Formation of O2 and CO2 reduction without Sunlight using Weak Energy of Water with pico-sized Particle

Medicon Agriculture & Environmental Sciences Pub Date : 2022-01-31 DOI:10.55162/mcaes.02.011

S. Sugihara

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引用次数: 2

Abstract

They have researched photosynthesis for approx. 250 years. They found the structure of chlorophyll in the 20th century, and photosynthesis has been elucidated as the total system by the Calvin cycle. Hereafter, they discussed the electron transfer in the chlorophyll. Since COP21, carbon-neutral has rapidly been a topic to decrease CO2, and they study even artificial photosynthesis repeatedly. Their researches are solar beam, CO2, and H2O involving plants. The discussion has not developed from there up to today. The chlorophyll receives sunlight leading to an electron transfer, when the manganese cluster dissociates H2O, then makes ATP. The enzyme catches CO2 and forms glucose. This system is the well-known Calvin-Benson cycle. Here is a point that we report, namely, non-sunlight. We may dissociate the hydrogen bonds of water and assume to form the pico-sized particles that help plants absorb water from their roots, and they are easy to get around in stems and leaves, resulting in reaction with CO2. The particles can emit far-infrared and terahertz under no sunlight, where we propose the agriculture factory with sustainable energy sources.

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利用微颗粒水的弱能在没有阳光的情况下形成O2和还原CO2

他们对光合作用的研究已有近十年的历史。250年。他们在20世纪发现了叶绿素的结构，并通过卡尔文循环阐明了光合作用是整个系统。此后，他们讨论了叶绿素中的电子转移。自COP21以来，碳中和迅速成为减少二氧化碳的主题，他们甚至反复研究人工光合作用。他们的研究方向是太阳光、二氧化碳和涉及植物的水。讨论并没有从那时发展到今天。叶绿素接受阳光导致电子转移，当锰簇解离H2O，然后产生ATP。这种酶捕获二氧化碳并形成葡萄糖。这个系统就是著名的卡尔文-本森循环。这是我们报告的一点，即非阳光。我们可以解离水的氢键，并假设形成帮助植物从根部吸收水分的微型颗粒，它们很容易在茎和叶中传播，从而与二氧化碳发生反应。这些粒子可以在没有阳光的情况下发射远红外和太赫兹，我们建议在那里建立可持续能源的农业工厂。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Medicon Agriculture & Environmental Sciences

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