In 2006, a team of international scientists announced they had created a new form of hydrogen, called “hydrino”, using a process called “cold fusion”. This opens up the possibility of producing energy cheaply and safely, without the radioactive by-products of conventional nuclear power.
The new process involves heating a cup of water to just below its boiling point and then bombarding it with ultrasound. This causes the water to break down into its constituent atoms, which then recombine to form “hydrinos”. These are a new form of hydrogen with a lower energy state than normal hydrogen.
When the “hydrinos” are burned in a conventional power plant, they release far more energy than burning normal hydrogen. This could theoretically provide enough energy to power the world for centuries, without the dangers of radioactive waste or greenhouse gas emissions.
The scientists behind the discovery are now working on a prototype power plant, which they hope will be operational within a few years. If successful, this could be the biggest energy breakthrough in history.
We have a genuine fusion energy breakthrough.
Yes, you read that right – we may have finally achieved sustained nuclear fusion, which could potentially provide limitless energy and end our dependence on fossil fuels.
The key to this breakthrough is a new type of plasma – a superhot, electrically charged gas – that can be heated to extremely high temperatures without melting the surrounding walls. This is thanks to a new technique called magnetic field stabilization, which confines the plasma using magnetic fields.
So far, the results have been promising, with the new plasma sustaining itself for over five minutes – a new record. The next step is to see if this can be scaled up to a power plant-sized device, which could provide clean, safe and limitless energy to the world.
Of course, there is still a long way to go and many challenges to overcome, but this is a genuinely exciting breakthrough that could change the world as we know it.
It’s been a long time coming, but we may finally have a genuine fusion energy breakthrough.
After decades of research and development, scientists have finally managed to create a sustained nuclear fusion reaction in a laboratory setting. This is a significant milestone, as it is the first time that nuclear fusion has been achieved without using prohibitively expensive and difficult-to-maintain equipment.
The breakthrough was made by a team of researchers at the Princeton Plasma Physics Laboratory in the US. Using a device known as a “tokamak”, they were able to heat and compress a small amount of hydrogen gas to the point where the atoms fused together, releasing a huge amount of energy.
While this is only a small-scale proof-of-concept, it raises the prospect of eventually being able to produce fusion energy on an industrial scale. This would be a game-changer, as fusion reactors would be much cleaner and more efficient than the current generation of nuclear fission reactors.
The race is now on to build a larger tokamak that can produce more fusion power for longer periods of time. If successful, this could lead to the first commercial fusion power plant being operational within the next few decades.
So far, the results are very promising. We may finally be on the brink of harnessing the power of the stars.
In the 1970s, scientists began to theorize about the possibility of using fusion to create clean, unlimited energy. But despite significant progress in the intervening years, this “holy grail” of energy has remained elusive.
Now, however, it appears that we may finally have a genuine fusion energy breakthrough.
In the last few months, a number of organizations have announced significant progress in the development of fusion reactors.
The most notable of these is the Iter project, a massive international collaboration involving 35 nations. Iter is building a prototype fusion reactor in France, and it is on track to begin operation in 2025.
If Iter is successful, it will be a major step forward for fusion energy. But even if it is not, the recent progress made by other organizations suggests that fusion energy may finally be within our grasp.
So what is fusion, and how could it provide us with clean, unlimited energy?
In short, fusion is the process of combining atoms to form new atoms. This is the same process that powers the sun and other stars.
Fusion reactions release huge amounts of energy, but they also produce very little radioactive waste. In fact, the radioactivity produced by fusion is about the same as that produced by natural background radiation on Earth.
Fusion energy has the potential to provide us with clean, safe, and unlimited energy. But despite significant progress in recent years, it remains elusive.
The key to making fusion energy a reality is to confine the extremely hot plasma that is created during a fusion reaction. This plasma is so hot that it is impossible to confine it using traditional methods, such as containment vessels made of steel.
Instead, scientists must use magnetic fields to confine the plasma. This is a very difficult task, but it is one that researchers have made significant progress on in recent years.
The most promising method for containing plasma is called magnetic confinement fusion. In this approach, the plasma is confined using strong magnetic fields.
The most advanced magnetic confinement fusion reactor is currently the Iter project in France. If Iter is successful, it will be a major step forward for fusion energy. But even if it is not, the recent progress made by other organizations suggests that fusion energy may finally be within our grasp.
We have a genuine fusion energy breakthrough.
In the race to create a new, more environmentally friendly energy source, one company has taken a big step forward. General Fusion, a Canadian company, has announced a major breakthrough in the development of fusion energy.
The company has successfully created a magnetic field that can confine and control a plasma, the super-hot state of matter that is key to fusion. This is a significant achievement, as previous attempts at magnetic confinement have been unsuccessful.
The next step for General Fusion is to build a prototype power plant. If all goes well, the company could be generating commercial-level power within a decade.
Fusion energy has the potential to be a game-changer. It is clean, safe, and environmentally friendly. Unlike fossil fuels, it does not produce greenhouse gases. And, unlike nuclear power, it does not create dangerous radioactive waste.
With the world searching for new energy sources, the timing couldn’t be better for a breakthrough like this. General Fusion’s achievement is an important step on the road to a cleaner, brighter future.
Fusion energy is the holy grail of physics and engineering. For over a hundred years, scientists have been trying to harness the power of the sun and use it to produce electrical energy. The idea is to use the sun’s energy to heat up a plasma to the point where the nuclei of the atoms fuse together, releasing a huge amount of energy. This fusion reaction is what powers the sun, and it has the potential to produce virtually limitless energy here on earth.
The problem has always been that it is incredibly difficult to contain and control a plasma hot enough to fuse atoms together. But now, scientists at the University of Washington have taken a major step forward in making fusion energy a reality. They have successfully fused together atoms of hydrogen in a plasma for the first time, using a new device called a field-reversed configuration (FRC) reactor.
This breakthrough is a key milestone on the road to fusion energy. The next step is to scale up the device so that it can produce more power. The University of Washington team is already working on this, and they are confident that they can make fusion energy a reality within the next few decades.
If they are successful, the implications will be huge. Fusion energy would provide a virtually limitless supply of clean, green energy that could power the world for centuries to come. It would be the ultimate solution to climate change, and it would allow us to phase out fossil fuels completely.
So far, the University of Washington team’s achievement is just a small step on the road to fusion energy. But it is a hugely important one. It shows that fusion energy is possible, and it brings us closer than ever to making this incredible technology a reality.
We have a genuine fusion energy breakthrough. The long-awaited fusion reaction that could provide an almost limitless supply of energy has been successfully achieved in a laboratory for the first time.
The reaction, which takes place in an ultra-hot plasma, was triggered using a powerful laser at the National Ignition Facility (NIF) in California.
It is a key step forward in the quest to create a fusion reaction that can be used to generate electricity, and it could lead to a new era of clean, safe and sustainable energy production.
The experiment was conducted by a team of scientists from the US, UK, Germany and Japan, and the results are published in the journal Nature.
In the experiment, a laser was used to heat and compress a tiny pellet of deuterium and tritium, the two heaviest isotopes of hydrogen.
This created conditions in which the nuclei of the atoms fused together, releasing a huge amount of energy.
It is the first time that such a reaction has been achieved using a laser-based method, and it opens up the possibility of using fusion energy to generate electricity on a commercial scale.
Currently, nuclear fusion reactors are not yet capable of generating more energy than they consume. But the new results show that it is possible to create the necessary conditions for a self-sustaining fusion reaction.
The next step is to scale up the experiment to a larger size, which would be necessary for a commercial fusion reactor.
If successful, fusion energy could provide a virtually limitless supply of clean, safe and sustainable energy. It would also have a major impact on climate change, as it does not produce greenhouse gases.
The promise of fusion energy has been elusive for decades, but these latest results bring us closer than ever to making it a reality.