Wireless Power Transmission

Wireless Power Transmission through inductive coupling is one of the new emerging technologies that will bring tremendous change in human life. Due to shortage of time and fast running life style it is difficult to carry the complete charging set which increases the demand of the wirelessly charged products. Wireless power transfer is one of the simplest and inexpensive ways of charging as it eliminate the use of conventional copper cables and current carrying wires. In this paper, a technique is devised for a wireless power transfer through induction, and a feasible design is modeled accordingly. The technique used in this paper is the inductive coupling as it the easiest method of high efficiency power transfer without using wired medium (eg, transformer). In this paper the result of experiment is given which is done to check wireless working of a simple application by glowing LED, and charging a mobile. Wireless power transfer is not much affected by placing hurdles likes books, hands and plastic between transceiver and receiver. This research work focuses on the study of wireless power transfer for the purpose of transferring cut and dried amount of energy at maximum efficiency

Microbial Responses to Carbon Sequestration Soil Amendment and Productivity

Soil a significant carbon sink, plays a pivotal role in mitigating climate change. This review underscores the potential of soil amendments for enhancing carbon sequestration, focusing on the intricate relationship between these amendments and soil microbial communities. Soil amendments, ranging from biochar and organic compost to mineral additives, have been identified as viable strategies to boost soil carbon stocks. Concurrently, these amendments influence the diversity, structure, and functional roles of microbial communities, which in turn, are integral to soil carbon dynamics. Tools like 16S rRNA sequencing, metagenomics, and isotope tracing techniques have propelled our understanding of microbial responses, shedding light on the complex microbial networks and their roles in carbon cycling. While promising, the application of soil amendments presents challenges. Variability arising from different soil types, climates, and microbial dynamics poses a consistent research challenge. Potential risks like reduced sequestration over time and economic considerations for large-scale application necessitate attention. Future directions hinge on innovations in soil amendment products, harnessing microbial inoculants for synergistic effects, and fostering interdisciplinary collaborations. This convergence of science, technology, and collaborative research heralds a future where soils are not just seen as substrates but as active, dynamic entities in the fight against climate change