The site in Sichuan province will help the country deal with growing quantities of radioactive material as it steps up its use of nuclear power.
Category: nuclear energy
Researchers at the International Thermonuclear Experimental Reactor debuted the first part of a massive magnet they’ll use to build a fusion reactor.
That successful demonstration paves the way for practical, commercial, carbon-free power.
Our partners at UK Atomic Energy Authority and Createc brought Spot to Sellafield Ltd to demonstrate how Spot can automate nuclear inspections
Posted in nuclear energy, robotics/AI | Leave a Comment on Our partners at UK Atomic Energy Authority and Createc brought Spot to Sellafield Ltd to demonstrate how Spot can automate nuclear inspections
Our partners at UK Atomic Energy Authority and Createc brought Spot to Sellafield Ltd to demonstrate how Spot can automate nuclear inspections, support decommissioning, and reduce risk for people in hazardous environments. Watch the full video: https://bit.ly/3ttOgcr
What we need now is an expansion of public and private investment that does justice to the opportunity at hand. Such investments may have a longer time horizon, but their eventual impact is without parallel. I believe that net-energy gain is within reach in the next decade; commercialization, based on early prototypes, will follow in very short order.
But such timelines are heavily dependent on funding and the availability of resources. Considerable investment is being allocated to alternative energy sources — wind, solar, etc. — but fusion must have a place in the global energy equation. This is especially true as we approach the critical breakthrough moment.
If laser-driven nuclear fusion is perfected and commercialized, it has the potential to become the energy source of choice, displacing the many existing, less ideal energy sources. This is because fusion, if done correctly, offers energy that is in equal parts clean, safe and affordable. I am convinced that fusion power plants will eventually replace most conventional power plants and related large-scale energy infrastructure that are still so dominant today. There will be no need for coal or gas.
Circa 2014
Scientists researching nuclear energy have made a breakthrough in nuclear fusion with an experiment that generated more fuel than was put in.
It was a moment three years in the making, based on intensive research and design work: On Sept. 5 for the first time, a large high-temperature superconducting electromagnet was ramped up to a field strength of 20 tesla, the most powerful magnetic field of its kind ever created on Earth. That successful demonstration helps resolve the greatest uncertainty in the quest to build the world’s first fusion power plant that can produce more power than it consumes, according to the project’s leaders at MIT and startup company Commonwealth Fusion Systems (CFS).
That advance paves the way, they say, for the long-sought creation of practical, inexpensive, carbon-free power plants that could make a major contribution to limiting the effects of global climate change.
“Fusion in a lot of ways is the ultimate clean energy source,” says Maria Zuber, MIT’s vice president for research and E. A. Griswold Professor of Geophysics. “The amount of power that is available is really game-changing.” The fuel used to create fusion energy comes from water, and “the Earth is full of water—it’s a nearly unlimited resource. We just have to figure out how to utilize it.”
Fusion reactors will use abundant sources of fuel, will not leak radiation above normal background levels, and will produce less radioactive waste than current fission reactors. Learn about this promising power source.
The chernobyl special industrial zone — ecosystem restoration, remediation, and the development of energy and chemical byproducts — mykola tolmachov, chernobyl-51 industrial cluster.
The Chernobyl disaster / nuclear accident, occurred on April 26th, 1,986 at the No. 4 reactor in the Chernobyl Nuclear Power Plant, near the city of Pripyat in the north of Ukraine.
The initial emergency response, together with later decontamination of the environment, ultimately involved more than 500,000 personnel and cost an estimated US$68 billion, adjusted for inflation.
The current Chernobyl Exclusion Zone covers an area of approximately 2,600 km2 (1,000 sq mi) in Ukraine, immediately surrounding the Chernobyl Nuclear Power Plant, where radioactive contamination is highest and public access and inhabitation are restricted.
The Exclusion Zone’s purpose is to restrict access to hazardous areas, reduce the further spread of radiological contamination, and conduct radiological and ecological monitoring activities.
Today, the Exclusion Zone is still one of the most radioactively contaminated areas in the world and draws significant scientific interest for the high levels of radiation exposure in the environment, as well as increasing interest from tourists.
Despite the extremely high radioactivity of the region, the zone has become a thriving sanctuary with natural flora and fauna with some of the highest biodiversity and thickest forests in all of Ukraine.
On this episode of our show, we are joined by Mykola Tolmachov, of the Chernobyl-51 Industrial Cluster, discussing their novel public-private partnership for both ecosystem restoration and the production of both energy and chemical byproducts, in the exclusion zone.
NuScale Power, the startup specializing in the design of small modular nuclear reactors, has published new data concerning the production capacities of its NuScale Power Module (NPM). Thanks to the 25% increase in power output of an NPM, each NuScale module is now capable of producing 2,053 kg/hour of hydrogen, or nearly 50 metric tons per day.
Just one NuScale Power Module can produce 77 MWe of carbon-free electricity to power 60,000 homes in the U.S. NuScale’s flagship power plant design can house up to 12 modules for a total gross output of 924 MWe. The 924 MWe that a 12-module NuScale plant produces is enough to power nearly 700,000 homes with clean, reliable energy.
“The ability of our NPM to now produce even more clean hydrogen, in a smaller footprint, is yet another example of how NuScale’s technology can help decarbonize various sectors of the economy while providing additional revenue streams for customers,” said Dr. José Reyes, Chief Technology Officer and Co-founder of NuScale Power. “Coupled with our proven design, unparalleled safety, and load-following capabilities, this analysis further demonstrates that NuScale’s design is the gold standard in helping meet the demand for innovative solutions to challenging global energy needs.”