Dr. Brian Josephson, winner of the 1973 Nobel Prize in Physics for his work on superconductivity, has recently released a YouTube video of an interview of himself conducted by Judith Driscoll, Professor of Materials Science at Cambridge University. The video is also published on the Cambridge University website.
In the video, Dennis M. Bushnell – Chief Scientist at the NASA Langley Research Center – says that the Rossi e-cat reactor:
This is capable by itself of completly changing geoeconomics, geopolitics and solving climate and energy.
Professor Josephson is also very hopeful that the e-cat will be a breakthrough on par the first flight of the Wright brothers.
Popular Science reports:
A wee particle accelerator in the English countryside could be a harbinger of a safer, cleaner future of energy. Specifically, nuclear energy, but not the type that has wrought havoc in Japan and controversy throughout Europe and the U.S. It would be based on thorium, a radioactive element that is much more abundant, and much more safe, than traditional sources of nuclear power.
Some advocates believe small nuclear reactors powered by thorium could wean the world off coal and natural gas, and do it more safely than traditional nuclear. Thorium is not only abundant, but more efficient than uranium or coal — one ton of the silver metal can produce as much energy as 200 tons of uranium, or 3.5 million tons of coal, as the Mail on Sunday calculates it.
The newspaper took a tour of a small particle accelerator that could be used to power future thorium reactors. Nicknamed EMMA — the Electron Model of Many Applications — the accelerator would be used to jump-start fissile nuclear reactions inside a small-scale thorium power plant.
Thorium reactors would not melt down, in part because they require an external input to produce fission. Thorium atoms would release energy when bombarded by high-energy neutrons, such as the type supplied in a particle accelerator.
Techie Buzz notes:
A miniature particle accelerator, small enough to be stashed away in your basement, can be used to produce nearly unlimited amounts of nuclear energy, in a controlled manner, using the radioactive element thorium.
Scientists have long looked at a radioactive element other than Uranium as a potential candidate for producing nuclear power – Thorium. Thorium research is, however, at its infancy, given that the focus of all nuclear research has focused on Uranium. Thorium is found widely, easily refined, extremely safe to handle and leaves no residue after fission. Thorium produces about 200 times the energy produced by Uranium and produces no carbon dioxide. The only catch is that, for fission, it needs to be initiated by bombardment with charged particles, such as electrons. This is a happy handicap, since a Thorium reactor would be incapable of a meltdown. After Fukushima, this maybe the new global fool-proof safety standard.
Enter EMMA. EMMA can deliver the required accelerated electrons onto a Thorium core, producing energy in a process that is much more controlled than Uranium fission … A nation powered by only Thorium based nuclear energy would leave no carbon footprint or nuclear waste and would not run out of energy in the next 10,000 years.
EMMA could usher in new-generation, clean and danger-free nuclear power plants, something that is considered an oxymoron today.
Moreover, as Popular Science points out in another article, a new alloy can convert heat directly into electricity:
A new alloy with unique properties can convert heat directly into electricity, according to researchers at the University of Minnesota. The alloy, a multiferroic composite of nickel, cobalt, manganese and tin, can be either non-magnetic and highly magnetic, depending on its temperature.
Multiferroic materials possess both magnetism and ferroelectricity, or a permanent electric polarization. Materials with both of these properties are very rare; check out this explainer from the National Institute of Standards and Technology if you’re interested in the electron orbital arrangements that cause these phenomena.
One obvious use for this material would be in the exhaust pipes of vehicles. Several automakers are already working on heat transfer devices that can convert a car’s hot exhaust into usable electricity; General Motors is using alloys called skutterudites, which are cobalt-arsenide materials doped with rare earths.
Rare earth magnets are already a necessity in many hybrid car batteries, so heat-capture devices made of the new multiferroic compound could be placed near the magnets.
The material could also be used in power plants or even ocean thermal energy generators, the researchers said.
Indeed, as I wrote in April:
Power can also be captured from excess heat energy. As I’ve previously noted:
Heat can be used to generate electricity. This is true not only on the industrial scale, but even on the level of your home faucet. Indeed, inventors have already built home faucet kits which turn the unused heat from your hot water into electricity.
In hot climates, black thermal-electric mats could be installed on roofs to generate electricity.
Heat is a byproduct of other processes, and so nothing special needs to be done to create it. Just about every human activity and many natural processes create heat, so we just have to utilize it.
A dramatic example of wasted heat energy is the Oak Creek coal-fired power plant in Wisconsin. The two units at Oak Creek suck up two billion gallons of water from Lake Michigan each day, and pipe it back into lake 10-15 degrees warmer. All of that heat energy is wasted.
So a new alloy which directly converts heat into energy is exciting.
And as I noted last year:
Due to high oil prices, major breakthroughs in energy production are happening every day.
- A scientist has figured out how to make and store energy by splitting water with sunlight. He says: “You’ve made your house into a fuel station [and we can get] rid of all the … grids” [he’s recently discovered an even cheaper way to do this] …
- It has been discovered that alcohol made from donuts, grass and other abundant materials can run cars and all other engines [see below]
And as I’ve written before, alcohol has more alternative energy applications than you might know:
There’s a secret history regarding alcohol that you won’t hear on the six o’clock news:
- Cars and everything else running on internal combustion engines can run on alcohol at least as well as they can run on gasoline. Indeed, engines were built back in 1870 that could run using either alcohol or gasoline
“Autoists Discuss Alcohol As Fuel; Great Future Ahead For Use In Commercial Wagons, Says Prof. Lucke. Tests With Motor Truck E.R. Hewitt Tells Engineers Of His Results With Gasoline And Alcohol In Same Engine”
- Henry Ford said that alcohol was “a cleaner, nicer, better fuel for automobiles than gasoline” (James Brough, The Ford Dynasty: An American Story, p. 118, and cited in “Ford – The Men and the Machine”, p. 365). The Model T Ford had a knob right on the dashboard to adjust the fuel-air mixture for either alcohol or gas
- Alcohol does not corrode or shorten the lifespan of modern cars, and an inexpensive adjustment to regular cars will make them run smoothly and inexpensively on alcohol
Moreover, those in the know actually are using alcohol as a fuel today. For example, there are many millions of cars being driven in Brazil that run on alcohol.
And many government and car fleets are actually required to be able to run on either alcohol or gas. The car companies simply forgot to tell the American consumer that these kind of cars are available. See this and this.
Indeed, as I’ve previously noted, running equipment using alcohol should not increase food prices:
The leading proponents of alcohol as fuel are not talking about corn. Corn is a lousy crop for making alcohol, and there are many other crops that are much more efficient. Indeed, the leaders in this field promote growing a wide variety of crops (appropriate for whatever specific climate you live in), and many of the crops they suggest are also valuable food crops.
And you don’t even need to use plants . . . you can make alcohol fuel out of rotten fruit, stale soft drinks or donuts.
Indeed, in a decidedly old-fashioned spin on the still and moonshine-making as livelihood during the Great Depression, engineer and alcohol production expert David Chu points out that we can create alcohol for our machines, mash to raise mushrooms, earthworms and fish, and CO2 for our garden all at the same time – producing a livelihood for ourselves in the process: