Grain yield and resource efficiency responses to water-nitrogen coupled input reduction: A global meta-analytical perspective

Improving yield and nitrogen use efficiency through alternative fertilization options for rice in China: A meta-analysis

Responses of crop yield and water use efficiency to climate change in the North China Plain

Combined effect of deficit irrigation and strobilurin application on yield, fruit quality and water use efficiency of “cherry” tomato (Solanum lycopersicum L.)

Forage production from Rocky Mountain meadows is characteristically low, averaging 1.3 ton/acre. Research has shown that lack of N fertilization is a major factor limiting yield. Little research has compared N fertilizer sources, rates, and application time for meadow pastures. Experiments were conducted on a less productive Edlin sandy loam soil (coarse-loamy, mixed Borollic Camborthids) located near Saratoga, WY, and on a more productive Mayoworth sandy clay loam soil (fine, montmorillinitic Argic Cryoborolls) near Gannby, CO, over 3 yr. Treatments consisted of factorial combinations of two application times (fall and spring), five N rates (0, 50, 100, 150, and 200 lb N/acre), and two N sources (ammonium nitrate [AN] and urea). Forage production increased from 1.1 ton/acre with no N fertilizer to 3.4 ton/acre on the Edlin soil and from 2.7 ton/acre to 4.9 ton/acre on the Mayoworth soil with 150 lb N/acre as AN. Optimum economic N rate varied with source, time of application, and most importantly, with yield potential of the soil. Ammonium nitrate consistently produced more forage and higher fertilizer recovery efficiency than urea at equal N rates. Spring N application produced higher yields and higher fertilizer recovery efficiency than fall application on the more productive Mayoworth soil. On the Edlin soil, time of application did not affect forage production. Fall application may be necessary, however, where mountain meadows are wet during the spring fertilization period, preventing access to fertilizer application equipment. For fall application, AN should be used as the N source, since AN provided the highest yield and fertilizer recovery efficiency. On the Edlin soil, 150 lb N/acre spring-applied increased protein from 7.1 % to 8.7 % and 9.2 % for urea and AN, respectively. On the more productive Mayoworth soil, forage protein concentration increased less dramatically with similar N application rates. If producers are interested in producing quality forage, adequate N fertilization is vital

Contribution of summer rainfall and nitrogen to the yield and water use efficiency of wheat in Mediterranean-type environments of South Australia

ABSTRACTMoringa leaf extracts (MLE) from two varieties of Moringa oleifera Lam. were applied to leaves of wheat (Triticum aestivum L.) in two glasshouse experiments. MLE was extracted from the leaves of using three different solvents (hexane, butanol; ethyl-acetate). The extracts were applied as foliar sprays at different growth stages of wheat (T. aestivum L.) grown on two soil types with either adequate or low phosphorus (P) nutrient additions at Albany, Western Australia. Sprays were applied at the 4–5 leaf (tillering) and the 7-leaf (Boot) stage either as a single spray or a combination of sprays at tillering and boot stage. The application of MLE either at tillering or boot stage increased the dry weight of shoots (biomass) and grain yield of wheat. A foliar spray of MLE applied at tillering increased biomass at the boot stage by ∼37% and grain yield increased by ∼34% compared to nil MLE spray. A single spray of MLE increased grain yield by ∼30% when applied at boot stage. A single application at tillering gave a better yield response than a single spray at the 7-leaf or boot or than a double spray applied at tillering and boot stage. A 50% dilution of the extractant concentration gave the same grain yield response as the original concentration applied at tillering stage. The hexane extracts gave the significantly higher grain yield responses. Plant tissue and grain analysis showed no significant difference in protein and nutrient concentration of wheat grain from plants sprayed with and without MLE. A MLE spray at boot also increased grain yield by 44% on the red sandy-loam soil where P application was at sub-optimum levels, ∼80% of P requirement for maximum yield. The partial factor productivity (PFP) index indicated that the P and potassium (K) use improved where MLE was applied as a foliar spray. For example, the PFP of P and K for grain yield increased by about 30%, where MLE was sprayed to foliage. The results of this study indicate that MLE extracted can potentially be a viable option to increase wheat grain yield and fertilizer efficiency use, particularly P and K, in Mediterranean wheat production system.

Yield and water use efficiency of wheat in the Loess Plateau: Responses to root pruning and defoliation

Proper irrigation and fertilization are essential for achieve high tuber yield and quality in potato production. However, the high cost of these inputs necessitate optimization of their use to improve both water use efficiency and crop productivity. This study aimed to investigate the impact of irrigation and nitrogen fertilization on potato yield, quality and water use efficiency. The research included different drip irrigation treatments (100%, 66%, and 33% of field capacity) and nitrogen levels: 0 (N0), 100 (N1), 200 (N2), 300 (N3), 400 (N4) and 500 (N5) kg N ha−1. The results indicated that potato yield and growth were more sensitive to irrigation treatment than nitrogen levels. Full irrigation with 300 kg N ha−1 produced the highest total tuber yield, while low irrigation treatments resulted in significantly lower yields. In contrast, the 66% field capacity irrigation treatment consistently had the highest water use efficiency in both years of the study. Furthermore, the study showed that the quality characteristics of the tubers were negatively impacted by full irrigation treatments compared to low irrigation. These findings suggest that with appropriate irrigation and nitrogen application, potatoes can be produced with acceptable yields while conserving water and minimizing nitrogen use. This research emphasizes the importance of optimizing inputs to improve water use efficiency and yield productivity while reducing water. As a result, obtaining useful information on crop management for farmers to make informed decisions may be possible by achieving optimal irrigation and nitrogen levels.

Responses of yield, quality and water-nitrogen use efficiency of greenhouse sweet pepper to different drip fertigation regimes in Northwest China

Responses of yield and water use efficiency to the interaction between water supply and plastic film mulch in winter wheat-summer fallow system

Analysis of production responses to changing crude protein levels in lactating dairy cow diets when evaluated in continuous or change-over experimental designs

Simple SummaryAdopting deficit irrigation (DI) to improve crop production and safeguard groundwater resources is of great importance in water scarce regions, e.g., the North China Plain (NCP). Under the background of global warming, it is worth investigating whether DI continues to play such a key role under future climate change scenarios. Thus, we studied the effect of DI on wheat yield and water use efficiency under future climate change scenarios. We found that moderate deficit irrigation (DI3, ≤0.4 PAWC at sowing to flowering stage) under the N3 (150 kg N ha−1) condition was identified as the optimum irrigation schedule for the study site under future climate change scenarios. However, the compensation effect of DI3 on yield and water use efficiency (WUE) became weak in the future. To conclude, in water scarce regions of NCP, DI remains an effective strategy to maintain higher yield and enhance water use under future climate scenarios.Background. Deficit irrigation (DI) is a feasible strategy to enhance crop WUE and also has significant compensation effects on yield. Previous studies have found that DI has great potential to maintain crop production as full irrigation (FI) does. Therefore, adopting DI to improve crop production and safeguard groundwater resources is of great importance in water scarce regions, e.g., the North China Plain (NCP). Under the background of global warming, it is worth investigating whether DI continues to play such a key role under future climate scenarios. Methods. We studied the response of winter wheat yield and WUE to different DI levels at pre-anthesis under two Shared Socioeconomic Pathways (SSPs) scenarios (SSP245 and SSP585) using the Agricultural Production Systems Simulator (APSIM) model driven by 21 general circulation models (GCMs) from the Coupled Model Inter-Comparison Project phase 6 (CMIP6). Additionally, we explored the effects of different nitrogen (N) fertilizer application rates on DI. Results. We found that simulated wheat yield would increase by 3.5–45.0%, with WUE increasing by 8.8–46.4% across all treatments under future climate change. Moderate deficit irrigation (DI3, ≤0.4 PAWC at the sowing to flowering stage) under the N3 (150 kg N ha−1) condition was identified as the optimum irrigation schedule for the study site under future climate change. However, compensation effects of DI3 on yield and WUE became weak in the future, which was mainly due to increased growing season rainfall projected by GCMs. In addition, we found that N fertilizer application could mitigate the effect of DI3. Conclusions. We highlight that in water scarce regions of NCP, DI remains an effective strategy to maintain higher yield and enhance water use under future climate scenarios. Results strongly suggest that moderate deficit irrigation under a 150 kg N ha−1 condition could mitigate the contradiction between production and water consumption and ensure food safety in the NCP.

Achieving optimal balance between maize yield and water use efficiency is an important challenge for irrigation maize production in arid areas. In this study, we conducted an experiment in Xinjiang China in 2016 and 2017 to quantify the response of maize yield and water use to plant density and irrigation schedules. The treatments included four irrigation levels: 360 (W1), 480 (W2), 600 (W3), and 720 mm (W4), and five plant densities: 7.5 (D1), 9.0 (D2), 10.5 (D3), 12.0 (D4), and 13.5 plants m−2 (D5). The results showed that increasing the plant density and the irrigation level could both significantly increase the leaf area index (LAI). However, LAI expansion significantly increased evapotranspiration (ETa) under irrigation. The combination of irrigation level 600 mm (W3) and plant density 12.0 plants m−2 (D4) produced the highest maize yield (21.0–21.2 t ha−1), ETa (784.1–797.8 mm), and water use efficiency (WUE) (2.64–2.70 kg m−3), with an LAI of 8.5–8.7 at the silking stage. The relationship between LAI and grain yield and evapotranspiration were quantified, and, based on this, the relationship between water use and maize productivity was analyzed. Moreover, the optimal LAI was established to determine the reasonable irrigation level and coordinate the relationship between the increase in grain yield and the decrease in water use efficiency.

Increasing doses of biocholine on apparent digestibility, ruminal fermentation, and performance in dairy cows

Potato is an important crop in the Northwest China, however, its production is constrained by water scarcity. Plastic mulching film is an efficient technical measure to alleviate potato production restrictions. Therefore, studying the response of potato yield and water use efficiency to plastic mulching film is of great significance. The study conducted a meta-analysis to quantify the effect of plastic film on potato yield and water use efficiency in the Northwest. The study then quantified the effects of different levels of natural conditions (mean annual precipitation, mean annual accumulated temperature ≥ 10 °C), fertilizer application (nitrogen fertilizer, phosphate fertilizer, potassium fertilizer), cultivation measures (planting density, cultivation method, mulching method), and mulching properties (mulching color, mulching thickness) through subgroups analysis. Finally, the random forest model was used to quantify the importance of factors. Plastic film mulching increased yield by 27.17% and water use efficiency by 27.16%, which had a better performance under relatively lower mean annual precipitation, low mean annual accumulated temperature ≥ 10 °C, relatively lower fertilizer application, planting density of 15,000–45,000 plants·ha−1, ridge, and black mulching. Natural conditions, fertilization measures were vital to improve productivity. The research results can provide reference for agricultural management strategies of potato cultivation using plastic film in the Northwest China and other potato-producing areas.