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Papers
61,005 resultsShowing papers similar to Efficacy of Mineral And Nano Fertilizers on Yield and Quality of Sugar Beet crop cv. Karam., (Beta vulgaris, L)
ClearComparative Study on the Use of Traditional, Conventional and Advanced Methodologies for Sustainable Agriculture – a Review
Not relevant to microplastics — this is a review comparing traditional, conventional, and nano-technology-based fertilisation methods in agriculture.
The challenge of nanotechnology in the field of agricultural applications: Nanofertilizers as an emerging technology
This systematic review covers the development and applications of nanofertilizers — nano-scale nutrient delivery systems for agriculture — as an emerging and more efficient alternative to conventional fertilizers. Precision agriculture using nanotechnology could reduce the reliance on plastic-coated slow-release fertilizers that contribute microplastics to soil.
Nanoparticles as catalysts of agricultural revolution: enhancing crop tolerance to abiotic stress: a review
This review looks at how nanoparticles can help crops withstand environmental stresses like drought, salt, and heavy metal contamination. While not directly about microplastics, the research is relevant because nanoparticles and microplastics share similar size ranges and behaviors in soil, and understanding how tiny particles interact with plants helps scientists assess both the risks and potential benefits of nanoscale materials in agriculture.
How to improve crop photosynthesis more efficiently using nanomaterials: Lessons from a meta-analysis
Researchers analyzed dozens of studies and found that applying nanomaterials to crops can boost photosynthesis — the process plants use to grow — especially under drought and salt stress conditions, though they caution that lab results may not always translate to real farm fields and that nanoplastics in the soil can reduce these benefits.
A Review on Crop Responses to Nanofertilizers for Mitigation of Multiple Environmental Stresses
This review examines how nanoscale fertilizers can help crops survive environmental stresses like drought, salt, and pollution by improving nutrient delivery at the cellular level. While focused on agricultural benefits, the research is relevant to microplastics because nanofertilizers may help plants cope with microplastic-contaminated soil. However, the authors caution that widespread use of nanoparticles in farming raises its own questions about potential effects on the environment and human health.
Aspersión foliar de nanoestructuras con zinc en plántulas de pepino (Cucumis sativus)
Not relevant to microplastics — this study tests the effects of zinc oxide nanostructures applied as foliar sprays on cucumber seedling growth, comparing different synthesis methods and a commercial zinc sulfate fertilizer.
Micro (nano) plastic pollution: The ecological influence on soil-plant system and human health.
This review examines how micro- and nanoplastics affect soil health, plant growth, and food quality, finding that these particles accumulate in plant root systems and can reduce crop yields and alter nutritional content. Since contaminated soil and water are increasingly delivering microplastics to food crops, these findings are directly relevant to agricultural food safety.
Towards Sustainable Management of Mineral Fertilizers in China: An Integrative Analysis and Review
This review examines strategies for sustainable management of mineral fertilizers in China, synthesizing research on improving nutrient use efficiency and reducing environmental impacts from fertilizer overuse. It is an agricultural science study unrelated to microplastics.
Nutrient Management Influences Root Characteristics and Nitrogen Use Efficiency in the Vegetable-Based Agroecosystem in the Northwestern Himalayas
This paper is not about microplastics — it evaluates how different fertilizer combinations affect root growth and nitrogen use efficiency in vegetable crops.
Unraveling the adverse Impacts of Nano-scale Carbon Exposure on Nitrogen Metabolism during Early Seedling Establishment in Zea mays L. Roots
This paper is not relevant to microplastics research — it examines how nano-scale carbon materials affect nitrogen metabolism and root development in early maize seedlings.
Reduced DNA methylation by Mn3O4 nanozyme protein corona formation improves cotton yield in saline land
Despite its title referencing nanoparticles and nanozymes, this paper studies how manganese oxide nanoparticles applied to cotton plant leaves improve crop growth and yield in salt-stressed soils — not microplastic pollution. It examines DNA methylation mechanisms and enzyme interactions in agricultural settings and is not relevant to microplastics or human health from plastic exposure.
The effects of microplastics on crop variation depend on polymer types and their interactions with soil nutrient availability and weed competition
Researchers investigated how different types of microplastics interact with soil nutrient availability and weed competition to affect crop growth. The study found that the effects of microplastics on plant performance depend on the polymer type and are modulated by fertilization levels and competition from weeds, suggesting that real-world agricultural impacts of microplastic pollution may be more complex than laboratory studies indicate.
Biopolymer-based nanocarriers for sustained release of agrochemicals: A review on materials and social science perspectives for a sustainable future of agri- and horticulture
This review examines how biopolymer-based nanocarriers can deliver fertilizers and pesticides more efficiently in agriculture, reducing the need for excessive chemical applications. Unlike conventional plastic-based delivery systems, these biodegradable carriers do not generate persistent microplastic pollution in farmland. The study also considers the social and economic factors that influence whether these environmentally friendly alternatives can successfully compete with conventional approaches.
Review of Crop Response to Soil Salinity Stress: Possible Approaches from Leaching to Nano-Management
This review covers approaches to managing soil salinity, a problem that threatens global food production, using methods ranging from traditional leaching to newer nanotechnology-based solutions. While not directly about microplastics, soil health is connected to microplastic contamination because plastic mulch films used in agriculture are a major source of microplastic pollution in farmland soils.
Micro and nano-plastics on environmental health: a review on future thrust in agro-ecotoxicology management
This review examines the growing body of evidence on how microplastics and nanoplastics affect plant health, soil microbial communities, and agricultural productivity. The study highlights that plastic accumulation in agricultural soils can alter crop growth and yield while disrupting soil ecosystem dynamics, and calls for greater attention to agro-ecotoxicology management to address these emerging threats to food production.
Micro/nanoplastics: a potential threat to crops
This review examines micro- and nanoplastic contamination in agricultural soil and water, summarizing sources, adsorption onto microplastics, uptake pathways into crops, effects on plant growth and physiology, and current detection and removal approaches, while highlighting the limited data on nanoplastic transport in plants.
Nanoparticles in Agriculture: Enhancing Crop Resilience and Productivity against Abiotic Stresses
This review examines how engineered nanoparticles can help crops withstand environmental stresses like drought, salinity, and heavy metal contamination. While not focused on microplastics directly, it discusses how nanotechnology interacts with similar biological pathways that microplastics disrupt in plants. The review also raises important concerns about the potential toxicity and environmental impact of adding more nanoparticles to agricultural systems.
Effects of micro(nano)plastics on soil nutrient cycling: State of the knowledge.
This review systematically examined how micro- and nano-plastics affect soil nutrient cycling for carbon, nitrogen, and phosphorus, finding that physical interference with soil structure, alteration of microbial communities, and chemical toxicity collectively disrupt mineralization, nitrification, and phosphorus availability in contaminated soils.
Nanofarming: Promising Solutions for the Future of the Global Agricultural Industry
This review covers how nanotechnology is being applied to improve agriculture through nanofertilizers, nanopesticides, and nanosensors that can boost crop yields while reducing environmental impact. While not directly about microplastics, the research is relevant because nano-based agricultural solutions could reduce reliance on plastic-intensive farming practices like plastic mulch films. Smarter farming technology may help decrease the amount of plastic entering agricultural soils.
Bibliometric analysis and review of direct factors implicating the impact of nano and microplastics on crop health and development
This review uses bibliometric analysis to map the research landscape on how nano- and microplastics affect crop health and agricultural productivity. Researchers found that the impacts depend on a complex interplay of factors including particle size, chemical composition, exposure duration, and soil conditions. The evidence indicates that these plastic particles accumulate in plant tissues and can reduce germination and growth rates, posing a growing concern for food security.
Unraveling consequences of soil micro- and nano-plastic pollution on soil-plant system: Implications for nitrogen (N) cycling and soil microbial activity
This review examines how micro- and nano-plastics affect soil microbial activity and nitrogen cycling in agricultural ecosystems, finding mixed effects that depend on polymer type and size. The authors highlight concerns about biodegradable plastics posing greater risks to plant growth than conventional plastics, complicating the assumption that biodegradable options are always safer.
Tiny pollutants, big consequences: investigating the influence of nano- and microplastics on soil properties and plant health with mitigation strategies
Researchers reviewed the impact of nanoplastics and microplastics on soil properties and plant health, examining absorption and translocation mechanisms in plants. The study suggests that plastic particles alter soil structure and microbial communities, impair plant growth and nutrient uptake, and proposes mitigation strategies to address these emerging threats to agricultural ecosystems.
[Effects of Three Different Types of Microplastics on Cucumber Growth and Nitrogen Utilization].
Researchers conducted a greenhouse pot trial examining the effects of three different microplastic types on cucumber growth and nitrogen utilization, finding that MP presence in soil disrupts normal nitrogen uptake and plant development, with effects varying by polymer type.
Editorial: Interaction of nano and microplastic with different plant species: concerns and opportunities
This editorial introduces research on how nano- and microplastics affect plants, covering both risks and potential opportunities. Plastics in agricultural soils can carry heavy metals and organic pollutants into crops, posing risks to food safety and ecosystem health.