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This study evaluates the feasibility of utilizing suspension fertilizers as alternatives to conventional organic fertilizers in drip irrigation systems. The investigation focused on several key aspects, including storage stability, particle size distribution, soil organic matter (OM) content, seed germination, and nutrient utilization efficiency. Suspension fertilizers maintained excellent storage stability, with no stratification or deterioration observed over prolonged storage (≥ 30 days). Their particle size distribution remained suitable for drip irrigation systems, ensuring uniform application and reducing clogging risks. The application of suspension fertilizers significantly increased soil OM content across different soil layers (5–20 cm depth) by 25.3 to 44.1%. The phosphorus-use efficiency of banana seedlings increased 9.1- to 12.6-fold relative to the control. The germination index of cucumber and radish seeds improved by 41.7 to 184.6%. The results demonstrate that suspension fertilizers are a viable alternative to traditional organic fertilizers in drip irrigation systems. They enhance soil fertility, promote seed germination, and improve nutrient utilization efficiency. Future research should focus on long-term field trials to validate these benefits across diverse agricultural settings and soil types.

Garlic ( Allium sativum L.) exhibits limited agronomic traits and nutrient use efficiency under conventional cultivation, necessitating innovative non-chemical approaches to enhance productivity. This study evaluated helium-neon (He-Ne) laser and ultraviolet (UV A+B ) radiation as sustainable pre-treatment strategies to optimize garlic growth, yield, and nutrient utilization. Garlic cloves were pre-treated with control (no irradiation), He-Ne laser (1, 5, 30, or 60 minutes), or UV A+B ra6diation (1, 5, 30, or 60 minutes). Results demonstrated that He-Ne laser produced dose-dependent improvements, with 60-minute exposure maximizing plant height (20.5%), shoot fresh weight (48.1%), bulb fresh weight (29.1%), bulb yield (29.0%), and nutrient use efficiency (nitrogen: 146.6%, phosphorus: 85.1%, potassium: 78.4%). In contrast, UVA+B radiation exhibited a biphasic response, with moderate benefits at low doses (1–5 minutes) but progressive decline at extended exposure (30–60 minutes), reducing yield by 10.7% and nutrient use efficiency by 14.9–29.9%. Response Surface Methodology confirmed 60-minute He-Ne laser pre-treatment as the optimal dose, representing a sustainable strategy for enhancing garlic productivity. These findings demonstrate the potential of laser-based technologies for sustainable vegetable production and warrant further investigation into cultivar-specific optimization and field-scale applications for global food security.

Recently, nanomaterials have received considerable attention in the agricultural sector, due to their distinctive characteristics such as small size, high surface area to volume ratio, and charged surface. These properties allow nanomaterials to be utilized as nanofertilizers, that can improve crop nutrient management and reduce environmental nutrient losses. However, after soil application, metallic nanoparticles have been shown to be toxic to soil biota and their associated ecosystem services. The organic nature of nanobiochar (nanoB) may help to overcome this toxicity while maintaining all the beneficial effects of nanomaterials. We aimed to synthesize nanoB from goat manure and utilize it with CuO nanoparticles (nanoCu) to influence soil microbes, nutrient content, and wheat productivity. An X-ray diffractogram (XRD) confirmed nanoB synthesis (crystal size = 20 nm). The XRD spectrum showed a distinct carbon peak at 2θ = 42.9°. Fourier-transform spectroscopy of nanoB’s surface indicated the presence of C=O, C≡N–R, and C=C bonds, and other functional groups. The electron microscopic micrographs of nanoB showed cubical, pentagonal, needle, and spherical shapes. NanoB and nanoCu were applied alone and as a mixture at the rate of 1000 mg kg−1 soil, to pots where wheat crop was grown. NanoCu did not influence any soil or plant parameters except soil Cu content and plant Cu uptake. The soil and wheat Cu content in the nanoCu treatment were 146 and 91% higher, respectively, than in the control. NanoB increased microbial biomass N, mineral N, and plant available P by 57, 28, and 64%, respectively, compared to the control. The mixture of nanoB and nanoCu further increased these parameters, by 61, 18, and 38%, compared to nanoB or nanoCu alone. Consequently, wheat biological, grain yields, and N uptake were 35, 62 and 80% higher in the nanoB+nanoCu treatment compared to the control. NanoB further increased wheat Cu uptake by 37% in the nanoB+nanoCu treatment compared to the nanoCu alone. Hence, nanoB alone, or in a mixture with nanoCu, enhanced soil microbial activity, nutrient content, and wheat production. NanoB also increased wheat Cu uptake when mixed with nanoCu, a micronutrient essential for seed and chlorophyll production. Therefore, a mixture of nanobiochar and nanoCu would be recommended to farmers for improving their clayey loam soil quality and increasing Cu uptake and crop productivity in such agroecosystems.

【Objective】 Low nutrient use efficiency is a common problem facing agricultural production in China, and improving fertigation is an effective way to improve fertilizer use efficiency and reduce nutrient loss, especially in acidic soils. How irrigation and fertigation combine to affect water and nutrient uptake by plants, however, is an issue poorly understood. Taking banana as an example, this paper is to investigate the effect of different chemical fertilizations on banana yield and its nutrient use efficiency. 【Method】 The field experiment included three chemical fertilizations: Top-dressing 309.7 kg/hm2 of N with N∶P2O5∶K2O=1.00∶0.37∶2.61 (A), top-dressing 619.3 kg/hm2 of N with N∶P2O5∶K2O=1.00∶0.37∶1.76 (B), top-dressing 619.3 kg/hm2 of N and 18.0 kg/hm2 of compounded fertilizers with N∶P2O5∶K2O=1.00∶0.37∶1.76 (C). The control was no fertilization (CK). Plants in all treatments were drip-irrigated, and the fertilizers were fertigated simultaneously with the drip irrigation. 【Result】 Chemical fertilizations increased the pseudo-stem girth, leaf numbers and leaf length (P<0.05). Compared with treatment B, treatment A increased banana yield by 9.7% to 53 781 kg/hm2, agronomic efficiency and partial factor productivity by 125.6% and 72.6% respectively. The net income of treatment A was 116 614 yuan/hm2, 22.2% higher than that in treatment B, increasing the output-input ratio from 1.95∶1 to 2.18∶1. 【Conclusion】 Balancing economic benefit, reduction in fertilizer use and banana fruit quality, the optimal fertilization was top-dressing 309.7 kg/hm2 of N, 114.6 kg/hm2 of P2O5 and 808.3 kg/hm2 of K2O simultaneously with the drip irrigation. This is an efficient fertigation for banana grown in acidic soils in the studied area.

IntroductionSoybean breeding in southwestern China has vastly improved soybean yields with the increasing demand for nutrients such as phosphorus (P) and nitrogen (N). This study aimed to assess the impact of soybean breeding on P and N utilization efficiencies.MethodsField experiments with split-plot experimental designs were conducted at two locations [Dafang (DF) and Shiqian (SQ)] in the 2019 growing season to determine the agronomic efficiency of P fertilizer (AEp), P and N utilization efficiencies, and P and N accumulation and partitioning in different soybean organs under 0 (P0) and 35 (P35) kg ha−1 P supply.ResultsThe results showed that soybean breeding targeting high seed yield also improved AEp ( p < 0.05) and P ( p < 0.05) and N utilization efficiencies ( p < 0.05), with the improvement in AEp associated with the high yield response to P supply. P and N accumulation significantly increased in pods ( p < 0.05) and leaves ( p < 0.05) but not in stems or roots with year of release, while P and N concentrations did not change in any organ with year of release. In addition, only pod dry weight significantly increased ( p < 0.01) with year of release, and P and N partitioning increased to pods ( p < 0.05) but decreased to stems ( p < 0.05) with year of release. Correlation and PCA analyses revealed P and N utilization efficiencies positively correlated with P and N partitioning to pods but negatively correlated with P and N partitioning to stems. While P supply increased P and N accumulation, it reduced P utilization efficiency.DiscussionWe conclude that (1) soybean breeding improved AEp and P and N utilization efficiencies; (2) the increased P and N partitioning to pods but decreased partitioning to stems contributed to the high P and N utilization efficiencies in new soybean cultivars, reducing the demand for N and P; (3) P supply increased nutrient accumulation but reduced P utilization efficiency. These results highlight the significance of appropriate resource allocation among organs and efficient P management for enhancing nutrient utilization and reducing fertilizer requirements.

Unlike in soil culture, a substrate (nutrient solution) in a hydroponics system can flow, and this can affect both nutrient uptake and plant growth. In this study, we hydroponically cultivated Swiss chard (Beta vulgaris L. ssp. cicla) under different flow rates to analyze changes in the growth, nutrient uptake, and nutrient use efficiency. When the flow rate was intensified from 2 to 4 L/min, leaf area, the fresh weight, dry weight, and root length increased. However, when the flow rate was increased from 4 to 8 L/min, values of these growth parameters decreased. The nutrient uptake had a similar trend relative to the growth parameters and nutrient use efficiency of macronutrient elements, increased as the flow rate increased. This indicates that the flow rate affects plant growth by influencing the nutrient uptake, and an increase in the flow rate can aid in improving nutrient use efficiency. In hydroponics, regulating the flow rate at a reasonable volume is recommended to increase yield by enhancing nutrient use efficiency, but too intensive a flow rate may cause excessive physical stimulation to plants and inhibit their growth. Therefore, it is important to choose an appropriate substrate flow rate for optimal hydroponics production.

Currently, the global agriculture productivity is heavily relied on the use of chemical fertilizers. However, the low nutrient utilization efficiency (NUE) is the main obstacle for attaining higher crop productivity and reducing nutrients losses from these fertilizers to the environment. Coating fertilizer with micronutrients and biopolymer can offer an opportunity to overcome these fertilizers associated problems. Here, we coated urea with zinc sulphate (ZnS) and ZnS plus molasses (ZnSM) to control its N release, decrease the ammonia (NH3) volatilization and improve N utilization efficiency by sunflower. Morphological analysis confirmed a uniform coating layer formation of both formulations on urea granules. A slow release of N from ZnS and ZnSM was observed in water. After soil application, ZnSM decreased the NH3 emission by 38% compared to uncoated urea. Most of the soil parameters did not differ between ZnS and uncoated urea treatment. Microbial biomass N and Zn in ZnSM were 125 and 107% higher than uncoated urea, respectively. Soil mineral N in ZnSM was 21% higher than uncoated urea. Such controlled nutrient availability in the soil resulted in higher sunflower grain yield (53%), N (80%) and Zn (126%) uptakes from ZnSM than uncoated fertilizer. Hence, coating biopolymer with Zn on urea did not only increase the sunflower yield and N utilization efficiency but also meet the micronutrient Zn demand of sunflower. Therefore, coating urea with Zn plus biopolymer is recommended to fertilizer production companies for improving NUE, crop yield and reducing urea N losses to the environment in addition to fulfil crop micronutrient demand.

The crop phosphorus (P) utilization efficiency of commercial fertilizers is only 10–15%, leaving much P fixed in the soil. Coating fertilizer can lessen this problem, but most of the current available options are potentially toxic and expensive. This study-investigated nanobiochar as a coating material for engineering “smart” di-ammonium phosphate (DAP) fertilizer that controls P and nitrogen (N) release in soil, ultimately enhancing nutrient utilization by maize. Biochar was produced from farmyard manure and ball-milled to obtain nanobiochar. Different nanobiochar concentrations (2.5%, 5%, and 10% w/w) were used to coat the DAP granules in a fluidized-bed coater. The release of N and P was studied after immersing both coated and uncoated DAP fertilizers in water. In a pot experiment, five treatments, i.e.i) control (C), ii) uncoated DAP (UF), iii) 2.5% nanobiochar-coated DAP (CUNB1), iv) 5% nanobiochar-coated DAP (CUNB2), and v) 10% nanobiochar-coated DAP (CUNB3) were introduced, after which maize was sown. The presence of a uniform nanobiochar coating on DAP was confirmed by the discrete carbon peaks observed through X-ray diffraction and FTIR spectroscopic analyses. In a laboratory study, the slowest release of N and P was observed for CUNB3. Remarkably, the application of CUNB1 substantially increased the microbial biomass carbon and N by 104% and 147%, respectively, while enhancing the plant-available P, N, and potassium (K) by 40%, 70%, and 46%, respectively, compared with those of C. This treatment increased maize shoot dry matter yield by 88%, accompanied by marked increases of 229%, 205%, and 67% in maize P, N, and K uptakes compared to C, respectively. However, other coating treatments failed to increase these parameters compared with those of UF, confirming that these coatings had the slowest nutrient availability for short-duration crops. The 2.5% nanobiochar concentration can be recommended for coating DAP fertilizer to reduce problems of P fixation and enhance P availability, crop growth and nutrients uptake, hence contributing to sustainable fertilizer management practices in agroecosystem.

The management of mineral elements in agriculture is important for their nutritional role for plants and dietary value for humans, sparking interest in strategies that can increase mineral use efficiency and accumulation in plant food. In this work, we evaluated the effects of the isosmotic variations of the concentration on three macrocations (K, Ca, and Mg) in lettuce ( Lactuca sativa L.). Our aim was to improve the nutritional components of this valuable dietary source of minerals. Using a full factorial design, we analyzed mineral utilization efficiency (UtE), leaf morphology, gas exchange parameters, phenolic profiles (through ultra-high performance liquid chromatography coupled to a quadrupole-time-of-flight (UHPLC-QTOF) mass spectrometry), and enzymatic activities in two phytochemically diverse butterhead lettuce varieties (red or green). Plants were fed in hydroponics with three nutrient solutions (NSs) with different ratios of K, Ca, and Mg. The variation of these minerals in the edible product was associated with alterations of the morphology and physiology of the leaves, and of the quality and functional properties of lettuce, with a trade-off between total accumulation and mineral UtE. Moreover, in non-limiting conditions of nutrient availability, significant mineral interactions were also present. The flexibility of the plant response to the different ratios of macrocations, and the observed large intraspecific variation, were adequate to provide mineral-specific phytochemical profiles to the edible product. Specifically, the full-red lettuce provided more interesting results in regard to the compositional and functional attributes of the leaves.

The efficiency of pig production using nutrients has increased over the years. Still, better efficiency of nutrient utilization can be achieved by feeding pigs with diets adjusted to their estimated requirements. An increase in nutrient efficiency of utilization represents economic gains while maximizing environmental performance. The objective of this paper is to review the impact of different methods of diet formulation that provide farm animals with the amount of nutrients to satisfy their needs while minimizing nutrient excretion and greenhouse gas emissions. Diet formulation is one tool that can help to maximize nitrogen and energy utilization by decreasing crude protein content in diets. The use of local feedstuff and non-human-edible products (e.g., canola meal) associated with synthetic amino acid inclusion in the diet are valuable techniques to reduce carbon footprint. Precision feeding and nutrition is another powerful tool that allows not only daily tailoring of diets for maximal nutrient efficiency of utilization but also to reduce costs and improve nitrogen efficiency of utilization. In this review, we simulated through mathematical models the nitrogen and energy efficiency of utilization resulting from crude protein reduction in the diet. An 8% crude protein reduction in the diet can increase nitrogen efficiency of utilization by 54% while costing 11% less than a control diet without synthetic amino acids. The same reduction in crude protein represented a major improvement in available energy due to the decrease of energetic losses linked to protein deamination. Urinary and hindgut fermentation energy losses were 24% lower for pigs fed with low-protein diets when compared to control diets. In terms of modern feeding techniques and strategies, precision feeding and nutrition can decrease nitrogen excretion by 30% when compared to group phase feeding. The benefits of feeding pigs with low-protein diets and precision feeding techniques are additive and might result in a 61% nitrogen efficiency of utilization. There is room for improvement in the way nutrient requirements are estimated in pigs. Improving the understanding of the variation of nutrient utilization among pigs can contribute to further environmental gains.