Abstract
Field experiments were conducted to evaluate eight different integrated crop management (ICM) modules for 5 years in a maize-wheat rotation (MWR); wherein, ICM1&2-ˈbusiness-as-usualˈ (conventional flatbed maize and wheat, ICM3&4-conventional raised bed (CTRB) maize and wheat without residues, ICM5&6-conservation agriculture (CA)-based zero-till (ZT) flatbed maize and wheat with the residues, and ICM7&8- CA-based ZT raised bed maize and wheat with the residues. Results indicated that the ICM7&8 produced significantly (p < 0.05) the highest maize grain yield (5 years av.) which was 7.8–21.3% greater than the ICM1-6. However, across years, the ICM5-8 gave a statistically similar wheat grain yield and was 8.4–11.5% greater than the ICM1-4. Similarly, the CA-based residue retained ICM5-8 modules had given 9.5–14.3% (5 years av.) greater system yields in terms of maize grain equivalents (MGEY) over the residue removed CT-based ICM1&4. System water productivity (SWP) was the highest with ICM5-8, being 10.3–17.8% higher than the ICM1-4. Nevertheless, the highest water use (TWU) was recorded in the CT flatbed (ICM1&2), ~ 7% more than the raised bed and ZT planted crops with or without the residues (ICM4-8). Furthermore, the ICM1-4 had produced 9.54% greater variable production costs compared to the ICM5-8, whereas, the ICM5-8 gave 24.3–27.4% additional returns than the ICM1-4. Also, different ICM modules caused significant (p < 0.05) impacts on the soil properties, such as organic carbon (SOC), microbial biomass carbon (SMBC), dehydrogenase (SDH), alkaline phosphatase (SAP), and urease (URE) activities. In 0.0–0.15 m soil profile, residue retained CA-based (ICM5-8) modules registered a 7.1–14.3% greater SOC and 10.2–17.3% SMBC than the ICM1-4. The sustainable yield index (SYI) of MWR was 13.4–18.6% greater under the ICM7&8 compared to the ICM1-4. Hence, this study concludes that the adoption of the CA-based residue retained ICMs in the MWR could sustain the crop yields, enhance farm profits, save water and improve soil properties of the north-western plans of India.
Subject terms: Climate-change impacts, Ecosystem ecology, Environmental impact
Globally, maize (Zea mays L.) is the 3rd most important cereal, and across ecologies, being grown in ~ 155 nations; called ˈQueen of cerealsˈ (maize), the back bone of American food or a miracle crop. The United State produced ~ 31% of the maize grains, subsequently China (24%), Brazil (8%) and India (2.2%)1,2. In India, the maize-wheat rotation (MWR) is the 5th leading cropping rotation, occupying ∼2 million ha in the Indo-Gangetic Plains (IGPs), the heart land of the rice–wheat rotation (RWR)3. The relatively greater yields of the RWR in the upper IGPs materialized at the costs of the over utilization of the natural resources4,5, which caused nutrient imbalances, greater energy use and increased labour demands, weed shift/resistance and more GHGs emissions6,7. Further, rice residue burning is one of the realised threats of the RWR sustainability, which resulted in the extensive impacts on the losses of soil organic matter (SOM) and nutrients, reduced biodiversity, lowered water and energy efficiency, and of course the declined air quality. In India’s capital and other adjoining north Indian cities, the residue burning reduces air quality, with severe impacts on human and animal health8,9. Hence, these ruinous factors have given impetus to pursue alternative crops/rotations or to follow the integrated sustainable strategies in the line of UN Sustainable Development Goals, i.e., more environmentally sound and efficient utilizer of resources10–12.
The maize adaptability to diverse agro-ecologies or across seasons is unmatched to any other crops. It can be a feasible alternative to the rice in RWR, and a potential driver for the crop diversification13,14. In India, it covers ~ 9.5 million hectares with 24.5 million tonnes annual production, and 3rd most important food crop next to rice and wheat2. It is consumed in the form of grains, green cobs, sweet corn, baby corn and popcorn, besides its use as animal feed, fodder and raw material for the industrial products such as food (25%), animal feed (12%), poultry feed (49%), starch (12%), brewery and seed15. The intensive tillage with crop establishment accounts ~ 25% of the total production cost, leading to the reduced net income16. Here, the major challenge is to develop the alternative production system that should be climate and resource resilient, and can help to sustain the crop yields in the long-run17. Recently, the CA-based crop management, such as no-till or zero-till and bed plantings with residue retention and judicious crop rotations, is gaining more attention with the rising concerns pertaining to the over degradation of the natural resources, to offset the production cost18. Both the crops (maize, wheat) could be well fitted, and may prove input responsive in the CA-based practices19,20. A great potential exists to raise the yields and sustainability of the maize-wheat rotation (MWR) further by combining the CA-based production with certain integrated crop management (ICM) practices. Thus, need was felt to find out the best combinations of the ICM practices to accomplish the sustainability of the MWR. It is reported that these ICM practices can help in the initial crop establishment with greater input efficiency, and open up avenues for CA-based ICMs which could further help in the timely seeding of the both crops, hence may lead to the sustained yields without compromising the degradation of the natural resources.
Recently, the Food and Agriculture Organisation (FAO) has suggested that the ICM is of much significance and relevance than the individual agronomic management approach. The ICM is fundamentally based on the understanding of the interactions between the biology, environment and the land management systems apart from conserving the natural resources and producing the food on an economically viable and sustainable platform21. Adoption of the ICM practices significantly improved the crop yields to the tune of 20–30% in India22, and 13.5% in China23 over the farmers’ practice, while minimizing the production costs simultaneously24,25. In RWR, a recent long-term study showed the superiority of the ICM-based modules, with 10–13% greater system yields, saved 8–12% irrigation water, and gave 19–22% additional economic returns over the CT-based modules5.
Therefore, the integration of the ICM practices along with the CA-background needs to be developed in a holistic manner so as to achieve the long-term sustainability and profitability of the MWR. With this hypothesis, we have evaluated the different ICM modules for five years in a MWR of the north-western India, chiefly aimed to improve the crop and water productivity, economic profitability, sustainability and soil biological properties.
Results
Five years’ trends and pooled maize grain and stover yields
During the initial year, the maize grain yield did not differ significantly among the ICM modules, although the highest yield was recorded under the ICM8. Nevertheless, from the second year onwards, the different ICM modules had the significant (p < 0.05) impacts on the maize grain yield (Fig. 1a). The ICM7 consistently produced the highest yield across the years, which was closely followed by the ICM8. Similarly, the highest stover yield across the years was recorded with ICM7, except first year (Fig. 1b). The highest pooled grain (5.2 Mg ha−1) and stover (8.7 Mg ha−1) yields were recorded with the ICM7, being close to the ICM3-6&8. On an average, the ICM7&8 had produced 5.9–21% and 5.8–18.4% greater grain and stover yields, respectively, over the ICM1-6 (Table 1).
Table 1.
Treatment | Maize | Wheat | ||
---|---|---|---|---|
Grain | Stover | Grain | Straw | |
ICM1 | 4.1b ± 0.33 | 7.2b ± 0.52 | 4.4a ± 0.16 | 6.7a ± 0.20 |
ICM2 | 4.1b ± 0.11 | 7.1b ± 0.40 | 4.3a ± 0.23 | 6.7a ± 0.39 |
ICM3 | 4.4ab ± 0.27 | 7.8ab ± 0.21 | 4.3a ± 0.20 | 6.7a ± 0.39 |
ICM4 | 4.2ab ± 0.11 | 7.9ab ± 0.26 | 4.3a ± 0.30 | 6.6a ± 0.50 |
ICM5 | 4.8ab ± 0.35 | 8.1ab ± 0.45 | 4.8a ± 0.19 | 7.3a ± 0.09 |
ICM6 | 4.6ab ± 0.22 | 7.9ab ± 0.43 | 4.8a ± 0.35 | 7.2a ± 0.57 |
ICM7 | 5.2a ± 0.15 | 8.7a ± 0.39 | 4.9a ± 0.14 | 7.3a ± 0.08 |
ICM8 | 5.1a ± 0.19 | 8.6a ± 0.16 | 4.8a ± 0.11 | 7.7a ± 0.04 |
#ICM1&2 = conventional flatbed maize & wheat (CTFB); ICM3&4 = conventional raised bed maize & wheat (CTRB); ICM5&6 = zero-till (ZT) flatbed maize with wheat residue at ~ 3 Mg ha−1 (ZTM + WR) & ZT wheat with maize residue at ~ 5 Mg ha−1 (ZTW + MR), and ICM7&8 = ZT raised bed maize with wheat residue (ZTRB + WR) & ZT wheat with maize residue (ZTRB + MR). #RDF = recommended fertilizers for maize / wheat 150:26.2:50 / 120:26:33 NPK kg ha−1; LBFs = NPK liquid bio-fertilizer; AMF = arbuscular mycorrhizal fungi.
Five years’ trends and pooled wheat grain and straw yields
The different ICM modules did not impact the wheat grain yield significantly during the first three years. While, at the fourth year, the ICM5 had the highest yield, being significantly higher than the ICM1-3, and subsequently in the fifth year, it was ICM8 which outperformed significantly (p < 0.05) over the ICM4 (Fig. 1c). Similarly, the straw yield did not differ significantly among the ICM modules in the initial three years, but significantly a greater yield was registered with the ICM8 in the fourth and fifth years (Fig. 1d). However, the mean grain and straw yields under the ICM5-8 (CA-based ZT) was 8.4–11.5% and 7–14% greater than the CT-based residue removed (ICM1-4) modules (Table 1).
System yields in terms of maize grain equivalents
The ICM modules had a significant impact on the maize grain equivalents (MGEY) across the years, except during the initial two years (2015–16 and 2016–17), wherein the ICM7 produced the highest yield during the 2017–18 and 2019–20, which was significantly greater than the ICM1-4 to the tune of 19–22% and 17–26%, respectively. While, in 2018–2019, the highest yield was recorded with the ICM8, which was significantly higher than the ICM1-4 by 16–22%. Averaged across the five years, the ICM5-8 had 6–15% system MGEY advantage over the ICM1-4 (Table 2).
Table 2.
Treatment | System maize grain equivalents (MGEY) | ||||
---|---|---|---|---|---|
2015–16 | 2016–17 | 2017–18 | 2018–19 | 2019–20 | |
ICM1 | 8.5a ± 0.94 | 9.9a ± 0.68 | 8.7bcd ± 0.25 | 9.3bc ± 0.65 | 9.7bc ± 0.54 |
ICM2 | 9.6a ± 0.95 | 9.2a ± 1.01 | 8.4d ± 0.58 | 9.0c ± 0.63 | 9.1c ± 0.53 |
ICM3 | 10.5a ± 0.21 | 9.1a ± 1.38 | 8.6 cd ± 0.30 | 9.5bc ± 0.23 | 9.8bc ± 1.53 |
ICM4 | 9.6a ± 0.80 | 9.7a ± 1.09 | 8.6 cd ± 0.36 | 9.7bc ± 0.26 | 8.7c ± 0.90 |
ICM5 | 9.7a ± 1.36 | 9.8a ± 1.45 | 10.3ab ± 1.11 | 11.4a ± 0.62 | 10.9ab ± 0.71 |
ICM6 | 10.0a ± 1.95 | 8.8a ± 1.16 | 10.1abc ± 0.70 | 10.8ab ± 0.55 | 11.0ab ± 0.66 |
ICM7 | 10.1a ± 0.66 | 10.2a ± 0.66 | 10.8a ± 0.83 | 11.5a ± 0.45 | 11.8a ± 1.15 |
ICM8 | 10.2a ± 1.50 | 10.0a ± 0.14 | 10.0abc ± 0.51 | 11.6a ± 0.64 | 11.7a ± 1.03 |
#ICM1&2 = conventional flatbed maize & wheat (CTFB); ICM3&4 = conventional raised bed maize & wheat (CTRB); ICM5&6 = zero-till (ZT) flatbed maize with wheat residue at ~ 3 Mg ha−1 (ZTM + WR) & ZT wheat with maize residue at ~ 5 Mg ha−1 (ZTW + MR), and ICM7&8 = ZT raised bed maize with wheat residue (ZTRB + WR) & ZT wheat with maize residue (ZTRB + MR). #RDF = recommended fertilizers for maize / wheat 150:26.2:50 / 120:26:33 NPK kg ha−1; LBFs = NPK liquid bio-fertilizer; AMF = arbuscular mycorrhizal fungi.
System water use and productivity
The system water use (TWU) (irrigation + Ep) differed across the years. The highest water was consumed (1434–1753 kg ha−1 mm−1) in the ICM1&2, while it was relatively lesser under the ICM3-8 (1324–1663 kg ha−1 mm−1). On an average, the ICM3-8 saved 6.5% system water use compared to the ICM1&2 (Fig. 2a). In contrast, the highest water productivity (WP) was observed with the ICM3 (2015–16), ICM7 (2016–17, 2017–18), and ICM8 (2018–19). While, in 2019–20, the ICM7&8 produced the similar WP, but significantly higher than the ICM1-4. The average WP under CA-based residue retained modules (ICM5-8) was 7.7–19.6% greater than the CT (ICM1-4) practices (Fig. 2b).
System variable production costs and economic returns
Across the years, the variable input costs differed among the ICM modules. The highest system input cost was incurred with the ICM3 (US$1001–1145 ha−1 yr−1), while the least was under the ICM6 (US$868–991 ha−1 yr−1). On an average, the ICM1-4 had 9.54% greater variable production costs compared to the ICM5-8 (Fig. 3a). Furthermore, the ICM7&8 gave the highest net economic returns, resulting chiefly due to greater yields and lesser production costs incurred. The average increment in the net returns under the ICM7&8 was 23.6–29.5% compared to the ICM1-4 (Fig. 3b).
Soil properties
The ICM modules had a significant impact on the variable soil properties i.e., soil organic carbon (Soc), microbial biomass carbon (SMBC), dehydrogenase activity (SDH), alkaline phosphatase (SAP) and soil urease (URE) activities (Fig. 4, Table 3).
Table 3.
Treatment | SDH (µg TPF g−1 fresh soil d−1) | SAP (µg p-NP g−1 soil h−1) | URE (µg NH4-N g−1 soil h−1) | ||||||
---|---|---|---|---|---|---|---|---|---|
0.0–0.05 m | 0.05–0.15 m | 0.15–0.30 m | 0.0–0.05 m | 0.05–0.15 m | 0.15–0.30 m | 0.0–0.05 m | 0.05–0.15 m | 0.15–0.30 m | |
ICM1 | 58.3c | 26.1cd | 13.2ab | 54.3d | 44.6bc | 27.1a | 14.2c | 11.8c | 7.6a |
ICM2 | 53.2d | 22.0d | 13.4ab | 49.8d | 38.9c | 30.2a | 15.6bc | 12.6bc | 6.5a |
ICM3 | 57.4cd | 26.5cd | 15.7a | 61.8c | 44.9bc | 32.8a | 14.7c | 12.3bc | 6.1a |
ICM4 | 62.0bc | 28.7bc | 13.4ab | 52.9d | 43.5c | 28.9a | 16.3abc | 11.7c | 8.4a |
ICM5 | 60.9bc | 26.5cd | 16.4a | 66.0bc | 51.9a | 30.6a | 18.5ab | 13.5abc | 8.6a |
ICM6 | 67.3a | 29.5abc | 15.5a | 70.4ab | 56.3a | 28.9a | 19.4a | 14.7ab | 7.7a |
ICM7 | 63.3ab | 31.9ab | 13.8ab | 72.0a | 51.1ab | 31.6a | 18.5ab | 13.7abc | 7.8a |
ICM8 | 65.2ab | 34.7a | 11.7b | 73.6a | 42.6c | 31.4a | 19.5a | 16.1a | 7.7a |
#ICM1&2 = conventional flatbed maize & wheat (CTFB); ICM3&4 = conventional raised bed maize & wheat (CTRB); ICM5&6 = zero-till (ZT) flatbed maize with wheat residue at ~ 3 Mg ha−1 (ZTM + WR) & ZT wheat with maize residue at ~ 5 Mg ha−1 (ZTW + MR), and ICM7&8 = ZT raised bed maize with wheat residue (ZTRB + WR) & ZT wheat with maize residue (ZTRB + MR). #RDF = recommended fertilizers for maize / wheat 150:26.2:50 / 120:26:33 NPK kg ha−1; LBFs = NPK liquid bio-fertilizer; AMF = arbuscular mycorrhizal fungi.
Soil organic carbon (Soc)
In the top 0.00–0.05 m soil depth, the highest Soc was recorded with the ICM7, which was significantly higher than the ICM2&4. The increment in Soc under the ICM7&8 over the ICM1-4 was to the tune of 10.2–16.2%. Further, in the 0.05–0.15 m soil depth, the highest Soc was recorded with the ICM6, wherein it was significantly more than the ICM3, but statistically (p < 0.05) similar to the ICM1,2,4,5,7&8. While, there were no significant differences among the ICM modules, with respect to the Soc, in the 0.15–0.30 m soil depth (Fig. 4a).
Soil microbial biomass carbon (SMBC)
The highest SMBC in the 0.00–0.05 m soil depth was observed under the ICM8, wherein it was similar to the ICM5&6, but significantly higher than the ICM1-4&7. The ICM8 had 6–23% greater SMBC than the ICM1-4. While, in the 0.05–0.15 m soil depth, the highest SMBC was recorded in the ICM6, being significantly greater than the ICM1-5 to the tune of 12–22.8%, but similar to the ICM7&8. In contrast, at lower soil depth (0.15–0.30 m), the highest SMBC was observed under the ICM3, and being greater than that of the ICM1,2&4–8 (Fig. 4b).
Soil dehydrogenase activity (SDH)
The ICM6 had the highest SDH which was similar with the ICM7&8, but significantly greater than the ICM1-5 to the tune of 7.8–21% in the top 0.00–0.05 m soil depth. Further, in the second depth (0.05–0.15 m), the ICM8 recorded the highest SDH, wherein it was similar to the ICM6&7, but shown 17–36.6% greater SDH than the ICM1-5. In the 0.15–0.30 m soil depth, ICM5 resulted in the highest SDH. Averaged across the soil depths, the ICM6-8 gave 4–21% higher SDH than the ICM1-5 (Table 3).
Soil alkaline phosphatase (SAP)
The highest SAP in the top 0.00–0.05 m soil depth was recorded with the ICM8, being significantly higher than the ICM1-5, but similar to the ICM6&7. Indeed, the ICM7&8 resulted in 8.3–32.3% higher SAP compared to the ICM1-5. While, in the 0.05–0.15 m soil depth, the highest SAP was observed with the ICM6, where it was significantly more than the ICM1-4&8, but at par with the ICM5&7. Further, at 0.15–0.30 m, no significant difference in SAP was noticed among the ICM modules (Table 3).
Soil urease (URE)
The URE in the 0.00–0.05 m soil depth was the highest with the ICM8, in which it was similar to the ICM4-7, but significantly greater than the ICM1-3. The increment in URE under ICM7&8 over the ICM1-4 (CT modules) was to the tune of 12.7–27.2%. Similarly, in the 0.05–0.15 m, the highest URE was recorded with the ICM8, which was significantly greater than the ICM1-4, but similar to the ICM5-7. As expected, the ICM7&8 produced 8–27% higher URE compared to the ICM1-4. However, in the lowest soil layer (0.15–0.30 m), no significant differences in URE were observed among the ICM modules (Table 3).
Sustainable yield index (SYI)
Among the ICM modules in the maize, the ICM7 had the greater SYI, but being at par to the ICM1,5,6&8, which was 12–15.2% greater than the ICM2-4. Again, SYI in wheat was the highest under the ICM7, similar with ICM5&8, being 17.9–25.3% greater than the CT-based ICM1-4 modules. In the case of MWR, the SYI was the highest under the ICM7&8, which was 13.4–18.6% higher than the ICM1-4, and similar to ICM5 (Fig. 5).
Discussion
The rice–wheat is the commanding rotation in northern India’s ecologies. However, of late, from the resource exploitation to their judicious use for sustained yield, save water and improve soil-based properties is the focus19,26, besides achieving SDGs12. Seeing the degradation of natural resources, stagnation in crop yields and other constraints in adoption of rice–wheat rotation (RWR), it is thus noteworthy to identify the alternative crops and cropping rotations to sustain the food security. Maize ˈQueen of cerealsˈ being a C4 plant, has wider adaptability under the diverse climate, thus could be a striking substitute of rice2. Every year, in the rice–wheat belt of north western India, the ground water falls off by 0.30–0.40 m27, and therefore, acreage under maize is likely to increase with the time. It is clearly evident that rice is the main water consumer28, maize could be a potential choice for accompanying wheat in this area, as it saves irrigation water, fulfils demand for palatable fodder and industries. Rice residue burning rather than returning to the soil, is another concern which not only deteriorates the air quality, but also have acute effects on human health8. Thus, the MWR has a potential to replace the water guzzling rice under the RWR. The CA-based ICM practices in MWR would intend for sustainable residue recycling, improve soil properties19,29 and sustain long-term production30.
Our findings confirmed the yield gains (14.6%, maize; 11.2%, wheat) under the CA-based ICM5-8 over the ICM1-4, however, the MGEY enhanced by 12.3% (5 years’ av.). The ICM5-8, proved superior because of ZT, crops residue, and eventually the efficient use of inputs31,32 along with LBFs consortia and AMF. Most soil organic matter (SOM) originates from the residues, and crops produce is positively linked with SOM33; crops residue retention helps SOM build up, soil temperature moderation, improved water holding capacity, microbial and enzymatic activities, and nutrients mobilization in the rhizospheric zone34,35. In cereals, AMF has extraordinary importance in boosting the yields36, and has capacity to acquire immobile nutrients beyond the radius of roots through their hyphal network37,38 owing to greater nutrients/water taken up39,40, ultimately improve yields41,42.
ICM5-8 increased 0.49 Mg ha−1 pooled wheat yield, but was 0.73 Mg ha−1 in maize, whereas, the yield advantage was more (0.96 Mg ha−1) with ZT bed planted maize (ICM7-8) than to the ICM1-4 (Table 1, Fig. 1). Excess (heavy rains) and deficit (longer dry spells) moisture are the common obstacles in the rainy season maize ecologies, but such variability does not exist during winters (wheat season). Residue retention in the ICM5-8 infiltrate more water (Fig. 6d), and creates better aeration for the maize crop, bed planted maize (ICM7&8) combining residues recorded yield advantage. Some meta-analysis studies have shown that the AMF helps to tolerate such stresses43,44. The LBFs fixes atmospheric-N and helps in solubilizing the insoluble P compounds which facilitate nutrient uptake, and improves the soil fertility, thereby, reduces the rate of chemical fertilizers up to 25%.
Water productivity (WP) is the crop yield unit−1 of water consumption. Five years’ results delineated that the ICM5-8 could save ~ 7% irrigation water, compared to the ICM1&2 (Fig. 2a). Long-time ZT tilled conditions where residues are retained, not only conserve the soil water, but facilitate better moisture regimes in the effective rhizosphere, and resulted in greater WP32,45. In the ICM5-8 modules, the surface residues could reduce the losses of water vapour and retained moisture for the longer period, thus requiring lesser irrigations. Further, the bed planting coupled with the crops residues has twin benefits of greater infiltration and lower water application rates4,46,47,80. In 2017–18 and 2018–19, the higher WP was associated with the least water input coupled with greater yields than in other years (Fig. 2b).
Modules ICM5-6 being lesser expensive, on account of lesser tillage operations involved and thus saved labor costs in various physical field operations, whereas, the ICM7-8 were relatively costlier as these involved extra expenses in reshaping the beds (Fig. 3a). While, the ICM1&4 incurred the highest cost owing to more trafficking in different tillage operations48. The sequential tillage included the extra fuel cost, eventually these modules gave lower yield, as indicated in the inclination of economic net returns5. Of course, the timely sowing of the succeeding wheat under the ZT conditions gave yield advantage49,50 with the improved economic returns48. These results also reinforce the earlier research work in the adjoining ecologies32,49,51.
The ICM based agronomic management have vital role in the soil profile activities, and sustaining the soil health in the long-run52. Continuous crop residues recycling significantly improves the SOC fractions53 and total SOC45. These CA-based practices have been widely analyzed for improving the SOC and the microbial population size54. Interestingly, over the years, the ZT + residues could increase the SOC, particularly by releasing the considerable rhizo-depositions through hidden half and lower decaying rates40. Our results showed that the SOC changed remarkably in the top soil layers, and ICM5-8 increased the SOC storage by 12.1% in the top soil layer over the CT-based ICM1-4 (Fig. 4a), as intensive tillage operations facilitate the loss of SOC, which is undesirable for the global C balance45,55.
The SMBC is the living component (i.e., bacteria and fungi) of SOM, being the key indicator for SOC. In spite of small size, being a labile pool of SOM56, it contributes to the transformation or cycling of SOM57,58. In this study, the CA-based residue retained modules had 13.7% greater SMBC in the 0.0–0.15 soil layers than the modules where residues were removed (Fig. 4b), as regular residue addition accumulated the soil C that enhanced the SMBC and other microbial activities46,59. Moreover, the ZT conditions with sufficient crops residue are more conducive for the fungal hyphae growth, with additional supply of AMF along with LBFs further enhanced the fungal population and diversity, which could play an important role in the C / N cycling through their hyphal networks60. The SDH is the most intuitive bioindicators, describing the soil fertility61. It is associated with the SOM oxidation, and its activity depends on the microorganisms’ abundance and activity62. Current results showed a 10.1% improvement in the SDH activity under the CA-based ICM5-8 modules, over CT-based practices (Table 3). The SMBC and SDH activities are directly associated with the recycling of the organic amendments, such as, the crops residues46,63.
Phosphatase activity is needed for P-mineralization and release of the PO43− for the plant uptake. Often it is stated that the phosphatase activities (alkaline / acid) are greater in the P deficient soils65, and the current study soils are alkaline in nature (pH 7.9) with only 13 kg ha−1 available P. The P deficiency, residue addition and stoichiometric changes66 would exhilarate the phosphatase activity under the CA-based modules. The urease activity responsible for the N mineralization and NH3 release through hydrolysing the C–N bond of the amides67. The residue based ICMs recorded greater urease, as residues acts as a substrate for the urease, and eventually help in increasing the N availability for plant uptake. The SOC, SMBC, SDH, APA and URE activities are directly linked with and the soil biological properties, and hence the soil fertility. We conclude that the CA-based residue retained modules of MWR improved crops yields, farm economic profitability, and conserved the soil moisture. Such practices could also supplement the nutrients, sustain the crop yields, conserve natural resources, especially water and boost up the soil microbial functions for the long-term sustainability.
Conclusions
The five years' results clearly indicated the superiority of the CA-based residue retained ICM5-8 modules, which produced 9.5–14.3% greater system maize grain equivalents (MGEY) over the CT-based modules (ICM1-4). Further, the ICM2-8 saved 6.5–8.0% irrigation water, and ICM5-8 recorded 10.3–17.8% higher system WP than the residue removed (ICM1-4) modules. Of course, the conventional modules (ICM1-4) were expensive, however, ICM5-8 gave 24.3–27.4% extra returns than the ICM1-4, eventually made them economically more profitable. The residue retained modules (ICM5-8) registered 7.1–14.3% (0.0–0.15 m) greater SOC than the ICM1-4, indicating the positive impacts of the residue addition which would be useful in sustaining the soil health in long-run. On an average, in 0.0–0.15 m depths, the soil biological activities i.e., SMBC (10.1–16.7%), SDH (10–15.6%), SAP (14.8–18.1%), and URE (16.5–20%) increased in the ICM5-8 compared to the ICM1-4, thus the effect of residue retention was more pronounced in the upper soil layers than in lower depths. Further, there is a need to change regional growers’ perceptions towards the adoption of maize, it could be a potential choice for accompanying wheat in this area. Therefore, the ZT residue retained modules either ICM7&8 or ICM5&6 could be acceptable for their adoption in the MWR for improving the yields, economic profitability and soil biological properties in the north western India and probably in other similar agro-ecologies.
Materials and methods
Experimental site, location and climate
Five years’ field experimentation on ICM was started in 2014–15 at the ICAR-Indian Agricultural Research Institute (28°35′ N latitude, 77°12′ E longitude, 229 m MSL), New Delhi, India. The study site comes under the 'Trans IGPs', being semi-arid with an average annual rainfall of 650 mm, of which ~ 80% occurs in July–September (south-west monsoon). The mean max. / min. air temperature ranges between 20-40ºC and 4-28ºC, respectively. The five years (2014–2019) weather data were recorded from the observatory adjoining to the experimental field, and presented in Supplementary Table 1. Before start of the experiment, a rainy season Sesbania was grown in 2014 to ensure the uniform fertility across the blocks. Initial soil samples (0.0–0.15 m depth) were collected in October 2014 after incorporating the Sesbania residues in soil. The soil samples were processed for the chemical analysis. The study site had a pH of 7.9 (1:2.5 soil and water ratio)68, 3.8 g kg−1 soil organic-C69, 94.1 kg ha−1 KMnO4 oxidizable N70, 97 µg g−1 soil microbial biomass carbon71, 51.3 μg PNP g−1 soil h−1 alkaline phosphatase72, 53.0 μg TPF g−1 soil d−1 dehydrogenase73, and 13.5 μg NH4-N g−1 soil h−1urease74.
Description of different ICM modules
The eight ICM modules were tested, comprising of four conventional tillage (CT)-based (ICM1-4) and four conservation agriculture (CA)-based (ICM5-8) modules, replicated thrice in a complete randomized block design with the plot size of 60 m2 (15 m × 4.5 m) (Table 4). The crop residues were completely removed in the CT-based modules (ICM1-4), while in the ICM5-8 modules, in-situ wheat (~ 3 Mg ha−1 on dry weight basis)) and maize (~ 5 Mg ha−1, on dry weight basis) residues were retained on the soil surface during all the seasons of crops cultivation (Footnote Table 4, Fig. 6a,b).
Table 4.
Treatment notations | Maize | Wheat |
---|---|---|
ICM1 | CTFB + 100% RDF | CTFB + 100% RDF |
ICM2 | CTFB + 75% RDF + AMF + LBFs | CTFB + 75% RDF + AMF + LBFs |
ICM3 | CTRB + 100% RDF | CTRB + 100% RDF |
ICM4 | CTRB + 75% RDF + AMF + LBFs | CTRB + 75% RDF + AMF + LBFs |
ICM5 | ZTM + WR + 100% RDF | ZTW + MR + 100% RDF |
ICM6 | ZTM + WR + 75% RDF + AMF + LBFs | ZTW + MR + 75% RDF + AMF + LBFs |
ICM7 | ZTRB + WR + 100% RDF | ZTRB + MR + 100% RDF |
ICM8 | ZTRB + WR + 75% RDF + AMF + LBFs | ZTRB + MR + 75% RDF + AMF + LBFs |
#ICM1&2 = conventional flatbed maize & wheat (CTFB); ICM3&4 = conventional raised bed maize & wheat (CTRB); ICM5&6 = zero-till (ZT) flatbed maize with wheat residue at ~ 3 Mg ha−1 (ZTM + WR) & ZT wheat with maize residue at ~ 5 Mg ha−1 (ZTW + MR), and ICM7&8 = ZT raised bed maize with wheat residue (ZTRB + WR) & ZT wheat with maize residue (ZTRB + MR). #RDF = recommended fertilizers for maize / wheat 150:26.2:50 / 120:26:33 NPK kg ha−1; LBFs = NPK liquid bio-fertilizer; AMF = arbuscular mycorrhizal fungi.
#Integrated weed management (maize): ICM1-4 = atrazine-pre-emergence (PE) fb 1hand weeding (HW) mulch; ICM5-8 = glyphosate-preplant (PP) + atrazine-PE fb I HW mulch. IWM (wheat): ICM1-4 = sulfosulfuron 75 + metsulfuran-methyl (total)-PoE; ICM5-8 = glyphosate-PP fb pendimethalin-PE & total PoE. #Need-based integrated pest management (IPM) and disease management (IDM) were followed in all the ICM modules.
In the ICM1-4 modules, the field preparation was carried out by sequential tillage operations, such as, deep ploughing using the disc harrow, cultivator/rotavator twice (0.15–0.20 m), followed by levelling in each season. In the ICM3-4, the raised beds of 0.70 m bed width (bed top 0.40 m and furrow 0.30 m) were formed during each cropping cycle using the tractor mounted bed planter, and simultaneously wheat sowing was done (Fig. 6c). In the case of maize, ridges (0.67 m length) were prepared using the ridge maker. In the CA-based ICM5-8 modules, the tillage operations, such as, seed and fertilizer placement were restricted to the crop row-zone in maize and wheat both. In the ICM7&8, the permanent raised beds (0.67 m mid-furrow to mid-furrow, 0.37 m wide flat tops, and 0.15 m furrow depth), were prepared (Fig. 6d). However, these beds were reshaped using the disc coulter at the end of each cropping cycle without disturbing the surface residues. The sowing was accomplished using the raised bed multi-crop planter.
Cultural operations and the fertilizer application
During every season, the maize (cv. PMH 1) was sown in the first week of July using 20 kg seed ha−1. The wheat (cv. HD 2967) crop was sown in the first fortnight of November using the seed-cum fertilizer drill (ICM1-2), bed planter (ICM3-4) and zero-till seed drill (ICM5-8) at 100 kg seed ha−1. The chemical fertilizers (N, P and K) were applied as per the modules described in the footnote of Table 4. At sowing, the full doses of phosphorous (P) and potassium (K) were applied using the di-ammonium phosphate (DAP) and muriate of potash (MOP), and the nitrogen (N) supplied through DAP. The remaining N was top-dressed through urea in two equal splits after the first irrigation and tasseling / silking stages in maize, and crown root initiation and tillering stages of wheat. In the modules receiving ¾ fertilizers (ICM2,4,6,8), the seeds were treated with the NPK liquid bio-fertilizer (LBFs) (diluted 250 ml formulation 2.5 L of water ha−1), and an arbuscular mycorrhiza (AMF) was broadcasted at 12 kg ha−1 as has been described by75. This LBFs had the microbial consortia of N-fixer (Azotobacter chroococcum), P (Pseudomonas) and K (Bacillus decolorationis) solubilizers, procured from the commercial biofertilizer production unit of the Microbiology Division, ICAR-Indian Agricultural Research Institute, New Delhi (Patentee: ICAR, Govt. of India). Weeds were managed by integrating the pre- and post-emergence herbicides, and their combinations along with the hand weeding-mulching, as mentioned in the concerned modules (Footnote Table 4). However, in the CA-based modules (ICM5-8), the non-selective herbicide glyphosate (1 kg ha−1) was used 10 days before the sowing. The need-based integrated insect-pests and disease management practices were followed uniformly across the modules.
Soil sampling and analysis
Before start of the experiment, the soil sampling was done from 0.0–0.15 m depth. Afterwards, five random samples from each module from 0.0–0.30 m soil depth were collected at the flowering stage of 5th season wheat. These samples were taken from the three soil depths (0.0 to 0.05, 0.05–0.15 and 0.150–0.30 m) using the core sampler. The ground, air-dried soil samples, passed through a 0.2 mm sieve were used for the determination of the Walkley and Black organic carbon (SOC), as described by76. For the soil biological properties, the soil samples were processed, and stored at 5ºC for 18–24 h, then analyzed the soil microbial biomass carbon (SMBC), dehydrogenase (SDH), alkaline phosphate (SAP) and the urease (URE) activities.
The soil microbial biomass carbon (SMBC)
The SMBC was measured using the fumigation extraction method as proposed by71. The pre-weighed samples from the respective soil depths were fumigated with the ethanol-free chloroform for the 24 h. Separately, a non–fumigated set was also maintained. Further, 0.5 M K2SO4 (soil: extractant 1:4) was added, and kept on a reciprocal shaker for 30 min. and then filtered through a Whatman No. 42 filter paper. OC of the filtrate was measured through the dichromate digestion, followed by the back titration with 0.05 N ferrous ammonium sulphate. The SMBC was then calculated using the equation:
where, EC = (Corg in fumigated soil – Corg in non-fumigated soil), and expressed in µg C g−1 soil.
The dehydrogenase activity (SDH)
The SDH activity (μg TPF g−1 soil d−1) was assessed using the method of73. The soil sample (~ 6 g) was saturated with 1.0 ml freshly prepared 3% triphenyltetrazolium chloride (TTC), and then incubated for 24 h under the dark. Later on, the methanol was added to stop the enzyme activity, and the absorbance of the filtered aliquot was read at 485 nm.
The alkaline phosphatase activity (SAP)
The APA activity was estimated in 1.0 g soil saturated with 4 ml of the modified universal buffer (MUB) along with 1 ml of p-nitrophenol phosphate followed by incubation at 37 °C for 1 h. After incubation, 1 ml of 0.5 M CaCl2 and 4 mL of NaOH were added and the contents filtered through Whatman No. 1 filter paper. The amount of p-nitrophenol in the sample was determined at 400 nm72 and the enzyme activity was expressed as µg p-NP g−1 soil h−1.
The urease activity
Urease activity was measured using 10 g soil suspended in 2.5 ml of urea solution (0.5%). After incubating for a day at 37 °C, 50 ml of 1 M KCl solution was added. This was kept on a shaker for 30 min and the aliquot was filtered through Whatman No. 1 filter paper. To the filtrate (10 ml), 5 ml of sodium salicylate and 2 ml of 0.1% sodium dichloro-isocyanide solution were added and the green color developed was measured at 690 nm74. These values are reported as µg NH4-N g−1 soil h−1.
Water application and productivity
In experimental modules, water was given through the controlled border irrigation method. The current meter was fixed in the main lined rectangular channel, and the water velocity was measured. To get the flow discharge, then multiplied with area of cross section of the channel. The following formulae were used to calculate the applied irrigation water quantity and depth3:
where, F is flow rate (m3 s−1), t is time (s) taken in each irrigation in each module and A is area (m2).
The effective precipitation (EP, difference between total rainfall and the actual evapotranspiration) was calculated, and then EP was added to the irrigation water applied to calculate the total water applied in each module. Across the maize and wheat modules (ICM1-8), irrigations were given at the critical growth stages, such as, knee high and silking / tasseling (maize) and crown root formation, maximum tillering, flowering, heading / milking (wheat) stages, and after long dry spell (≥ 10-days).
On the basis of the soil water depletion pattern (at the depth of 0.60 m), in each season, 3–6 irrigations were given to maize, while wheat received 5–8 irrigations per season or crop including the pre-sowing irrigation. The rainfall data were obtained from the meteorological observatory located in the adjoining field. The water productivity (kg grains ha−1 mm−1 of water) was measured as per the equation given below:
Additionally, the systems water productivity (SWP) was also estimated by adding the water productivity (WP) of both maize and wheat crops grown under the MWR.
Yield measurements
In each season, the maize and wheat crops were harvested during the months of October and April, respectively, leaving 0.75 m border rows from all the corners of each module. The crops were harvested from the net sampling area (6 m × 3 m, 18 m2) located at the center of each plot. Maize crop was harvested manually and the wheat by using the plot combine harvester. All the harvested produce was sun dried before threshing and the grain and straw / stover yields were weighed separately. The stover/straw yields were measured by subtracting the grain weight from the total biomass. To compare the total (system) productivity of the different ICM modules, the system yield was computed, taking maize as the base crop, i.e., the maize equivalent yield (MGEY) using the equation20:
where, Ym = maize grain yield (Mg ha−1), Yw = wheat grain yield (Mg ha−1), Pm = price of maize grain (US$ Mg−1) and Pw = price of wheat grain (US$ Mg−1).
Farm economics
Under different ICM modules, the variable production costs and economic returns were worked out based on the prevailing market prices for the respective years. The production costs included the cost of various inputs, such as, rental value of land, seeds, pesticides, LBFs / consortia, AMF, labor, and machinery; tillage / sowing operations, irrigation, mineral fertilizers, plant protection, harvesting, and threshing etc. The costs for the crops’ residues were also considered. The system total returns were computed by adding the economic worth of the individual crop, however, the net returns were the differences between the total returns to the variable production costs of the respective module. The Govt. of India’s minimum support prices (MSP) were considered for the conversion of grain yield to the economic returns (profits) during the respective years. Further, the system net returns (SNR) were worked out by summing the net income from both maize and the wheat in Indian rupees (INR), and then converted to the US$, based on the exchange rates for different years.
Sustainable yield index (SYI)
77,78described the SYI as a quantitative measure of the sustainability of agricultural rotation/practice. The sustainability could be interpreted using the standard deviation (σ) values, where the lower values of the σ indicate the greater sustainability and vice-versa. Total crop productivity of maize and wheat under the different ICM modules was computed based on the five years' mean yield data. SYI was calculated using equation78.
where, –ȳa is the average yield of the crops across the years under the specific management practice, σn–1 is the standard deviation and Y–1 m is the maximum yield obtained under the set of an ICM module.
Statistical analysis
The GLM procedure of the SAS 9.4 (SAS Institute, 2003, Cary, NC) was used for the statistical analysis of all the data obtained from different ICM modules to analyze the variance (ANOVA) under the randomized block design79. Tukey’s honest significant difference test was employed to compare the mean effect of the treatments at p = 0.05.
Authors have confirmed that all the plant studies were carried out in accordance with relevant national, international or institutional guidelines.
Supplementary Information
Acknowledgements
Authors acknowledge to the ICAR-Indian Agricultural Research Institute and the Indian Council of Agricultural Research, New Delhi for providing the financial support and necessary facilities in conducting this research. We thank to Dr. O.P. Singh, Dr. M. Pal and field and lab staff for their help during the experimentation and lab studies.
Author contributions
V.P., R.R.Z., N.B., A.K.C., led the research work, planned, supervised, and conducted field experiments, read and edited the manuscript. N.B., R.R.Z., K.D., M.M.P., R.L.C., R.D.J., M.K., H.R., G.M., K.K.L., L.M., collected soil and plant samples and performed chemical analysis, also wrote the initial draft of the manuscript, prepared figures, and tables. D.K. Y.S., A.K., R.D.J., H.R., M.K.K., K.S., R.L.C., A.K.C., R.K.J., project supervision, reviewed, read and edited the manuscript with significant contributions. A.L. performed statistical analysis.
Competing interests
The authors declare no competing interests.
Footnotes
Publisher's note
Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
These authors contributed equally: Vijay Pooniya and Dinesh Kumar.
These authors jointly supervised this work: Karivaradharajan Swarnalakshmi and L. Muralikrishnan.
Contributor Information
Vijay Pooniya, Email: vpooniya@gmail.com.
Dinesh Kumar, Email: dineshctt@yahoo.com.
Karivaradharajan Swarnalakshmi, Email: swarna_bga@yahoo.com.
R. L. Choudhary, Email: ramlalkherwa@gmail.com
Rajkumar Jat, Email: R.Jat@cgiar.org.
L. Muralikrishnan, Email: muraliagextension@gmail.com
Supplementary Information
The online version contains supplementary material available at 10.1038/s41598-022-05962-w.
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