ABSTRACT
Continuous cropping and frequent soil cultivation contribute to the breakdown of soil aggregates and the removal of organic matter, which reduces soil fertility and production. Green manuring is a low-cost and efficient approach for reducing the expense of inorganic fertilizers and preserving soil fertility. Due to the mounting problems facing agriculture, including climate change, extreme weather events, soil deterioration, and land contamination as a result of the overuse of chemical fertilizers, many farmers are adding green manuring into their methods to prevent soil erosion, improve soil structure, control weed growth, and most importantly increase the soil's fertility. The use of green manure has drastically decreased, raising concerns about the sustainability of soil fertility. Field crops may experience a temporary setback following the integration of organic residues with a high C-N ratio. By enhancing the soil's structure, fertility, and nutrient content, green manuring functions as a restoration factory to maintain the soil's fertility for sustainable agriculture. Green manure is therefore essential for growers that seek to decrease the use of dangerous chemicals for soil fertilization. Many farmers must use green manure in their operations to avoid the usage of chemical fertilizers in agriculture.
ABSTRACT
The utilization of nanomaterials in agriculture has gained significant attention due to their potential to induce changes in plant physiology and genetics, thereby offering new avenues for enhancing crop improvement strategies. This paper delves into the intricate interplay between nanomaterials and plants, shedding light on their molecular mechanisms of uptake and interaction. It explores the physiological responses that ensue following nanomaterial exposure, unraveling the intricate network of signaling pathways and stress responses. Moreover, the paper delves into the alterations in genetic expression triggered by nanomaterials, providing insights into the underlying regulatory mechanisms. The influence of epigenetic factors and potential transgenerational effects further accentuates the complexity of these interactions.Underpinning this understanding, the paper discusses the prospects of harnessing nanomaterial-induced changes to enhance crop traits. It investigates how these changes can be employed to boost crop resilience, nutrient uptake, and stress tolerance. The integration of nanomaterial-induced alterations into breeding and genetic modification strategies offers a promising approach for developing improved crop varieties. Ultimately, this comprehensive exploration of nanomaterial-induced changes in plant physiology and genetics highlights their far-reaching implications for revolutionizing crop improvement strategies in the face of evolving agricultural challenges.