1. Introduction
Rice (
Oryza sativa L.) is a principal source of food for more than half of the world population, and ranks third as an agricultural commodity after sugarcane and maize [
1]. Rice contributes one-fifth of total caloric intake by human beings making it an important grain. More than 90% of rice worldwide is grown and consumed in Asia [
2]. In Nepal, rice is the first most important cereal crop with 1.36 million hectares of cultivated area with a productivity of 3.15 t ha
−1 in 2016 [
3].
Rice-wheat (
Triticum aestivum L.) is a major crop rotation in the Indo-Gangetic Plains (IGP) of South Asia that spreads over 13.5 million ha in Bangladesh, India, Nepal and Pakistan [
4]. As both crops exhaustively uptake large amounts of nutrients and most of the nutrients in the plants are removed from the fields as harvested crop, the double cropping system heavily depletes soil nutrients [
5,
6]. However, if crop residues are retained in the soil, a large proportion of nutrients taken from the soil are retained in the ecosystem which might help to maintain the fertility of the soil [
7]. Additionally, the retained residue can increase soil organic carbon and overall soil health [
8,
9]. Rice and wheat residue in the region are traditionally used for feeding animals. However, in recent decades, a large volume of crop residue is left in during mechanical harvesting which is burned to ease planting of following crop. However, burning crop residues is not a sustainable practice since it generally accelerates the loss of soil carbon, increases emissions of CO
2 and increases air pollution [
10].
Traditionally, lowland rice in Nepal and elsewhere in the IGP is transplanted into puddled field soil after repeated ploughing. Puddling reduces percolation loss of water, controls weeds, eases planting of seedlings and decreases the loss of soil carbon as carbon dioxide [
11,
12,
13]. However, conventional tillage practices for puddling can destroy soil aggregates, form plough pan in the subsurface layers, and may increase the loss of soil and nutrients as runoff [
14]. Also, puddling is a labor- and cost-intensive practice which may increase the cost and reduce profits [
15]. Therefore, as an alternative to conventional puddling, there is increased interest in direct seeded rice as it might contribute to reducing the cost of cultivation while conserving water, soil and other resources incurred in cultivation [
13,
15].
Weed management is a major challenge for no-till direct seed rice cultivation but the availability and use of herbicides in the IGP are increasing rapidly which may increase the adoption of direct seeded rice cultivation [
13]. Farm sizes in Nepal are generally very small (less than one hectare) which makes it feasible to manually weed rice and wheat crops. However, in recent decades a large portion of the working population has emigrated creating a labor shortage in the farming sector. The labor shortage and ease of operation has increased exponential use of herbicide use in the country. However, the effectiveness and management options of herbicide in comparisons to manual weeding is scarcely evaluated.
Many field studies were conducted in the IGP during the last two decades to understand tillage, residue and weed managements on the yield of wheat grains [
13,
16,
17]. However, field trials were mostly conducted in India and Pakistan. Thus, the influence of tillage systems, residue retention and weed managements on growth, yield and yield attributes of rice in the Southern Nepal, which is considered as a grain bowl of the country, are scarce. Therefore, this field study was conducted to compare tillage systems (zero and conventional tillage), rice residue retention (whole, partial and no-retention), and forms of weed management (manual and chemical) on yield and yield attributes of rice. These hypotheses were tested in this study: (i) direct seeded rice on zero-tilled soil would produce similar yield as transplanted rice on conventionally tilled puddled field, (ii) rice yield would increase with increased level of wheat residue retention, and (iii) herbicide application will be equally effective as manual weeding in rice.
2. Materials and Methods
2.1. Study Area and Environmental Materials
A field experiment was conducted at the research farm (27°31′49′′ N, 83°27′36′′ E and 82 m above sea level) of the National Wheat Research Program (NWRP) in Bhairahawa, Nepal. The climate is of sub-tropical type with three distinct seasons as summer, rainy and winter. Detailed descriptions of soil physical and chemical properties are given elsewhere [
18]. In brief, the texture is classified as silt loam to silty clay loam. Total soil organic matter content was 2.5% and total N content was 0.14%. The soil was mildly alkaline, with an average soil pH of 7.9. This study site lies within C-block of the NWRP farm map [
18].
The field experiment was conducted over three main rice growing seasons (June through November) of Nepal during 2014, 2015 and 2016 which are defined as Year-1, Year-2 and Year-3, respectively in the following descriptions.
2.2. Experimental Design and Crop Management
The experiment was designed as nested split-split plots in a completely randomized design. Tillage and planting systems were the main plots where rice was either transplanted on puddled field managed with conventional tillage (CT) or direct seeded on zero till (ZT) soil. Main plots were split into sub-plots at three levels of wheat residue management treatment as whole (WR), partial (PR) and no (NR) residue retention. In WR management, all aboveground residues of wheat were chopped, stored in bags, and later used as mulching material during the vegetative stage of rice. In PR management, the bottom 20 cm of the wheat plant was left in the field. In NR management, all wheat residue was removed. Forms of weed management were the sub-sub plots with manual weeding (MW) was compared with chemical weeding (CW) with application of bispyribac-sodium. Thus, there were a total of 12 treatment combinations with 3 replicated plots (4m × 4m) in each combination.
Wheat was harvested in April in all the three years of study. After wheat harvest, rice (cv. Sabitri) was transplanted/sown at 0.2 m × 0.2 m spacing. Sabitri cultivar was released in 1979 and recommended for Terai and the inner Terai region of Nepal. Two to three seedlings per hill were transplanted in the CT system. Rice was sown/transplanted in an east–west row direction. The number of rows per plot were 20. Grain yield was determined on the central 12 lines comprising a net plot area of 9.6 m2.
Timelines of field operations during the rice cultivation are presented in
Supplementary Table S1. The plots were irrigated 3–5 times in each study year. In each irrigation event, all plots were flooded with water till the water height reaches up to 5–7 cm above the soil surface. All plots received inorganic fertilizer at the rate of 100:30:30 kg N: P: K (nitrogen, phosphorus, potash) ha
−1 at transplanting/sowing of rice as urea (46:0:0 N:P:K), di-ammonium phosphate (18:46:0 N:P:K) and muriate of potash (0:0:60 N:P:K). Half a dose of the N and full doses of P and K fertilizers were applied during transplanting/sowing of rice. The remaining half dose of N was applied as urea by equally splitting at 25 and 45 days after transplanting/sowing. Glyphosate (1 kg active ingredient ha
−1) was sprayed in ZT plots prior to sowing of rice. Weeds in CW plots were controlled with spraying bispyribac-sodium (Nominee gold
®, PI Industries, Gurgaon, India) at the rate of 0.025 kg active ingredient ha
−1 during the crop growing period of rice.
2.3. Measurement of Plant Growth and Yield Traits
Heading and physiological maturity was recorded on marked 50 plants. A particular stage was supposed to be completed while 75% of the observed plants show the characteristics of that phase and number of days were counted from the date of soaking the rice seed in water for sprouting in CT. In ZT, phenological stages were counted from the date of sowing. Plant height and panicle length and number of grains per panicle were measured from 10 randomly selected plants per plot at physiological maturity. Number of effective tillers per square meter were counted at physiological maturity stage from 1m2 areas in each plot. After final harvesting, the crop was sun dried, threshed, cleaned and grain was sun dried again. Grain yield was adjusted at 14% moisture since the grain was sun dried instead of oven drying. Thousand grain weight was determined by weighing 1000 grains resulted from each plot.
2.4. Statistical Analysis
Effect of tillage, residue and weed managements and their interactions were analyzed by analysis of variance (ANOVA) using a PROC GLIMMIX procedure in SAS software (version 9.3, Cary, NC, USA). Each dependent variable were analyzed with tillage system as the main factor, residue retention as the split factor, and weed control method as a split-split factor. All data for each measurement were combined across years, and years were treated as repeated measurement applying the autoregressive term AR(1). Block was treated as random variable with two- and three-way interactions with tillage and residue retention treatments. Measurements of plant height, panicle length and number of grains per panicle taken on multiple plants per plot were averaged prior to statistical analysis. Results are presented for each year and averaged across years since year × treatment interactions were significant for most of the measurements. Mean separation to compare treatments, years, and treatments for each year was done by least significant difference (LSD) method at the 5% probability level using the simulation option available in the LINES statement of PROC GLIMMIX.
4. Discussion
In this study, we evaluated the influence of tillage system, wheat residue retention rate and method of weed control on growth, yield attributes and grain yield of rice cultivated in the southern plains (Terai) of Nepal under rice-wheat cropping systems. Grain yield of rice cultivated under conventional tillage system was significantly greater (10%) compared to the direct seeded rice in zero-tilled soil. The results on decreased yield of direct seeded rice than transplanted rice in the puddled field under a conventional tillage system aligned with the results from studies in the IGP [
4,
8,
15]. Although the rice grain yield was decreased only by 10%, the system might be more profitable than the conventional puddling-based transplanting methods [
15]. Even though the results indicated minimal difference (albeit significant) between the two tillage/planting systems, the adoption of direct seeded rice planting mostly depend on availability of machineries for direct seeding on zero tilled soils. Therefore, stakeholders in Nepal should focus on increasing availability, use and training of direct seeded rice. Our results indicated that the lower number of effective tillers were the main reason for lower yield of direct seeded rice compared to the transplanted rice on puddled soil. Therefore, future research should also focus on the selection and breeding of rice varieties that have higher tiller forming ability under no-till, no-puddling conditions.
The key finding of this study is that an increased level of residue retention under rice-wheat cropping system can increase grain yield and improve yield attributes. These results also align with results from most of other studies in the IGP [
19,
20]. The lack of significant interaction effects of tillage and residue management on grain yield and other variables indicated that residue retention can improve performance of rice yield under both conventional and zero-tilled direct seeded systems of rice production. The results corroborate findings from the previous studies in the region as yields of rice and wheat were increased irrespective of tillage systems when residues were retained in the field [
19,
20,
21]. The results are encouraging since the deterioration of soil productivity, increased straw burning and increased cost of cultivation due to external fertilizer inputs are a great concern in the IGP. Our results thus recommend to retain as much straw of rice and wheat as possible under rice-wheat based cropping systems in the region. Although this study was limited to three years, greater positive effects of residue retention can be expected in the long term due to continued increase of carbon in the soil and improved soil health. Indeed, a previous study has documented significant increase of soil health parameters such as soil organic carbon and soil aggregate stability by coupling dry-seeded system and residue retention [
21]. Therefore, the concerned stakeholders in Nepal should promote adoption of residue retention practices in rice-wheat cropping system.
Our results showed a similar effect of both methods of weed managements on rice yield. The method of weed control had no significant interaction with systems of tillage system and residue retention rate on any measured variables. This indicated that the herbicide can work effectively not only for transplanted rice under the puddled field method, but also for direct seeded rice. The results are encouraging since farmers’ adoption of direct seeded rice in the region is constrained by higher weed infestation and greater cost of production in manual weeding [
22]. Previously, Singh et al. [
23] tested the effectiveness of bispyribac-sodium in Haryana, India, and found bispyribac-sodium as one of the most effective herbicides. Our results thus corroborate findings from the previous study in the IGP. Although application of bispyribac-sodium proved to be an effective alternative to manual weeding in this study, resistance to the herbicide is expected when a single herbicide is applied over the years. Further studies are required for effectiveness of other herbicides, resistance, application methods, residual effects and environmental effects in the region as the application of herbicides is a new but popular practice under rice-wheat rotation in the region.