The Future of Energy: Cold Fusion for US and China

NASA_coldfusionThe science behind cold fusion has been a source of constant controversy for decades. Not only has this pursuit turned up its share of phony claims, the fact that it also promises to yield clean, abundant energy on the cheap has led to no shortage of romantic endorsements and vocal detractors. But if it could be made to work, there is no doubt that our energy problems would be solved, and in a way that is not harmful to our environment.

Last February, NASA made waves by announcing that they were working towards cold fusion through low-energy nuclear reaction (LENR) technology. Then in September, the National Ignition Facility (NIF) in California announced a major milestone when they managed to produce a controlled reaction that provided more energy that was required to start it.

e-cat1But all of that seemed to pale in comparison to the announcement by Andrea Rossi’s that he managed to create a fusion power plant that was reportedly capable of generated a single megawatt of power. Known as the E-Cat 1MW Plant (short for Energy-Catalyser), Rossi announced its creation back in November, and indicated that he and his company were taking pre-orders and that they would start deliveries by 2014.

Today, the big news is that a large US investment company has acquired the rights to the cold fusion LENR technology. That investment company is Cherokee Investment Partners, and they appear to be interested in deploying the cold fusion tech commercially in both China and the US to meet both countries existing and projected energy needs.

fusion_energyRelying on the same process as other LENR technology, the E-Cat generates cold fusion by taking nickel and hydrogen and fusing them into copper – a process that has 10,000 times the energy density of gasoline, and 1,000 times the power density. Rossi says he’s found a special catalyst that makes the process work, but many scientists remain unconvinced.

Regardless of whether or it not it can deliver, it now seems that Rossi’s previously allusions to an American partner are true after all. Much like everything surrounding Rossi, he chose to be nebulous about the identity of the company that was supporting him. However, with this latest deal, Cherokee and its CEO Thomas Darden, a man who has a history of investing in clean energy, is a believer in the design.

e-cat3In addition to preparing the patents through a Limited Liability Company – known as Industrial Heat – there are also reports that Darden recently visited China to showcase the E-Cat to Chinese officials and businesspeople. China is reportedly looking at using the E-Cat to significantly reduce its carbon footprint and meet its the energy needs of its growing cities in a way that won’t generate more air pollution.

Needless to say, this deal has bolstered Rossi’s and the E-Cat’s credibility, but the technology remains unproven. Rossi says that he has a team of international scientists that are planning to do another round of tests on the E-Cat which are slated to end in March, with a peer-reviewed report to follow sometime after that. Fingers crossed, those rounds of test will provide conclusive proof.

Then, we can all get to work dreaming about a bright, clean future, and the thousands of applications such plants will have!

Source: extremetech.com

The Future of Fusion: 1-MW Cold Fusion Plant Now Available!

fusion_energyIt’s actually here: the world’s first fusion power plant that is capable of generated a single megawatt of power and is available for pre-order. It’s known as the E-Cat 1MW Plant, which comes in a standard shipping container and uses low-energy nuclear reactions (LENR) – a process, often known as cold fusion, that fuses nickel and hydrogen into copper – to produce energy 100,000 times more efficiently than combustion.

E-Cat, or Energy Catalyzer, is a technology (and company of the same name) developed by Andrea Rossi – an Italian scientist who claims he’s finally harnessed cold fusion. For just $1.5 million, people can pre-order an E-Cat and expect delivery by early 2014. With this news, many are wondering if the age of cold fusion, where clean, abundant energy is readily available, is finally upon us.

E.Cat1Cold fusion, as the name implies, is like normal fusion, but instead of producing fast neutrons and ionizing radiation that decimates everything in its path, cold fusion’s Low-Energy Nuclear Reactions (LENR) produce very slow, safe neutrons. Where normal fusion requires massive, expensive containment systems, it sounds like E-Cat’s cold fusion can be safely contained inside a simple, pressurized vessel.

And while normal fusion power is generated by fusing hydrogen atoms, cold fusion fuses nickel and hydrogen into copper, by way of some kind of special catalyst. Despite the rudimentary setup, though, cold fusion still has the massive power and energy density intrinsic to atomic fusion. In short, it produces far more energy than conventional chemical reactions – such as burning fossil fuels. The only challenge is, the massive amounts of power that are usually required to initiate the reaction.

e.cat2According to E-Cat, each of its cold fusion reactors measures 20x20x1 centimeters (7.8×7.8×0.39 inches) and you stack these individual reactors together in parallel to create a thermal plant. The E-Cat 1MW Plant consists of 106 of these units rammed into a standard shipping container. Based on the specs provided by Rossi, the fuel costs works out to be $1 per megawatt-hour, which is utterly insane. Coal power is around $100 per megawatt-hour.

But before anyone gets too excited about the commercialization of cold fusion, it should be noted that Rossi is still being incredibly opaque about how his cold fusion tech actually works. The data sheet for the 1MW Plant shares one interesting tidbit: Despite producing 1MW of power, the plant requires a constant 200 kilowatts of input power — presumably to sustain the reaction.

E.Cat5_-1030x858The spec sheet also says that the fuel (specially treated nickel and hydrogen gas) needs to be recharged every two years. One of the science community’ biggest sticking points about Rossi’s cold fusion devices is that he hasn’t proven that his LENR is self-sustaining. Despite a huge amount of output energy, the device still needs to be connected to the mains.

What’s more, due to a lack of published papers, and thus peer review, and a dearth of protective patents, the scientific community in general remains very wary of Rossi’s claims. And of course, we should all remember that this is not the first time that researchers have proclaimed victory in the race to make cold fusion happen. Whenever the words “cold fusion” are raised in conjunction, the case of the Fleischmann–Pons experiment immediately springs to mind.

NASA_coldfusionFor those who remember, this case involved an experiment made in 1989 where two researchers claimed to have achieved cold fusion using palladium rods and heavy water. Initially, the scientific community treated the news with exciteent and interest, but after numerous labs were unable to reproduce their experiment, and a number of false positives were reported, their claims were officially debunked and they relocated their lab to avoid any further controversy.

At the same time, however, one must remember that some significant changes have happened in the past three decades. For one, NASA’s LENR facility has been working on producing cold fusion reactions for some time using an oscillating nickel lattice and hydrogen atoms. Then there was the recent milestone produced by the National Ignition Facility in California, which produced the first fusion reaction using lasers that produced more energy than it required.

Who’s to say if this is the real deal? All that is known is that between this most recent claim, and ongoing experiments conducted by NASA and other research organizations to make LENR cold fusion happen, a revolution in clean energy is set to happen, and will most likely happen within our lifetimes.

Addendum: Just been informed by WordPress that this is my 1400th post! Woot-woot!

Sources: extremetech.com, ecat.com

The Future is Here: Self-Healing Metal

self-healing_metalYou’ve heard of self-healing concrete, you’ve heard of self-healing polymers. And now, it seems that researchers at MIT have found a way to make metals heal themselves after tiny cracks form. As the latest in a series of materials that is capable of maintaining itself, this discovery could very well help pioneer the revolution in manufacturing everyone has been waiting for.

Led by graduate student Guoqiang Xu and professor Michael Demkowicz, the process of getting metals to heal themselves was made almost entirely by accident. The discovery first came when they were modelling a sheet of nickle and tiny microscopic cracks were applied. Once tension was applied, the cracks became smaller and then disappeared as the edges fused together.

crystallineApparently, the key has to do with the fact that most metals are composed of microscopic crystalline grains, the size and orientation of which affect the overall strength and characteristics of the material. Nickel has always been of interest because of its use in so many superalloys, many of which are used in harsh environments – jet turbines, deep sea oil rigs, heavy industry joints.

It turns out that the grains making these materials so strong are not as static as scientists thought. As the metal is pulled outward, the edge of the crystalline grains begins to migrate and can eventually fill in the crack completely. The migration of this crystalline boundary is what heals the gaps in the material. And while it is not exactly polymorphic alloy (see pic below), its certainly big news.

metal_fatigueAnd while researchers have only been able to reproduce this healing behavior with cracks at the microstructural level (known as disclination), these micro-defects are the source of much larger and sometimes catastrophic cracks and metal fatigue. The geometry of disclinations can actually reverse an applied force locally, which is how the tension leads to the metal pulling itself back together.

The team believes this newfound knowledge can be used to prevent superalloys from accumulating structural cracks that could lead to real damage with time. Materials could also be designed to direct damage into disclination-type structures, areas that could absorb damage and then heal themselves. Given time, it could even lead to metals that don’t weaken with age.

t1000Still, you shouldn’t be expecting something like this guy anytime soon! And be sure to enjoy this brief but poignant video of the self-healing effect in action:


Source:
extremetech.com