Increased Maize Yield Research Articles

A new wavy-canopy architecture shaped by interlaced application of EDAH increases maize yield and lodging resistance at high density

A new wavy-canopy architecture shaped by interlaced application of EDAH increases maize yield and lodging resistance at high density

Agronomic Performance and Grain Yield of Low-Nitrogen-Tolerant Maize Varieties in Two Different Agro-Ecologies

The soil of Ekiti State is low in nitrogen due to continuous cropping, erosion and leaching, which has led to decrease in crop yield. A possible approach to increase maize yield even in soil with low nitrogen nutrient is the use of varieties that are tolerant to soil with low nitrogen. Experiments were conducted in two locations: Ikole-Ekiti (derived savanna) and Ikere-Ekiti (tropical rainforest) in Ekiti State, Nigeria. Four low nitrogen tolerant maize varieties developed by the International Institute of Tropical Agriculture Ibadan, Nigeria were obtained; TZEE-W Pop STR C₅, TZEE-W Pop HDT C₃ STR C₅, 2017 TZEE-W HDT STR and 2016 TZEE-W Syn Pop DT STR F₂. Three rates of nitrogen fertilizer, 0 Kg N/ha, 30 kg N/ha and 60 kg N/ha were applied. The three factors experiment were laid out in split-split plot design. Days to silking, anthesis-silking interval, flag leaf, plant height and grain yield significantly (p≤0.05) varied with the location, nitrogen rates and varieties. The results indicated that 60 kg N/ha reduced the grain yield of maize compared to 30 kg N/ha which improved the grain yield of the maize varieties in the two locations (Ikole-Ekiti: 1506.04 kg/ha and Ikere-Ekiti: 952.82 kg/ha). TZEE-W Pop HDT C₃ STR C₅ significantly had the highest grain yield among the varieties in Ikole-Ekiti and Ikere-Ekiti. High nitrogen application reduced the grain yield production of the maize varieties. Thus, low nitrogen level such as 30 kg N/ha is favourable for higher grain yield of low nitrogen tolerant maize varieties.

Variability of climate parameters and food crop yields in Nigeria: A statistical analysis (2010–2023)

This study investigated the variability of climate parameters and food crop yields in Nigeria. Data were sourced from secondary sources and analyzed using correlation and multivariate regression. Findings revealed that pineapple was more sensitive to climate variability (76.17%), while maize and groundnut yields were more stable with low sensitivity (0.98 and 1.17%). Yields for crops like pineapple (0.31 kg/ha) were more sensitive to temperature, while maize, beans, groundnut, and vegetable yields were less sensitive to temperature with yields ranging from 0.15 kg/ha, 0.21 kg/ha, 0.18 kg/ha, and 0.12 kg/ha respectively. On the other hand, maize, beans, groundnut, and vegetable yields were more sensitive to rainfall ranging from 0.19kg/ha, 0.15kg/ha, 0.22 kg/ha, and 0.18 kg/ha respectively compared to pineapple yields which decreased with increase rainfall (−0.25 kg/ha). The results further showed that for every degree increase in temperature, maize, pineapple, and beans yields decreased by 0.48, 0.01, and 2.00 units at a 5 % level of significance, while vegetable yield decreased by 0.25 units and an effect was observed. Also, for every unit increase in rainfall, maize, pineapple, groundnut, and vegetable yields decreased by 3815.40, 404.40, 11,398.12, and 2342.32 units respectively at a 5% level, with an observed effect for maize yield. For robustness, these results were confirmed by the generalized additive and the Bayesian linear regression models. This study has been able to quantify the impact of temperature on food crop yields in the African context and employed a novel analytical approach combining the correlation matrix and multivariate linear regression to examine climate-crop yield relationships. The study contributes to the existing body of knowledge on climate-induced risks to food security in Nigeria and provides valuable insights for policymakers, farmers, government, and stakeholders to develop effective strategies to mitigate the impacts of climate change on food crop yields through the integration of climate-smart agricultural practices like agroforestry, conservation agriculture, and drought-tolerant varieties into national agricultural policies and programs and invest in climate information dissemination channels to help consider climate variability in agricultural planning and decision-making, thereby enhancing food security in the country.

Root Lodging Resistance in Maize (Zea mays L.) Under Conservative Strip‐Till Cultivation System

ABSTRACTRoot lodging significantly affects maize yield and is influenced by both genotypes and soil characteristics. Strip‐till (ST) is a conservative cultivation method that disturbs only the planting strip, leaving the remaining soil undisturbed and covered with maize residues. Less is known about the effect of ST on root lodging. Here, a field experiment was conducted in Northeast China in 2020 and 2021 with 20 maize genotypes to study the relationship between root lodging and soil environment and root system architecture (RSA) under ST. Compared with conventional‐till (CT), in which the maize residues were cleared and the soil was cultivated using a rotary tiller, ST led to a smaller and narrower RSA, with crown root length reduced by 9.5% and crown root biomass reduced by 9.3%. Additionally, inter‐row root expansion angle and width were smaller by 5.3% and 17.3%, respectively. Despite these reductions, the root lodging rate in ST plants was significantly lower than in CT plants, with an absolute decrease of 25.5%. This enhanced resistance is attributed to the increased soil strength in the inter‐row, where the soil bulk density was 10.3% higher and the soil porosity was 10.2% lower in the 0–10 cm layer. Notably, certain maize genotypes, such as ZD958, developed a greater number of fine roots in the compacted inter‐row soil, showing a 66.4% increase compared to XY335 in the 0–12 cm soil layer. This trait contributed to improved resistance to root lodging. In conclusion, ST enhances root lodging resistance and offers opportunities to increase maize yield through optimised management practices, including the selection of high‐yielding cultivars with wide RSA.

Optimizing Irrigation Strategies to Improve Yield and Water Use Efficiency of Drip-Irrigated Maize in Southern Xinjiang

The contradiction between increased irrigation demand and water scarcity in arid regions has become more acute for crops as a result of global climate change. This highlights the urgent need to improve crop water use efficiency. In this study, four irrigation volumes were established for drip-irrigated maize under plastic mulch: 2145 m3 ha−1 (W1), 2685 m3 ha−1 (W2), 3360 m3 ha−1 (W3), and 4200 m3 ha−1 (W4). The effects of these volumes on soil moisture, maize growth, water consumption, crop coefficients, and yield were analyzed. The results showed that increasing the irrigation volume led to a 2.86% to 8.71% increase in soil moisture content, a 24.56% to 47.41% increase in water consumption, and a 3.43% to 35% increase in the crop coefficient. Maize plant height increased by 16.34% to 42.38%, ear height by 16.85% to 51.01%, ear length by 2.43% to 28.13%, and yield by 16.96% to 39.24%. Additionally, soil temperature was reduced by 1.67% to 5.67%, and the maize bald tip length decreased by 6.62% to 48%. The irrigation water use efficiency improved by 6.57% to 28.89%. A comprehensive evaluation using the TOPSIS method demonstrated that 3360 m3 ha−1 of irrigation water was an effective irrigation strategy for increasing maize yield under drip irrigation with plastic mulch in the southern border area. Compared to 4200 m3 ha−1, this strategy saved 840 m3 ha−1 of irrigation water, increased the irrigation water use efficiency by 23.96%, and resulted in only a 0.84% decrease in yield. The findings of this study provide a theoretical foundation for optimizing production benefits in the context of limited water resources.

Leaf angle regulation toward a maize smart canopy.

Dense planting of single-cross hybrids contributes to maize yield increase over the past decades. Leaf angle, an important agronomic trait relevant to planting density, plays a fundamental role in light penetration into the canopy and photosynthetic efficiency. Leaf angle is a key parameter of plant architecture in the concept of smart canopy. Maize smart-canopy-like plant architecture exhibits optimal leaf angle, resulting in erect upper leaves and intermediate or horizontal lower leaves. Leaf angle regulation is a promising way forward in the breeding of varieties with canopy ideotypes. In this review, we first describe the relationship between maize polarity axes and leaf angle formation. Then, we revisit advances in the mutant and quantitative genetics research of maize leaf angle, highlighting the biological implications of transcription factors for maize leaf angle regulation. We underscore that KNOX family is essential for the blade-sheath boundary establishment and brassinosteroid pathway components as well as regulator ZmRAVL1 serve as key hubs of the transcriptional hierarchy governing maize leaf angle formation. We also suggest potential avenues for manipulating maize leaf angles across canopy layers.

Supporting farmers dealing with climate change: The impact of Participatory Integrated Climate Services for Agriculture (PICSA) on smallholder lead farmers in Malawi

AbstractMotivationThe climate crisis threatens the livelihoods and welfare of farmers in the global south. Increasing variability of weather makes it ever more important to get forecasts to farmers and help them make best use of this information. Participatory Integrated Climate Services for Agriculture (PICSA) is an approach that gives farmers better weather forecasts and, in lockstep with agricultural extension workers, supports farmers in interpreting forecasts to make appropriate decisions for their own farms. It has been implemented across more than 20 countries of the global south, including Malawi.Reviews and evaluations of PICSA have been positive, although it has not previously been rigorously evaluated using impact evaluation techniques.PurposeWe estimate the impacts of PICSA training and meetings on lead farmers in Malawi, taking farmers in four districts where PICSA operated, and farmers in four other districts where the programme was not present.MethodsWe compare outcomes in farming practice, yields obtained, livelihood decisions and food security between lead farmers who participated in PICSA and those who did not. Because selection into the programme was not random, we use propensity score matching and regression adjustment to correct for potential selection bias.FindingsPICSA lead farmers used seasonal forecasts to plan farm decisions, change crop activities, increase maize yields, and improve their food security. Differences between them and the control group were, in most cases, significant.Our results confirm the potential of PICSA to help farmers adapt to climate change.PolicyIn similar contexts, the PICSA approach could effectively support smallholders to make informed agricultural decisions, in participatory discussions, based on climate and weather information.For Malawi, the evidence suggests the programme or something similar should be continued.

Weed Management Effects on Weed Dynamics, Yield and Economics of Spring Maize at Dang, Nepal

Weeds pose a significant challenge in maize fields in the Dang district, leading to a substantial 52% reduction in yield. Hence, this study was conducted in Satbariya village of Dang, Nepal, in 2023 to evaluate the impact of various weed management practices on weed dynamics, growth, and yield of spring maize. The experiment included seven treatments: a weedy check, weed-free plot, pre-emergence application of atrazine at 1.25 a.i. kg/ha (AtPrE), post-emergence application of atrazine at 1.25 a.i. kg/ha (AtPoE), manual weeding at 30 DAS, mini-tiller at 30 DAS, and LaPoE (tembotrione 42% SC + atrazine 50% WP) applied as post-emergence. The Subarna variety of maize was chosen for the study. Fifteen weed species from seven different families were identified in the experimental area. Specific morphological and phenological parameters, such as plant height and days to tasseling and silking, were not significantly influenced by the weed control methods. However, significantly lower weed density and biomass were observed in the weed-free plot and LaPoE. Similarly, weed-free plots and LaPoE exhibited significantly higher weed control efficiency (WCE) and weed control index at both 45 and 60 DAS, leading to a lower weed index (0.00–16.71%) and more effective weed control. Concerning the yield parameters, cob length, number of kernels per row, and 1000-grain weight were significantly higher in weed-free plots, followed by LaPOE, and the highest grain and biological yield were observed in weed-free plot (6.14–15.18 tons/ha) and LaPoE (5.12–13.32 tons/ha). Moreover, the benefit-cost ratio and net return were observed to be highest with LaPoE. This study suggests that LaPoE can be an effective and economical weed management strategy for increasing maize yield and profitability. Further research could explore the long-term effects of using LaPoE on weed control and crop productivity.

Ammonium Polyphosphate Promotes Maize Growth and Phosphorus Uptake by Altering Root Properties.

Phosphorus (P) is an essential nutrient for maize growth, significantly affecting both yield and quality. Despite the typically high concentration of available P in black soils, the efficiency of crop uptake and utilization remains relatively low. This study aimed to evaluate the effects of different P fertilizers on maize yield, root growth parameters, and P use efficiency to identify strategies for optimizing P management in black soil regions. Field experiment results indicated that the combination of ammonium polyphosphate (APP) with other P fertilizers led to variations in yield and P fertilizer absorption efficiency. Various P fertilizers were tested, including diammonium phosphate (DAP), ammonium polyphosphate (APP), fused calcium magnesium phosphate (FCMP), a combination of DAP and FCMP (DAP+FCMP), and a control with no phosphate (CK). The results indicated that P application significantly increased maize yield, with APP (171.8 g/plant) outperforming other P application treatments. Different P fertilizer types significantly affect soil P content and the composition of P fractions. APP significantly increased both the total P (TP) and the proportion of inorganic P (Pi). Furthermore, APP application significantly improved root length (RL), surface area (SAR), and root activity (RA) compared to CK, leading to enhanced nutrient absorption. APP also significantly increased P uptake and utilization (REp, FPp, AEp, PHI, and PAC). In summary, by optimizing plant biomass and P uptake, APP can directly and indirectly influence maize yield. Improving rhizosphere properties through the selection of suitable fertilizer types can enhance fertilizer use efficiency and increase maize production.

Transcriptomic Characterization of Genes Harboring Markers Linked to Maize Yield.

It is currently believed that breeding priorities, including maize breeding, should focus on introducing varieties with greater utility value, specifically higher yields, into production. Global modern maize breeding relies on various molecular genetics techniques. Using the above mentioned technologies, we can identify regions of the genome that are associated with various phenotypic traits, including yield, which is of fundamental importance for understanding and manipulating these regions. The aim of the study was to analyze the expression of candidate genes associated with maize yield. To better understand the function of the analyzed genes in increasing maize yield, their expression in different organs and tissues was also assessed using publicly available transcriptome data. RT-qPCR analyses were performed using iTaq Universal SYBR Green Supermix (Bio-Rad, Hercules, CA, USA) and CFX96 Touch Real-Time PCR Detection System (Bio-Rad, Hercules, CA, USA). Each of the performed RT-qPCR experiments consisted of three biological replicates and three technical replicates, the results of which were averaged. The research results allowed us to select three out of six candidate genes (cinnamoyl-CoA reductase 1-CCR1, aspartate aminotransferase-AAT and sucrose transporter 1-SUT1), which can significantly affect grain yield in maize. Not only our studies but also literature reports clearly indicate the participation of CCR1, AAT and SUT1 in the formation of yield. Identified molecular markers located within these genes can be used in breeding programs to select high yielding maize genotypes.

Effects of PBAT/PLA biodegradable film mulching on greenhouse gas emissions in rain-fed maize farmland of Northeast China

Plastic film mulching can effectively increase soil temperature, retain moisture, and enhance crop yield and quality. However, long-term application might pose risks of increased greenhouse gas (GHG) emissions and residual film pollution. Biodegradable film provides a crucial solution to alleviate farmland plastic pollution, but it remains unclear whether biodegradable film can simultaneously enhance crop yields and reduce GHG emissions. Thus, a two-year field experiment was conducted in rain-fed maize farmland of Northeast China. This field experiment included four treatments: BM1 (0.006 mm-thick biodegradable film), BM2 (0.010 mm-thick biodegradable film), PM (0.010 mm-thick traditional plastic film), and CK (non-mulching control). Results indicated that film mulching increased cumulative CO2 emissions by improving soil temperature and moisture. BM1 and BM2 achieved lower cumulative CO2 emissions than PM. N2O emissions were mainly concentrated in the emergence and jointing stages, whose peaks and cumulative values were reduced by film mulching. BM1 and BM2, however, had higher cumulative N2O emissions than PM. All treatments were CH4 sinks, and mulching treatments showed low soil CH4 absorption compared to CK. Additionally, mulching treatments increased maize yield, GWP and GHGI by 4.19 % to 15.89 %, 8.52 % to 52.20 % and − 0.06 % to 45.93 %, respectively, compared to CK. PM showed the highest GWP and GHGI. All mulching treatments improved the net ecosystem economic budget, with increases of 3.03–3.08 thousand CNY ha−1 and 0.35–1.39 thousand CNY ha−1 in 2022 and 2023, respectively, compared to CK. Biodegradable film treatments had higher net ecosystem economic budgets than traditional plastic film treatment. Overall, the biodegradable film can be used to replace traditional plastic film to enhance maize yield while minimizing residual film pollution and GHG emissions in the experimental region.

Combined Genome-Wide Association Study and Linkage Analysis for Mining Candidate Genes for the Kernel Row Number in Maize (Zea mays L.).

Kernel row number (KRN) is one of the key traits that significantly affect maize yield and productivity. Therefore, investigating the candidate genes and their functions in regulating KRN provides a theoretical basis and practical direction for genetic improvement in maize breeding, which is vital for increasing maize yield and understanding domestication. In this study, three recombinant inbred line (RIL) populations were developed using the parental lines AN20, YML1218, CM395, and Ye107, resulting in a multiparent population comprising a total of 490 F9 RILs. Phenotypic evaluation of the RILs for KRN was performed in three distinct environments. The heritability estimates of the RILs ranged from 81.40% to 84.16%. Genotyping-by-sequencing (GBS) of RILs identified 569,529 high-quality single nucleotide polymorphisms (SNPs). Combined genome-wide association study (GWAS) and linkage analyses revealed 120 SNPs and 22 quantitative trait loci (QTLs) which were significantly associated with KRN in maize. Furthermore, two novel candidate genes, Zm00001d042733 and Zm00001d042735, regulating KRN in maize were identified, which were located in close proximity to the significant SNP3-178,487,003 and overlapping the interval of QTL qKRN3-1. Zm00001d042733 encodes ubiquitin carboxyl-terminal hydrolase and Zm00001d042735 encodes the Arabidopsis Tóxicos en Levadura family of proteins. This study identified novel candidate loci and established a theoretical foundation for further functional validation of candidate genes. These findings deepen our comprehension of the genetic mechanisms that underpin KRN and offer potential applications of KRN-related strategies in developing maize varieties with higher yield.

Logistic and Structural Equation Fitting Analyses of the Effect of Slow-Release Nitrogen Fertilizer Application Rates on the Nitrogen Accumulation and Yield Formation Mechanism in Maize

The purpose of this study is to clarify the differential effects of the application rate of slow-release nitrogen fertilizer (SRFN) on the nitrogen (N) accumulation dynamics, nutrient organ N distribution and transportation, yield, and N utilization efficiency of maize harvested using grain-type machines. This has significant implications for the scientific application of SRFN, as well as for reducing its application rate and improving its efficiency, in the agro-pastoral transitional zone of northern China. In a long-term positioning experiment that began in 2018, five treatments consisting of different SRFN application rates were set up, namely, N120 (120 kg ha−1), N180 (180 kg ha−1), N240 (240 kg ha−1), N300 (300 kg ha−1), and N360 (360 kg ha−1), with no fertilization during the growth period used as control (CK) treatment. To explore the characteristics of nitrogen accumulation dynamics in maize populations and the main factors affecting maize yield formation under the different SRFN application rate treatments, this study adopted a combination of quantitative analyses and model fitting, including logistic models, principal component analysis, and structural equation modeling. The research results show that SRFN application increased the aboveground N accumulation of the maize population, and the fitting effect of the logistic models was significant. The maximum rate of N accumulation in both years showed a trend of first increasing and then decreasing with the increase in the SRFN application rate. Compared with CK, SRFN application reduced the proportion of N distribution in the nutrient organs during the R6 stage, and it increased the N transport from the nutrient organs to the grains after the VT-R1 stage. With the increase in the SRFN application rate, both the economic yield and biological yield showed a single peak curve change and were maximized in the N240 treatment. The economic yield reached 15,342.07 kg ha−1 in 2020 and 16,323.51 kg ha−1 in 2021, increasing by 36.2% and 61.7% compared with CK, respectively. The apparent N fertilizer recovery rate, N uptake efficiency, N agronomic efficiency, and N fertilizer partial productivity all gradually decreased with the increase in the SRFN application rate. In maize populations, an appropriate SRFN application rate can adjust the characteristic parameters during the aboveground N accumulation rapid growth period, increase the N accumulation amount in aboveground parts, promote the transport of N from nutrient organs to grains, and improve yield. An application of 180–240 kg ha−1 SRFN is recommended for maize cultivation in the agro-pastoral transitional zone of northern China, as it is beneficial for stabilizing and increasing maize yield, as well as reducing the rate and improving the efficiency of N fertilizer.

The indispensable function of agricultural cooperatives in South Sudan

AbstractMost of South Sudan's rural population ekes out a living from farming in a fragile context characterized by compounding and interrelated shocks. The productivity of maize, a key staple, has remained comparatively low. South Sudan is currently transforming its agricultural sector to be at the centre of its economic activity. Programming has zoomed in on seed‐related interventions. Cooperatives, which are longstanding and widespread in the country, are leveraged to distribute seed and, by mitigating production risk, could contribute to resilient development. To shed light on the key functions of cooperatives and how their role can be enhanced, we analysed recent data from 1247 maize‐producing households and 126 agricultural cooperatives from South Sudan. We find that through their services cooperatives contribute to both increasing maize yields and reducing their variability. Yield increases associated with seed production and/or distribution services are substantial but exclusive to members. Managerial capital in the form of a hired manager instead also generates spillover effects to the broader community. Our findings point to the relevance of cooperatives as indispensable stakeholders for the resilient development of the country and the need for investments to strengthen their managerial capital and enhance the provision of services related to seed production and/or distribution.

Drip Fertigation Improves Maize Yield, Resource Utilization, and Economic Benefits by Increasing Light Interception Under Dense Planting in Southwest China

ABSTRACTSeasonal drought and traditional water‐fertilizer management limit the increase in the grain yield of summer maize in Southwest China. Drip fertigation mode (HM) can effectively improve crop yields. However, research on drip fertigation has not been conducted in Southwest China. A 2‐year field experiment about HM was carried out with the traditional water‐fertilizer management mode (FM) as control. The plant densities were 5.25 × 104 plants ha−1 and 8.25 × 104 plants ha−1 in 2022 and 6.00 × 104 plants ha−1 and 9.00 × 104 plants ha−1 in 2023. The effects of HM on the aboveground biomass, leaf area index, yield, and resource utilization rate of summer maize were studied. Compared with the FM treatment, the HM treatment significantly increased the yield (25.18%), aboveground biomass (25.58%), leaf area index (34.87%), and leaf area duration (29.60%). HM optimized the canopy structure with an 11.05% improvement in light transmission at the top and a significant 61.32% increase in cumulative light radiation interception per unit area at the bottom of the canopy. The nitrogen partial factor productivity (NPFP), radiation utilization efficiency (RUE), heat utilization efficiency (HUE), and economic benefits of the HM treatment significantly increased by 39.58%, 49.45%, 25.92%, and 32.53%, respectively. In addition, dense planting increased the irrigation water use efficiency (IWUE) by 14.25%. In summary, drip irrigation combined with water and fertilizer can significantly improve maize grain yield, resource utilization efficiency, and economic benefits by increasing light interception in Southwest China. This study will lay a theoretical foundation for filling the relevant research gap in the region.

Impacts of multivalued interventions on maize farmers’ welfare: Evidence from SIPMA development project in Ghana

Recent research has highlighted the significance of agricultural development programmes in Sub-Saharan Africa for enhancing production, food security, and farmer welfare. However, these studies frequently investigate the effects of a single intervention rather than a combination of interventions. This study examines the impact of three interventions (credit access, structured market, and entrepreneurial training) on maize yield, food security, food expenditure and non-food expenditure in Ghana. We utilized multivalued inverse probability weighted regression correction, and propensity score matching with data from the Smallholder Inclusive Productivity and Market Access (SIPMA) agricultural development programme on 477 maize farmers. Participation in SIPMA interventions significantly increased maize yields, farm income, food spending, and non-food spending. For smallholder farmers, participation in a combination of input credit provision, structured market, and entrepreneurial training results in the highest yield, farm income, and non-food expenditures, while participation in entrepreneurial training alone results in a lower yield. Our empirical evidence suggests that the interventions should be expanded to other communities because the project's characteristics are distinctive in terms of fostering community engagement and collaboration with local/regional institutions.

Effects of combined application of Se and ammonium fertilizers on the growth and nutritional quality of maize in Hg-polluted soil under two irrigation conditions and its health risk assessment

The interactive effects of Se (Na2SeO3) and ammonium fertilizers ((NH4)2SO4 and NH4Cl) on the growth and quality of maize (Zea mays L.) in mercury (Hg)-contaminated soil were studied under different water conditions. This study determined how two nutrient sources (Se and NH4+-N) interacted to improve the yield, quality, and safety of maize to ensure food security and quality assurance under the stress of heavy metal Hg. The experiment was conducted under two irrigation conditions: W1 (complete irrigation condition, 60–70% of water-holding capacity) and W2 (restricted irrigation condition, 40–50% of water-holding capacity). The combined treatment of Se and ammonium fertilizers significantly improved the growth of maize and the quality of grain in Hg-polluted soil. When Na2SeO3 and (NH4)2SO4 were combined, the growth and quality of maize increased the highest among all treatments. The interaction between Na2SeO3 and ammonium fertilizers significantly affected the available Hg/methylmercury (MeHg) content in soil and the Hg/MeHg concentration in maize. NH4Cl significantly increased the content of available Hg/MeHg in soil and increased the accumulation of Hg/MeHg in maize tissues due to Cl−. However, the treatments containing Na2SeO3 or (NH4)2SO4 significantly reduced the content of available Hg/MeHg in soil, reduced the accumulation of Hg/MeHg in maize tissues, and significantly reduced the possible health risks to human beings. The treatments containing Na2SeO3 or (NH4)2SO4 promoted maize growth by increasing the Se content in maize tissues and reducing the Hg/MeHg content, relieving the stress induced by Hg, and increasing the nutrient content. The combined treatment of Na2SeO3 and (NH4)2SO4 had the best effect in this experiment. This study also showed that this strategy is helpful in reducing the opportunities for consumers to accumulate Hg/MeHg by eating maize and its derivatives, thus ensuring food safety. Se and ammonium fertilizer can be used together to increase maize yield and develop agricultural production in Hg-polluted areas, which may have a significant impact on global food production. In addition, this simple method can help farmers manage soil affected by heavy metal pollution.

Boron availability and fertilizer response of maize in soils from sub‐Saharan Africa

AbstractBackground and aimsLow boron (B) availability is associated with strongly weathered, coarse‐textured, and low organic matter soils, widespread in sub‐Saharan Africa (SSA). It is unknown to what extent B fertilization can increase maize yields in SSA. This study aims to understand the soil properties controlling B availability to field‐grown maize.MethodsBoron fertilizer omission trials with maize were executed at 15 sites in Kenya, Zambia, and Zimbabwe. Yield, B uptake, and soil parameters potentially relevant for B availability, including extractable soil B (hot water, 0.01 M CaCl2, and 0.43 M HNO3), were determined.ResultsSoil B pools were strongly intercorrelated and were positively correlated with organic carbon, suggesting the relevance of organic matter for soil B availability. Soil parameters described limited variation in B uptake and the yield response to B fertilization. Boron fertilization did not increase yields in any of the 15 sites but increased uptake in 11 sites. Yields were reduced through B fertilization in five sites, likely because B application induced toxicity. No clear critical soil or plant B concentrations indicating deficiency could be derived, but positive yield responses to B fertilization were absent with hot water B levels above 0.69 mg kg−1.ConclusionAssessing B fertilizer needs in maize grown in tropical soils based on soil or plant tissue concentrations remains challenging. Improving soil organic matter status could potentially alleviate B deficiency in crops when present. Recommendations are given to overcome the identified challenges associated with studying B availability in tropical soils.

Short-Term Effects of Incorporation Depth of Straw Combined with Manure During the Fallow Season on Maize Production, Water Efficiency, and Nutrient Utilization in Rainfed Regions

Diminishing soil fertility and crop productivity due to traditional intensive cultivation has prompted the use of straw and manure to improve soil health in Northeast China. However, few comparative studies have explored the influence of varying straw and manure incorporation depths on crop growth. A field experiment in the rainfed black soil regions of Gongzhuling and Keshan assessed the effects of deep (30 cm) and shallow (15 cm) incorporations of straw and manure on soil fertility, maize root growth, and maize productivity. Deep incorporations, via subsoiling tillage (DST) and deep-plow (DDT) tillage, enhanced soil water storage of 30–100 cm soil layer during periods of low rainfall, improved the availability of nutrients (nitrogen, phosphorus, and potassium) and soil organic matter content, especially in deeper soil, compared to shallow incorporation using rotary tillage (SRT). Both DST and DDT induced a larger rooting depth and a higher fine root (diameter class 0–0.5 mm) length density by 31.0% and 28.9%, respectively, accompanied by reduced root turnover. Furthermore, the sub-surface foraging strategies of roots under the DST and DDT treatments boosted the total nitrogen, phosphorus, and potassium uptake (6.5–17.9%) and achieved a higher dry mass accumulation during the later growth period, thus leading to notable improvements in the 100-kernel weight and yield (16.1–19.7%) and enhancing water- and nutrient-use efficiencies by 2.5–20.5%. Overall, compared to shallow incorporation, deep incorporation of straw and manure significantly enhances root growth and spatial distribution of soil water and nutrients, which has great potential for increasing maize yield in rainfed agricultural areas.

Enhancing Water Use Efficiency and Carbon Profitability Through the Long-Term Impact of Sustainable Farming Systems

This study aims to enhance water use efficiency, maximize productivity, and minimize environmental impact through the implementation of sustainable agricultural systems using drip irrigation systems. It investigates the effects of biodynamic farming compared to those of organic and conventional methods over a six-year period and focuses on soil properties, water use efficiency, crop yield, and environmental and economic perspectives. Using a biodynamic farming system resulted in an average increase in water use efficiency of 1.96 and 10.67% for maize and 3.62 and 10.68% for faba bean and an increase in maize yield of 1.68 and 0.99%, while the faba bean yield reached 3.25 and 1.57% compared to the organic and conventional farming systems, respectively. The biodynamic system sequestered the highest average soil carbon of 6.16 tons/ha (which is equivalent to 22.45 tons/ha of CO2 emissions), representing a 13% increase compared to the organic system. Additionally, the biodynamic system yielded an increase in total net profit of 5.70 and 21.66% for the maize crop and 6.72 and 22.19% for the faba bean crop compared to the organic and conventional farming systems, respectively. The farming system significantly influenced the soil carbon sequestration and organic carbon.