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Water
Apr 1, 2018 17:46:13 GMT -5
Post by tarzan on Apr 1, 2018 17:46:13 GMT -5
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Water
Apr 1, 2018 20:02:33 GMT -5
Post by spacecase0 on Apr 1, 2018 20:02:33 GMT -5
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Water
Apr 2, 2018 5:25:18 GMT -5
Post by tarzan on Apr 2, 2018 5:25:18 GMT -5
that's cos it's not available u expect the CIA to let us buy that?
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Water
Apr 5, 2018 14:14:48 GMT -5
Post by tarzan on Apr 5, 2018 14:14:48 GMT -5
www.greenmedinfo.com/blog/can-humans-photosynthesize-1Does Water Transduce Energy?The energy for building water structure comes ultimately from the sun. Radiant energy converts ordinary bulk water into ordered water, building this structured zone. We found that all wavelengths ranging from UV through visible to infrared can build this ordered water. Near-infrared energy is the most capable. Water absorbs infrared energy freely from the environment; it uses that energy to convert bulk water into liquid crystalline water (fourth phase water) β which we also call "exclusion zone" or "EZ" water because it profoundly excludes solutes. Hence, buildup of EZ water occurs naturally and spontaneously from environmental energy. Additional energy input creates additional EZ buildup. Of particular significance is the fourth phase's charge: commonly negative (Figure 1). Absorbed radiant energy splits water molecules; the negative moiety constitutes the building block of the EZ, while the positive moiety binds with water molecules to form free hydronium ions, which may diffuse throughout the water. Adding additional light creates more charge separation. Figure 1. Diagrammatic representation of EZ water, negatively charged, and the positively charged bulk water beyond. Hydrophilic surface at left. This process resembles the first step of photosynthesis. In that step, energy from the sun splits water molecules. Hydrophilic chromophores catalyze the splitting. The process considered here is similar, but more generic: any hydrophilic surface may catalyze the splitting. Some surfaces work more effectively than others. Melanin might be one of those. The separated charges resemble a battery. That battery can deliver energy in a manner similar to the way the separated charges in plants deliver energy. Plants, of course, comprise mostly water, and it is therefore no surprise that water itself could exhibit similar energy conversion. The stored electrical energy in water can drive various kinds of work, including flow. An example is the axial flow through tubes. Immersing tubes made of hydrophilic materials into water produces flow through those tubes (3), similar to blood flow through blood vessels (Figure 2). The driving energy comes from the radiant energy absorbed and stored in the water. Nothing more. Flow may persist undiminished for many hours, even days. Additional incident light brings faster flow (4). This is not a perpetual motion machine: incident radiant energy drives the flow β in much the same way that it drives vascular flow in plants and powers water from the roots to nourish trees taller than the length of a football field. By volume, two thirds of your cells' content is water. However the water molecule is so small that making up that two-thirds volume involves numerous water molecules. If you count molecules, 99% of the molecules in your body are water molecules. Modern cell biology considers that huge fraction of molecules as mere background carriers of the "important" molecules of life such as proteins and nucleic acids. It asserts that 99% of your molecules don't do very much. However, EZ water envelops every macromolecule in the cell. So tightly packed are those macromolecules that little room exists for any but liquid-crystalline EZ water. Most of your cell water is EZ water. ..... the ordered phase water plays a central role in everything the cell does. ....radiant energy, ... can power many of those cellular functions. An example is the blood flowing through your capillaries. That blood eventually encounters high resistance: capillaries are often narrower than the red blood cells that must pass through them; in order to make their way through, red cells need to bend and contort. Resistance is high. You'd anticipate the need for lots of driving pressure; yet, the pressure gradient across the capillary bed is modest. The paradox resolves if radiant energy helps propel flow through capillaries in the same way that it propels flow through hydrophilic tubes. Radiant energy may constitute an unsuspected source of vascular drive, supplementing cardiac pressure. more at link
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