TALE OF FOUR ELECTRONS

Tale of Four Electrons

Tale of Four Electrons

Introduction

Basic science research in conjunction with creativity and entrepreneurship has led to the boom in technology and standard of living over the past century in the developed world. These scientific breakthroughs have had wide ranging impacts on a variety of technologies from construction, automobiles, and aircraft, to telecommunications, medicine, and computation. Society has continuously tried to use its collective intelligence to further our understanding of the world around us on both macroscopic and microscopic levels to understand nature, even if the application is not immediate. While the society has many challenges that warrant considerable attention, two of the most profound are: the ability to discover or create abundant, cheap, and sustainable sources of energy and ways to execute computation with devices that become increasingly miniaturized. Nature has had the benefit of billions of years of evolution to develop the best way to convert visible light to usable forms of energy, and is an inspiration to scientists. Several events occur during photosynthesis light is first collected and funneled to a reaction center where charge separation occurs, following a series of electron and proton transfer steps to create a proton gradient that is used to drive the formation of adenosine triphosphate (ATP), which is utilized for carbon fixation. Therefore, all the issues related to the tale of four electrons will be discussed in detail.

Discussion

Bio-electronics is a possible approach to characterize in a quantitative manner through an aqueous medium. The relative simplicity of the measures provides contrast with the wealth of information that can be drawn. Bearing in mind the practical and theoretical limitations to this method, it is a valuable tool for analysis and research in many fields such as chemistry, biology, medicine, metallurgy and corrosion. In the present state of the knowledge, it only measures theoretical bio-electronic made ??in aqueous media which can be interpreted strictly, although the temptation is great to extend them to non-aqueous media or dispersed systems. Without a priority excluding this possibility, people limit themselves to the study of aqueous solutions where the level of intermolecular transfer of positive electrical charges (protons) and negative (electrons) are measurable. In addition, the ionizing power and very high electrical polarity of these environments facilitate electrostatic interactions and transport phenomena which are also used in the theory of bio-electronics. The microscopic aspects of it are obviously related to the structure of aqueous solutions. The image that many scientists are currently doing water at the molecular level consists of a network of more or less mobile electric charges whose order may contain a large number of information in the form of specific configurations variable stability. Bio-electronic, without giving a spatial image of the microscopic configurations, may delineate the macroscopic physical and chemical conditions for the existence of each type of configuration or molecular polarization. Vital phenomena are sensitive to these conditions; bio-electronic coordinates define a mathematical space in which to locate any biological activity including ...