The effects of climate change are one of the most urgent problems now confronting our world. Because of the growing concentrations of greenhouse gases, particularly carbon dioxide, in the atmosphere, the average surface temperature of the Earth is climbing at a startlingly rapid pace. This warming is producing a wide variety of effects, including changes in the distribution of plant and animal species as well as more intense weather patterns. However, the use of biochips is one approach that is being investigated as a potential solution to the problem of climate change.
Biochips are engineered substrates on which multiple biochemical reactions can take place at the same time. In nature, biochips, also known as plant-based chips or green chips, are a kind of technology that utilizes live organisms, such as plants, to absorb carbon dioxide from the air.The concept ofplant-basedbiochips is predicated on the fact that plants convert the carbon dioxide they take in during photosynthesis into oxygen and other organic compounds. By cultivating a large number of plants as biochips, it is possible to remove vast volumes of carbon dioxide from the air. The world’s repercussions from climate change may be lessened if this happens.
Benefits of using biochips
One of the most significant advantages of using biochips for carbon capture is the fact that they are an entirely natural and regenerative source of the material. In contrast to other methods of carbon capture, such as carbon capture and storage (CCS) or carbon capture and utilization (CCU), which are dependent on intricate mechanical systems and chemical processes, biochips are entirely dependent on the inherent capabilities of plants. This makes them a more sustainable and cost-effective solution for carbon capture. One further advantage of using biochips is that they may be used to enhance the quality of the air. It has been shown that a great number of plants possess air-purifying capabilities, which may assist in the removal of air pollutants such as volatile organic compounds (VOCs) and particulate matter (PM) from the atmosphere. It is feasible to remove carbon dioxide from the environment and enhance the air quality overall if plants are grown on biochips. This may be accomplished by cultivating plants on the chips.
Florence Hymore’s research on biochip technologies
Florence Hymore is a Canada-based Development Consultant who has worked in the areas of environment protection, climate change, sustainable growth, and food and health biotechnology. As a researcher, she plays an essential part in developing potential answers to the problem of climate change as well as in the process of biochips and nanotech solutions. She has carried out numerous research studies in order to get an understanding of the factors that contribute to climate change, as well as viable responses to the problem from an Ecosystemic approach. Her work is essential to the advancement of our knowledge of the climate of the Earth as well as the development of new technology that may assist in mitigating the effects of climate change.
Florence has also made significant contributions to the area of biochip solutions in a number of important ways. One of the most important methods is by examining the biology of a variety of plant species in order to determine which ones are the best at removing carbon dioxide from the air. She analyzed various experimental outcomes in order to ascertain the capacity of various plant species to take in carbon dioxide and to get an understanding of the influence that environmental conditions such as temperature, light, and humidity have on that capacity. In addition to this, she has also investigated nanotechnological approaches to using biochips to manage the ecosystem, as well as how the plants may be used to clean the air.
The current state of the climate is a worldwide emergency that demands quick intervention. According to Florence, biochips are a sort of carbon capture technology that is both natural and renewable; moreover, they give an encouraging option. In addition to lowering atmospheric concentrations of carbon dioxide and improving air quality, biochips may also be utilized to generate electrical power. However, she believes that there are still some challenges to overcome, such as scaling up the technology and reducing costs. Because of this, she is still working very hard to bridge those gaps in order to address the climate change crisis in a more effective manner, and she further aims to find out more innovative and sustainable solutions.
References: https://www.elprocus.com/what-is-a-biochip-and-types-of-biochips/
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