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NewHydrogen CEO Steve Hill Discusses the Need for Efficient Hydrogen Production Methods with Chair of Environmental Studies at Rhodes College - Seite 2
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0 KommentareDr. Eckenhoff received his Ph.D. in Inorganic Chemistry from Duquesne University. He is a synthetic inorganic chemist specializing in the synthesis of copper, iron, cobalt, nickel and molybdenum complexes. Research in Dr. Eckenhoff’s lab has two main projects underway. The first project investigates the design, synthesis, and testing of nickel and cobalt complexes as catalysts for hydrogen production in artificial photosynthesis. A clean and inexpensive method of producing hydrogen gas is vital for the creation of a future hydrogen economy. The second project looks at a group of Molybdenum complexes which exhibit a stunning and previously unknown solvatochromic effect, or color-change in different solvents. These compounds have potential applications in sensor technology and also enhance our understanding of polarity. Dr. Eckenhoff is listed as Google Scholar at https://scholar.google.com/citations?user=2vwrl6kAAAAJ.
Watch the full discussion on the NewHydrogen Podcast featuring Dr. Eckenhoff at https://newhydrogen.com/videos/ceo-podcast/dr-william-eckenhoff-rhodes ....
For more information about NewHydrogen, please visit https://newhydrogen.com/.
About NewHydrogen, Inc.
NewHydrogen is developing ThermoLoop – a breakthrough technology that uses water and heat rather than electricity to produce the world’s lowest cost green hydrogen. Hydrogen is the cleanest and most abundant element in the universe, and we can’t live without it. Hydrogen is the key ingredient in making fertilizers needed to grow food for the world. It is also used for transportation, refining oil and making steel, glass, pharmaceuticals and more. Nearly all the hydrogen today is made from hydrocarbons like coal, oil, and natural gas, which are dirty and limited resources. Water, on the other hand, is an infinite and renewable worldwide resource.
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Currently, the most common method of making green hydrogen is to split water into oxygen and hydrogen with an electrolyzer using green electricity produced from solar or wind. However, green electricity is and always will be very expensive. It currently accounts for 73% of the cost of green hydrogen. By using heat directly, we can skip the expensive process of making electricity, and fundamentally lower the cost of green hydrogen. Inexpensive heat can be obtained from concentrated solar, geothermal, nuclear reactors and industrial waste heat for use in our novel low-cost thermochemical water splitting process. Working with a world class research team at UC Santa Barbara, our goal is to help usher in the green hydrogen economy that Goldman Sachs estimated to have a future market value of $12 trillion.
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