1594. [Google Scholar] [CrossRef]
  65. Kumar, V.; Gathala, M.K.; Saharawat, Y.S.; Parihar, C.M.; Kumar, R.; Kumar, R.; Jat, M.L.; Jat, A.S.; Mahala, D.M.; Kumar, L. Impact of tillage and crop establishment methods on crop yields, profitability and soil physical properties in rice-wheat system of Indo-Gangetic Plains of India. Soil Use Manag. 2019, 35, 303–313. [Google Scholar] [CrossRef]
  66. Yadav, G.S.; Lal, R.; Meena, R.S.; Babu, S.; Das, A.; Bhowmik, S.N.; Datta, M.; Layak, J.; Saha, P. Conservation tillage and nutrient management effects on productivity and soil carbon sequestration under double cropping of rice in north eastern region of India. Ecol. Indic. 2019, 105, 303–315. [Google Scholar] [CrossRef]
  67. Lal, R. Sequestering carbon and increasing productivity by conservation agriculture. J. Soil Water Conserv. 2015, 70, 55A–62A. [Google Scholar] [CrossRef] [Green Version]
  68. Blanco-Canqui, H.; Ruis, S.J. No-tillage and soil physical environment. Geoderma 2018, 326, 164–200. [Google Scholar] [CrossRef]
  69. Srinivasarao, C.; Kundu, S.; Lakshmi, C.S.; Rani, Y.S.; Nataraj, K.C.; Gangaiah, B.; Laxmi, M.J.; Babu, M.V.S.; Rani, U.; Na-glakshmi, S. Soil health issues for sustainability of South Asian Agriculture. EC Agric. 2019, 5, 310–326. [Google Scholar]
  70. Alakukku, L.; Weisskopf, P.; Chamen, W.C.T.; Tijink, F.G.J.; van der Linden, J.P.; Pires, S.; Sommer, C.; Spoor, G. Prevention strategies for field traffic-induced subsoil compaction: A review: Part 1. Machine/soil interactions. Soil Tillage Res. 2003, 73, 145–160. [Google Scholar] [CrossRef]
  71. Bhatt, R.; Kukal, S.S.; Busari, M.A.; Arora, S.; Yadav, M. Sustainability issues on rice-wheat cropping system. Int. Soil Water Conserv. Res. 2016, 4, 64–74. [Google Scholar] [CrossRef] [Green Version]
  72. Verhulst, N.; Sayre, K.D.; Vargas, M.; Crossa, J.; Deckers, J.; Raes, D.; Govaerts, B. Wheat yield and tillage-straw management system×year interaction explained by climatic co-variables for an irrigated bed planting system in northwestern Mexico. Field Crop. Res. 2011, 124, 347–356. [Google Scholar] [CrossRef]
  73. Patra, S.; Julich, S.; Feger, K.-H.; Jat, M.L.; Jat, H.; Sharma, P.C.; Schwärzel, K. Soil hydraulic response to conservation agriculture under irrigated intensive cereal-based cropping systems in a semiarid climate. Soil Tillage Res. 2019, 192, 151–163. [Google Scholar] [CrossRef]
  74. Thierfelder, C.; Wall, P.C. Effects of conservation agriculture techniques on infiltration and soil water content in Zambia and Zimbabwe. Soil Tillage Res. 2009, 105, 217–227. [Google Scholar] [CrossRef]
  75. Mohammad, A.; Sudhishri, S.; Das, T.K.; Singh, M.; Bhattacharyya, R.; Dass, A.; Khanna, M.; Sharma, V.K.; Dwivedi, N.; Kumar, M. Water balance in direct-seeded rice under conservation agriculture in North-western Indo-Gangetic Plains of India. Irrig. Sci. 2018, 36, 381–393. [Google Scholar] [CrossRef]
  76. Modak, K.; Ghosh, A.; Bhattacharyya, R.; Biswas, D.R.; Das, T.K.; Das, S.; Singh, G. Response of oxidative stability of aggregate-associated soil organic carbon and deep soil carbon sequestration to zero-tillage in subtropical India. Soil Tillage Res. 2019, 195, 104370. [Google Scholar] [CrossRef]
  77. Singh, V.K.; Singh, Y.; Dwivedi, B.S.; Singh, S.K.; Majumdar, K.; Jat, M.L.; Mishra, R.P.; Rani, M. Soil physical properties, yield trends and economics after five years of conservation agriculture based rice-maize system in north-western India. Soil Tillage Res. 2016, 155, 133–148. [Google Scholar] [CrossRef]
  78. Meena, J.R.; Behera, U.K.; Chakraborty, D.; Sharma, A.R. Tillage and residue management effect on soil properties, crop performance and energy relations in greengram (Vigna radiata L.) under maize-based cropping systems. Int. Soil Water Conserv. Res. 2015, 3, 261–272. [Google Scholar] [CrossRef] [Green Version]
  79. Tiwari, R.; Naresh, R.K.; Vivek Lali Jat, P.S.; Singh, A. Soil aggregation and aggregate associated organic carbon fractions and microbial activities as affected by tillage and straw management in a rice-wheat rotation: A review. J. Pharmacog. Phytochem. 2018, 7, 2865–2893. [Google Scholar]
  80. Devi, S.; Gupta, C.; Jat, S.L.; Parmar, M.S. Crop residue recycling for economic and environmental sustainability: The case of India. Open Agric. 2017, 2, 486–494. [Google Scholar] [CrossRef]
  81. Hati, K.M.; Chaudhary, R.S.; Mandal, K.G.; Bandyopadhyay, K.K.; Singh, R.K.; Sinha, N.K.; Mohanty, M.; Somasundaram, J.; Saha, R. Effects of tillage, residue and fertilizer nitrogen on crop yields, and soil physical properties under soybean-wheat rotation in vertisols of Central India. Agric. Res. 2015, 4, 48–56. [Google Scholar] [CrossRef]
  82. Kushwa, V.; Hati, K.M.; Sinha, N.K.; Singh, R.K.; Mohanty, M.; Somasundaram, J.; Jain, R.C.; Chaudhary, R.S.; Biswas, A.K.; Patra, A.K. Long-term Conservation Tillage Effect on Soil Organic Carbon and Available Phosphorous Content in Vertisols of Central India. Agric. Res. 2016, 5, 353–361. [Google Scholar] [CrossRef]
  83. Saikia, R.; Sharma, S.; Thind, H.S.; Singh, Y. Tillage and residue management practices affect soil biological indicators in a rice-wheat cropping system in north-western India. Soil Use Manag. 2020, 36, 157–172. [Google Scholar] [CrossRef]
  84. Tripathi, R.; Nayak, A.K.; Bhattacharyya, P.; Shukla, A.K.; Shahid, M.; Raja, R.; Panda, B.B.; Mohanty, S.; Kumar, A.; Thilagam, V.K. Soil aggregation and distribution of carbon and nitrogen in different fractions after 41 years long-term fertilizer experiment in tropical rice-rice system. Geoderma 2014, 213, 280–286. [Google Scholar] [CrossRef]
  85. Mandal, A.; Patra, A.K.; Singh, D.; Swarup, A.; Masto, R.E. Effect of long-term application of manure and fertilizer on biological and biochemical activities in soil during crop development stages. Bioresour. Technol. 2007, 98, 3585–3592. [Google Scholar] [CrossRef]
  86. Marschner, P.; Umar, S.; Baumann, K. The microbial community composition changes rapidly in the early stages of decomposition of wheat residue. Soil Biol. Biochem. 2011, 43, 445–451. [Google Scholar] [CrossRef]
  87. Mohanty, M.; Sinha, N.K.; Reddy, K.S.; Chaudhary, R.S.; Rao, A.S.; Dalal, R.C.; Menzies, N.W. How important is the quality of organic amendments in relation to mineral N availability in soils? Agric. Res. 2013, 2, 99–110. [Google Scholar] [CrossRef]
  88. Chaudhary, A.; Sharma, D.K. Impact assessment of zero-tillage on soil microbial properties in rice-wheat cropping system. Indian J. Agric. Sci. 2019, 89, 1680–1683. [Google Scholar]
  89. Navarro-Noya, Y.E.; Gómez-Acata, S.; Montoya-Ciriaco, N.; Rojas-Valdez, A.; Suárez-Arriaga, M.C.; Valenzuela-Encinas, C.; Jiménez-Bueno, N.; Verhulst, N.; Govaerts, B.; Dendooven, L. Relative impacts of tillage, residue management and crop-rotation on soil bacterial communities in a semi-arid agroecosystem. Soil Biol. Biochem. 2013, 65, 86–95. [Google Scholar] [CrossRef]
  90. Trivedi, P.; Delgado-Baquerizo, M.; Jeffries, T.C.; Trivedi, C.; Anderson, I.C.; Lai, K.; McNee, M.; Flower, K.; Singh, B.P.; Minkey, D. Soil aggregation and associated microbial communities modify the impact of agricultural management on carbon content. Environ. Microbiol. 2017, 19, 3070–3086. [Google Scholar] [CrossRef]
  91. Gosai, K.; Arunachalam, A.; Dutta, B.K. Influence of conservation tillage on soil physicochemical properties in a tropical rainfed agricultural system of northeast India. Soil Tillage Res. 2009, 105, 63–71. [Google Scholar] [CrossRef]
  92. Brussaard, L.; de Ruiter, P.C.; Brown, G. Soil biodiversity for agricultural sustainability. Agric. Ecosyst. Environ. 2007, 121, 233–244. [Google Scholar] [CrossRef]
  93. Kar, S.; Pramanick, B.; Brahmachari, K.; Saha, G.; Mahapatra, B.; Saha, A.; Kumar, A. Exploring the best tillage option in rice based diversified cropping systems in alluvial soil of eastern India. Soil Tillage Res. 2021, 205, 104761. [Google Scholar] [CrossRef]
  94. Parihar, C.; Jat, S.L.; Singh, A.; Kumar, B.; Singh, Y.; Pradhan, S.; Pooniya, V.; Dhauja, A.; Chaudhary, V.; Jat, M.; et al. Conservation agriculture in irrigated intensive maize-based systems of north-western India: Effects on crop yields, water productivity and economic profitability. Field Crop. Res. 2016, 193, 104–116. [Google Scholar] [CrossRef]
  95. Singh, G.; Bhattacharyya, R.; Das, T.K.; Sharma, A.R.; Ghosh, A.; Das, S.; Jha, P. Crop rotation and residue management effects on soil enzyme activities, glomalin and aggregate stability under zero tillage in the Indo-Gangetic Plains. Soil Tillage Res. 2018, 184, 291–300. [Google Scholar] [CrossRef]
  96. Aryal, J.P.; Sapkota, T.B.; Jat, M.L.; Bishnoi, D.K. On-Farm Economic and Environmental Impact of Zero-Tillage Wheat: A Case of North-West India. Exp. Agric. 2015, 51, 1–16. [Google Scholar] [CrossRef] [Green Version]
  97. Grace, P.R.; Harrington, L.; Jain, M.C.; Robertson, G.P. Long-Term Sustainability of the Tropical and Subtropical Rice-Wheat System: An Environmental Perspective. Improv. Product. Sustain. Rice-Wheat Syst. 2003, 65, 27–43. [Google Scholar]
  98. Dey, A.; Dwivedi, B.S.; Bhattacharyya, R.; Datta, S.P.; Meena, M.C.; Das, T.K.; Singh, V.K. Conservation agriculture in a rice-wheat cropping system on an alluvial soil of north-western Indo-Gangetic plains: Effect on soil carbon and Nitrogen pools. J. Indian Soc. Soil Sci. 2016, 64, 246–254. [Google Scholar] [CrossRef]
  99. Modak, K.; Biswas, D.R.; Ghosh, A.; Pramanik, P.; Das, T.K.; Das, S.; Kumar, S.; Krishnan, P.; Bhattacharyya, R. Zero tillage and residue retention impact on soil aggregation and carbon stabilization within aggregates in subtropical India. Soil Tillage Res. 2020, 202, 104649. [Google Scholar] [CrossRef]
  100. Tirol-Padre, A.; Rai, M.; Kumar, V.; Gathala, M.; Sharma, P.C.; Sharma, S.; Nagar, R.K.; Deshwal, S.; Singh, L.K.; Jat, H.S.; et al. Quantifying changes to the global warming potential of rice wheat systems with the adoption of conservation agriculture in northwestern India. Agric. Ecosyst. Environ. 2016, 219, 125–137. [Google Scholar] [CrossRef]
  101. Govaerts, B.; Verhulst, N.; Castellanos-Navarrete, A.; Sayre, K.D.; Dixon, J.; Dendooven, L. Conservation Agriculture and Soil Carbon Sequestration: Between Myth and Farmer Reality. Crit. Rev. Plant Sci. 2009, 28, 97–122. [Google Scholar] [CrossRef]
  102. Mousques, C.; Friedrich, T. Conservation Agriculture in China and the Democratic People’s Republic of Korea; FAO: Rome, Italy, 2007. [Google Scholar]
  103. Anwar, M.Z.; Farooq, U.; Sharif, C.M.; Akmal, N.; Morris, M. Diffusion of Zero-Till Seed Drills in Punjab Province; Internal Report; Social Science Institute, National Agricultural Research Center (NARC): Islamabad, Pakistan, 2004.
  104. Tripathi, R.S.; Raju, R.; Thimmappa, K. Impact of zero tillage on economics of wheat production in Haryana. Agric. Econ. Res. Rev. 2013, 26, 101–108. [Google Scholar]
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Figure 1. Components and beneficial impacts of surface seeding of wheat. Note: GHG: greenhouse gases, GWP: global warming potential, WUE: water-use efficiency, WHC: water-holding capacity, SOC: soil organic carbon, SOM: soil organic matter.
Figure 1. Components and beneficial impacts of surface seeding of wheat. Note: GHG: greenhouse gases, GWP: global warming potential, WUE: water-use efficiency, WHC: water-holding capacity, SOC: soil organic carbon, SOM: soil organic matter.
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Figure 2. Possibilities of partial achievement of Sustainable Development Goals (SDGs) by practicing surface seeding of wheat.
Figure 2. Possibilities of partial achievement of Sustainable Development Goals (SDGs) by practicing surface seeding of wheat.
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Figure 3. Inter-relation among surface seeding of wheat with natural resource conservation and climate-resilient agriculture.
Figure 3. Inter-relation among surface seeding of wheat with natural resource conservation and climate-resilient agriculture.
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Table
Table 1. Comparative study between surface seeding, conservation agriculture, and conventional agriculture.
Table 1. Comparative study between surface seeding, conservation agriculture, and conventional agriculture.
ParametersConservation Agriculture Conventional Agriculture Surface Seeding
PracticeNominal soil disruption and the surface of the soil is fully coveredMaximal soil disruption and the surface of the soil is fully exposedLeast soil disruption and the surface of the soil is fully covered
TillageMinimal or no-tillage operationExcessive mechanical tillage operationNo-tillage operation
TimelinessMechanized operations, ensure timeliness of operationsOperations can be delayedTimeliness of operations more
optimal
Residue managementResidue retention on the soil surfaceResidue burning or removalSurface retention of residues
Use of organicsUse of in-situ organics/compostsUse of ex-situ organics/compostsUse of in-situ organics/composts
ErosionWind and water erosion is minimalWind and water erosion is maximumLeast wind and soil erosion
Water infiltrationBetter water infiltrationLowest due to clogging of soil pores The infiltration rate of water is high
Soil physical healthComparatively good by increasing porosity, water-holding capacity aggregation, and reducing bulk density Very poor by increasing bulk density, and decreasing porosity, water-holding capacity, and aggregationComparatively good by reducing bulk density, and increasing porosity, water-holding capacity, and aggregation
Soil organic matterSoil organic carbon build-up and worthy C-sequestration rateLow due to oxidation of organic matter and residue removalHigher soil organic carbon build-up and C-sequestration rate
Soil biological healthMore diverse and healthy biological properties and populationsPoor biological health, and less microbial diversity and activityBetter biological health, and rich in microbial diversity and activity
WeedsWeeds are troublesome in the initial stages of adoption but decrease with time; residues can aid in weed-growth-suppressionControls weeds, causes more weed seeds to germinate, and more crop–weed competition in later growth stageWeeds are troublesome in the initial stages of adoption but decrease with time; residues can aid in weed-growth-suppression/ reduce the weed seed germination, as they are not allowed to come above soil surface
Environmental stressAdditional resilience to stresses, lower yield losses under stressPoor adaptation to stresses, yield losses greater under stress conditionsAdded resilience to stresses, minimum yield losses under stress conditions
Greenhouse gases (GHGs) emissionLow, and global warming potential is also lessHigher GHGs emission and global warming potentialVery low GHGs emission and global warming potential
Use of machineryControlled traffic, no compaction in crop area, compaction in tramline Free-wheeling of farm machinery, increased soil compactionNo compaction in crop area
Diesel use and costsDiesel use much reducedDiesel use highLowest use of diesel
Production costsLowHighVery low
YieldYields on a par with CT, but can surpass if planting is performed in advanceGenerally lower than CA and delayed planting further reduces productivity Productivity of grains is higher, due to advanced planting
Table
Table 2. Effect of surface seeding on wheat yield in different regions of India.
Table 2. Effect of surface seeding on wheat yield in different regions of India.
LocationSoil TypeVarietyGrain Yield
(t ha−1)		Increase over Conventional Practices (%)References
BiharSC-5.211[26]
SCHD 29675.518[17]
SL-5.222[18]
--2.74.5[31]
HaryanaLoamDBW 176.225[32]
CLDPW 621-506.27.4[33]
Silt loamHD 29676.013[34]
Loam-5.57.0[16]
Loam-5.47.4[35]
-DPW 621–506.417[12]
Madhya PradeshCLMP 40104.75.8[36]
New DelhiLoamHD 28944.98.6[37]
SLHD 29674.715[19]
SLHD 29675.08.0[38]
PunjabSLHD 29675.76.8[39]
SLHD 29675.27.4[40]
SLHD 29675.88.7[21]
Uttar PradeshSL-6.020[41]
SLPBW 3435.413[42]
SLPusa 11214.818[43]
SCLHUW 2343.65.8[44]
Uttarakhand-UP 25653.6−8.9[15]
CLUP 26284.72.2[45]
SLPBW 3434.63.2[46]
SCLWheat 8043.60.3[13]
West BengalSL, CL to clay-3.115[47]
SCLK 03073.46.3[48]
SL-4.010[49]
Eastern Gangetic Plains, south AsiaLoam to SL-3.35.1[50]
Note: SCL: sandy clay loam; SL: sandy loam; CL: clay loam; SC: silt clay.
Table
Table 3. Effects of surface seeding on nutrients management and water-use efficiency of wheat grown in different regions of India.
Table 3. Effects of surface seeding on nutrients management and water-use efficiency of wheat grown in different regions of India.
LocationSoil TypeNutrients Application Rate
(kg ha−1)		Total Water Productivity
(kg Grain m−3 Water)		Increase over Conventional Practices (%)Reference
BiharSLN:150, P2O5:60, K2O:40 --[18]
HaryanaLoam-1.313[32]
Silt loamN:135, P2O5:62, K2O:60 1.430[34]
-N:150, P2O5:26, K2O:50 0.967[12]
New DelhiSLN:150, P2O5:80, K2O:60 --[38]
PunjabSLN:120, P2O5:25, K2O:25 --[39]
Uttar PradeshSLN:120, P2O5:26, K2O:50 1.444[41]
SLN:150, P2O5:26, K2O:50--[42]
SLN:150, P2O5:26, K2O:50 --[43]
West BengalSLN:150, P2O5:26.3, K2O:33.3 --[49]
HaryanaCLN:150, P2O5:60, K2O:60 Water consumption: 0.536[33]
Madhya PradeshCLN:120, P2O5:26.2, K2O:33.1 WUE: 131 kg grain ha−1 cm−114[36]
Uttarakhand-N:120, P2O5:60, K2O:40 WUE: 16 kg ha−1 mm−113 decreases[15]
UttarakhandSCLN:100, P2O5:60, K2O:40 WUE: 11 kg ha−1 mm−12.8[13]
Eastern Gangetic Plains, south AsiaLoam to SLN:60–145, P2O5:11–45, K2O:14 to 502.530[50]
Note: SCL: sandy clay loam; SL: sandy loam; CL: clay loam; WUE: water-use efficiency.
Table
Table 4. Various weed management practices under surface seeding adopted in different regions of India.
Table 4. Various weed management practices under surface seeding adopted in different regions of India.
LocationSoil TypeWeed Management PracticesReferences
BiharSLGlyphosate @ 1.0 kg a.i. ha−1 is used as pre-plant 2 days before sowing, to kill existing weeds.
Pre-mix herbicide sulfosulfuron + metsulfuron @ 32 g a.i. ha−1 at 30–35 DAS.		[18]
HaryanaLoamIn the 1st year, pre-mixed herbicide sulfosulfuron + metsulfuron @ 32 g a.i. ha−1 is applied at 35 DAS.
In 2nd year, tank mixture of clodinafop-ethyl + metsulfuron @ 60 + 4 g a.i. ha−1 is applied at 35 DAS.		[32]
HaryanaCLGlyphosate @ 1.25 kg a.i. ha−1 sprayed pre-planting of wheat.
Total (metsulfuron methyl 75% + sulfosulfuron) @ 1250 mL a.i. ha−1 is sprayed to control weeds after emergence.		[33]
New DelhiSLPendimethalin 1.0 kg ha−1 applied before emergence
(1 DAS), followed by sulfosulfuron @ 25 g ha−1 after emergence
(25 DAS).		[38]
Uttar PradeshSLGlyphosate @ 900 g a.i. ha−1 sprayed before the sowing of wheat.[41]
SLGlyphosate at 900 g a.i. ha−1 sprayed as pre-plant of wheat.
Grassy and broad-leaf weeds are managed by spraying sulfosulfuron + metsulfuron methyl @ 35 g a.i. + 4 g a.i. ha–1 at 25–30 DAS.		[65]
West BengalSLGlyphosate 41% S.L. at 3.75 l ha−1 applied 7 days prior to sowing, to smother the existing weed flora.
2,4-D Na salt 80% W.P. at 1 kg a.i. ha−1 at 4–5 weeks after sowing, to smother the broad-leaf weed flora.		[49]
Eastern Gangetic Plains, south AsiaLoam to SLGlyphosate sprayed 4 to 7 days before the sowing of wheat[50]
UttarakhandSLDominant grassy weeds flora is Phalaris minor (55.0%), whereas major non-grassy weed is Melilotus indica in wheat crop.[66]
Note: SL: sandy loam; CL: clay loam.
Table
Table 5. Effects of surface seeding on soil physical properties in wheat grown in different regions of India.
Table 5. Effects of surface seeding on soil physical properties in wheat grown in different regions of India.
LocationSoil TypeEffect on Soil PropertiesChange over Conventional Practices (%)Reference
BiharEntisolBulk density: 1.5 Mg m3−6.5[33]
-Bulk density: 1.5 g cm3−6.4[20]
HaryanaLoamBulk density: 1.6 Mg m3−2.4[16]
Madhya PradeshCLBulk density: 1.5 Mg m3−3.9[18]
New DelhiSLBulk density: 1.5 Mg m3−1.3[76]
PunjabSLBulk density: 1.6 Mg m36.7[23]
Uttar PradeshSLBulk density: 1.6 Mg m34.7[42]
Uttarakhand-Bulk density: 1.4 Mg m32.9[15]
SCLBulk density: 1.3 Mg m32.3[13]
New DelhiSLMean weight–diameter: 0.4 mm13[38]
PunjabSLMean weight–diameter: 1.2 mm10[23]
Uttar PradeshSLMean weight–diameter: 2.7 mm102[41]
SLMean weight–diameter: 1.2 mm32[44]
Uttarakhand-Mean weight–diameter: 0.7 mm4.2[15]
SLSoil aggregates (>0.25 mm): 70%35[41]
SLSoil aggregates (>0.25 mm): 75%51[42]
Bihar-Water-stable soil aggregates (MWD): 6.1 mm407[20]
HaryanaLoamAggregate stability: 46%91[53]
LoamWater-stable macro-aggregates: micro-aggregates: 7.9796[53]
Uttar PradeshSLAggregate ratio: 4.383[44]
Bihar-Air-filled porosity: 45.1%9.1[20]
UttarakhandSCLTotal porosity: 53%2.3[13]
-Effective porosity: 1.9 m3 m−37.5[15]
Bihar-Water-holding capacity: 55%40[20]
HaryanaLoamInfiltration rate: 0.3 cm hr−1244[16]
Madhya PradeshCLInfiltration rate: 5.8 mm hr−118[36]
PunjabSLSteady-state infiltration: 1.0 cm h−125[23]
Uttar PradeshSLSteady-state infiltration: 0.4 cm h−1200[42]
SLSteady-state infiltration: >0.1 cm hr−167[43]
Uttarakhand-Saturated hydraulic conductivity: 21−2.3[15]
HaryanaLoamVolumetric water content: 27%50[16]
Note: SCL: sandy clay loam; SL: sandy loam; CL: clay loam.
Table
Table 8. Effects of surface seeding on carbon footprint in wheat grown in different regions of India.
Table 8. Effects of surface seeding on carbon footprint in wheat grown in different regions of India.
LocationSoil TypeEffects on Carbon Status or AccumulationIncrease over Conventional Practices (%)References
HaryanaLoamOrganic carbon: 7.5 g kg−167[16]
LoamOrganic carbon: 6.1 g kg−130[35]
-Organic carbon: 7.4 g kg−140[12]
LoamOrganic carbon: 8.1 g kg−165[53]
Madhya PradeshCLOrganic carbon: 4.0 g kg−11.8[18]
New DelhiSCLOrganic carbon: 5.8 g kg−15.7[98]
PunjabSLOrganic carbon: 6.7 g kg−114[39]
SLOrganic carbon: 4.7 g kg−116[40]
SLOrganic carbon: 6.2 g kg−16.9[23]
SLOrganic carbon: 5.4 g kg−113[83]
Uttar PradeshSLOrganic carbon: 5.2 g kg−140[65]
Uttarakhand-Organic carbon: 7.6 g kg−12.7[15]
SCLOrganic carbon: 8.8 g kg−112[13]
West BengalSLOrganic carbon: 9.8 g kg−110[49]
BiharEntisolTotal soil organic carbon: 5.5 t ha−157[33]
Silt clayTotal soil organic carbon: 6.9 g kg−19.1[17]
HaryanaLoamTotal soil organic carbon: 11 g kg−181[53]
New DelhiSCLTotal soil organic carbon: 7.3 g kg−14.3[98]
SLTotal soil organic carbon: 13 Mg ha−111[19]
SLTotal soil organic carbon: 5.1 g kg−1-[95]
SLTotal soil organic carbon: 10 g kg−125[76]
SLTotal soil organic carbon: 7.6 Mg ha−123[99]
SCLTotal soil inorganic carbon: 2.1 g kg−1−22[98]
BiharSilt clayTotal soil organic carbon stock: 14 Mg ha−120[26]
New DelhiSLSoil organic carbon stock: 13 Mg ha−19.7[19]
PunjabSLSoil organic carbon stock: 14 Mg ha−116[23]
New DelhiSLSOC sequestration: 3.5 Mg ha−12.6[76]
SLSOC accumulation: 7.6 Mg ha−123[76]
PunjabInceptisolC-sequestration: 47.1 kg C ha−1−9.9[36]
UttarakhandSCLC-sequestration: 25 Mg ha−18.6[13]
SCLC-sequestration rate: 460 kg C ha−1 year−136[13]
BiharSilt clayCarbon management index: 11111[17]
New DelhiSLCarbon management index: 0.74.8[76]
Uttar PradeshSLCarbon management index: 15441[65]
New DelhiSLOxidative stability of C: 0.520[76]
PunjabInceptisolCarbon sustainability index: 10400[36]
Note: SL: sandy loam; CL: clay loam; SCL: sandy clay loam.
Table
Table 9. Impact of adverse environment on surface seeding wheat grown in different regions of India.
Table 9. Impact of adverse environment on surface seeding wheat grown in different regions of India.
LocationSoil TypeEnvironmental StressChange over Conventional Practices (%)Reference
HaryanaSL to CLN2O–N flux: 0.5 kg ha−114[100]
CLN2O–N flux: 1.7 kg N ha−1−32[33]
CLN2O–N flux: 4.5 kg N ha−172[33]
New DelhiLoamN2O–N flux: 0.9 kg ha−1−2.2[37]
SLN2O–N flux: 390 g ha−12.6[19]
West BengalEntisolN2O flux: 11 mg m−2 h−13.6[93]
New DelhiSLCO2–C flux: 266 g ha−1−17[19]
HaryanaCLGWP from emission: 825 kg CO2 eq ha−1−31[33]
CLGWP from emission: 2204 kg CO2 eq ha−172[33]
Silt loamGWP: 4592 kg CO2 eq ha−1 yr−140[34]
New DelhiLoamGWP: 378 kg CO2 eq ha−1−4.8[37]
SLGWP: 477 kg CO2 eq ha−1−18[19]
LoamGHG intensity: 0.1−8.1[37]
PunjabInceptisolTotal carbon equivalent emission: 1624 kg CO2 eq ha−1−21[36]
InceptisolGWP: 2.1 Mg CO2 eq ha−1−16[36]
HaryanaSilt loamGHG intensity: 0.4 kg kg−1 CO2 eq ha−1 yr−144[34]
PunjabInceptisolGHG intensity: 0.3 kg CO2 eq kg−1−12[36]
InceptisolCarbon equivalent emission: 0.6 Mg CO2 eq ha−1−17[36]
Eastern Gangetic Plains, south Asia-Carbon dioxide equivalent emission: 1.4 Mg ha−1−8.4[14]
Table
Table 10. Effects of surface seeding of wheat in economic aspects grown in different regions of India.
Table 10. Effects of surface seeding of wheat in economic aspects grown in different regions of India.
LocationSoil TypeBenefit: Cost RatioIncrease over Conventional Practices (%)Reference
BiharSL2.317[18]
Haryana-2.316[104]
Loam3.631[32]
Madhya PradeshCL2.441[22]
Uttar Pradesh SL3.764[41]
SL3.141[43]
West BengalSL, CL to clay2.2187[47]
SCL2.117[48]
SL1.610[49]
HaryanaCLNet return: USD1278 ha−113[33]
-Net return: USD1108 ha−121[12]
PunjabSLNet return: USD 621 ha−1Benefits: USD 167 ha−1[40]
Uttar PradeshSCLNet return: USD 395 ha−1Benefits: USD 29 ha−1[65]
Bihar-Returns to capital: INR 3.0 INR−127[31]
Uttar Pradesh-Cost of cultivation: USD 623 ha−1Benefits: USD 133 ha−1[77]
-Cost of cultivation: USD 620 ha−1Benefits: USD 158 ha−1[77]
HaryanaSilt loamNet return: USD 1280 ha−122[34]
Note: SL: sandy loam; CL: clay loam; SCL: sandy clay loam.
Table
Table 11. Potential benefits associated with surface seeding of wheat.
Table 11. Potential benefits associated with surface seeding of wheat.
BenefitsResulting fromReasons
Agro-ecological benefits
Progressive suppression of weed growthImprovement in soil structure and stabilityReduce tillage that allows weed seed in deep soil
Long-term yield increaseReduced water and wind erosionReduce tillage and improve soil structure
Increase in soil fertility and stability, and improved soil structureReduce tillage, improve soil cover due to mulching, intercropping, and crop rotation
Improved retention of water, nutrients, and soil moistureReduce tillage, improve soil cover due to mulching
Reduces run-offDecrease in erosion, improved soil structure and water-retention capacityReduce tillage and improve soil cover
Improves rooting conditionsIncrease in soil fertility stability, and
improved soil structure		Reduce tillage, improve soil cover due to mulching, intercropping, and crop rotation
Improves agrobiodiversityHigher biological activity in the soil and in the fieldImproved soil cover due to mulching
Crop diversificationCrop rotation and intercropping
Output stabilityReduced vulnerability to climatic shocksImproved rooting conditions
Enhanced biological pest and disease controlCrop rotation
Higher biological activity in the soil and in the field
Reduces waste of water and inputsReduced run-offDecrease erosion, improve soil structure and water retention capacity
Environmental benefits
Decrease in land degradationReduced dust particles, aerosol, and other particulate materialReduce tillage, improve soil cover, mulching, intercropping, and crop rotation
Improved agrobiodiversityHigher biological activity in the soil and in the field
Reduces downstream sedimentation and siltationReduced run-offDecrease erosion, improve soil structure and water retention capacity
Reduces contamination of soil, and surface and ground waterReduced run-offDecrease erosion, improve soil structure and water retention capacity
Reduction in CO2 emissions to the atmosphereHigher carbon sequestrationReduce tillage, improve soil cover, and mulching
Higher biological activityImprove soil cover and mulching
Socio-economic benefits
Increases food securityLong-term yield increase and output stabilityReduce erosion, greater soil arability, improve soil structure, field capacity, and nutrient retention
Enhance biological pest and disease control
Crop diversificationReduce vulnerability to climatic shocks
Compatibility with various farming systems and agro-ecological environments
Increases net profitabilityLong-term yield increase and output stabilityReduce erosion, greater soil arability, improved soil structure, field capacity, and nutrient retention
Enhance biological pest/disease control
Reduce susceptibility to climatic fluctuations
Reduction in on-farm costsCost-effective labor, machinery, and (in the medium-term) chemical inputs (herbicides, fertilizer, and pesticides, depending on the technology adopted)
Technological sustainabilityCompatibility with different farming systems and agro-ecological environmentsAn appropriate integration of cultivation techniques, equipment, and inputs
Table
Table 12. Potential constraints to the adoption of surface seeding of wheat.
Table 12. Potential constraints to the adoption of surface seeding of wheat.
ConstraintsResulting fromManagement Strategy
Management Constraints
Short-term pest and disease problemsVariation in crop managementDevelopment of suitable technology and training programs
Increased usage of soil cover/mulchingDisease control through IPM technique
Bio intensification and application of additional green chemicals
Short-term weed infestationAlteration in crop managementFormulating appropriate technology packages and training
Modified tillage techniquesAdditional incorporation of suitable chemicals at the critical growth stage of weed
Additional labor and drone-based application
Limited management skillsNeed to carefully plan the crop rotations and intercropping, cover crop preferences, new approaches to weed control and pest management, appropriate application of chief SS principles, etc.Technical support
Farmers’ participation in learning and experimentation
Devising proper training programs
Creation and operation of farming groups, research, and extension networks
High perceived risk
(country specific)		Technology shiftAppropriate use of rewards/incentives
Designing appropriate technology packages and training
Inadequate management skillsFarmers’ involvement and time commitment to learning and experimentation
Lack of country specific knowledge and informationTechnical and institutional support
Commitment of extension officers and innovative farmers
Cultural barriers and/or community prejudiceCommunity involvement in training/ demonstrations and technology adaptation
Economic Constraints
Additional startup costsProcurement of specialized planting equipmentBetter access to certain markets
Farmers’ participation in learning and experimentationAppropriate use of rewards and incentives
Additional labor requirements at initial stagesExpansion of suitable technology packages and training
Lower yields at initial stagesInitial immobilization of nutrientsIntercropping with leguminous/ nitrogen-fixing crops
Supplementary fertilizer application
Short-term problems related to pests, weeds, and diseases IPM training and biological pest/ disease control
Administration of additional chemicals and labor
Devising appropriate training and technology packages
Inadequate management skillsTechnical support and extension
Farmers’ participation and time commitment to experimentation/learning
Creating operational farming networks and research/extension groups
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Singh, S.K.; Patra, A.; Chand, R.; Jatav, H.S.; Luo, Y.; Rajput, V.D.; Sehar, S.; Attar, S.K.; Khan, M.A.; Jatav, S.S.; et al. Surface Seeding of Wheat: A Sustainable Way towards Climate Resilience Agriculture. Sustainability 2022, 14, 7460. https://doi.org/10.3390/su14127460

AMA Style

Singh SK, Patra A, Chand R, Jatav HS, Luo Y, Rajput VD, Sehar S, Attar SK, Khan MA, Jatav SS, et al. Surface Seeding of Wheat: A Sustainable Way towards Climate Resilience Agriculture. Sustainability. 2022; 14(12):7460. https://doi.org/10.3390/su14127460

Chicago/Turabian Style

Singh, Satish Kumar, Abhik Patra, Ramesh Chand, Hanuman Singh Jatav, Yang Luo, Vishnu D. Rajput, Shafaque Sehar, Sanjay Kumar Attar, Mudasser Ahmed Khan, Surendra Singh Jatav, and et al. 2022. "Surface Seeding of Wheat: A Sustainable Way towards Climate Resilience Agriculture" Sustainability 14, no. 12: 7460. https://doi.org/10.3390/su14127460

APA Style

Singh, S. K., Patra, A., Chand, R., Jatav, H. S., Luo, Y., Rajput, V. D., Sehar, S., Attar, S. K., Khan, M. A., Jatav, S. S., Minkina, T., & Adil, M. F. (2022). Surface Seeding of Wheat: A Sustainable Way towards Climate Resilience Agriculture. Sustainability, 14(12), 7460. https://doi.org/10.3390/su14127460

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