Plasma Assisted Digestion(TM) – Digestion Stage, post plasma
2023 marks a huge milestone for The Thorium Network and our division the International Plasma Research InstituteTM, or IPRITM. We successfully serviced a number of clients and cracked their inert materials using Plasma Assisted DigestionTM or PADTM for short.
We did this at indicative costs and time much less than industry standards. Indeed, one client gave us material they are unable to recover anything from. We obtained almost 80% of the precious Rare Earths from the material. That’s case study 3 below.
Here are the summaries of three case studies from some of our work in 2023:
IPRI PAD(TM) Cracking Case Study 1IPRI PAD(TM) Cracking Case Study 2IPRI PAD(TM) Cracking Case Study 3
Why Plasma to make Rare Earths and Thorium
Our plasma team is the best in the world, covering the United Kingdom, the Middle East, Russia and USA.
Using a proprietary configuration of gases, geometry and plasma, at IPRITM we are able to change the structure of a mineral matrix such that we crack a normally locked, tight crystal mineral lattice, such as monazite or apatite. This makes them quite accessible using mild liquid separation technologies.
The benefit are:
Removal of Naturally Occurring Radioactive Materials (NORMS) early from the process. This makes at-mine pre-processing possible before sending off for concentration.
Selective separation of element species using different wet conditions by adjusting temperature, pH and time.
Separation of low value rare earths, such as cerium, from high value rare earths in minutes.
We are excited by the potential to apply PADTM to other inert mineral structures to explore their viability also.
Here are some research papers from Necsa on Plasma technology that prove the technology.
Typical separation of rare earth elements is a capital intensive and expensive operation. With our partners we have PertraXTM. At a fraction of the cost of tradition solvent extraction technologies PertraXTM is able to safely separate rare earths with the smallest of environmental footprints with only a fraction of the hardware and consumables traditionally used. It’s a revolution in rare earth production.
PertraXTM is also part of our activities at IPRITM.
During 2023, the esteemed and highly experienced scientist Dr. Necdet Aslan joined us at IPRI.tech. Dr. Aslan is Türkiye’s expert in plasma physics and technology and professor at Yeditepe University, Istanbul, Türkiye.
As we move into the future we are excited by the prospects we have to expand our activities. Reach out to us here if you would like to join our illustrious team.
About The Thorium Network
Our objective at The Thorium Network is to Accelerate the Worldwide Adoption of Liquid Fission Thorium Energy. We do that through three main activities:
1) We strive for easy access to Thorium as a fission fuel and focus on Liquid Fission – its technical superiority is unrivalled. The track and trace of nuclear fuels provides a solution for countries to go nuclear faster. Less headaches. This is done in full compliance with international guidelines and country regulations;
2) Raising public awareness to the benefits of Fission. As well as being an innovator of supply chain logistics we are also a public relations group as as advocate Fission Energy;
3) Driving licensing and installation of Fission machines across the world, using our network and access within the industry. For this we include all advanced fission technology, as well of course, Liquid Fission Thorium Burners (LFTBs).
No other technology produces energy as cheaply, safely and continuously on a large scale as nuclear power. No other energy source can match nuclear power’s low environmental impact, partly because its energy density is a million times greater than that of fossil fuels – and more so for wind or solar.
As of 2016, the world’s 400 + nuclear reactors created about 15% of our electricity. France, alarmed by the cost of petro-fuels, went to 70% nuclear in just 16 years, and Finland, now at 30%, is aiming for 60%. Sweden is adding 10.
Nuclear France emits about 40 grams of CO2/kWh, but Germany, the US, Japan and most industrialised nations emit 400 – 500 grams per kiloWatt hour – ten times more per kWh than heavily nuclear France. Compared to fossil fuel-reliant wind and solar farms, nuclear power is a gift from the energy gods.
Nuclear power, being CO2-free, is by far the most effective displacer of greenhouse gases, so how can my fellow “greens,” oppose nuclear power when the environmental costs of burning carbon-based fuels are so high?
Dr. James Lovelock, a patriarch of the environmental movement, has begged people to support nuclear energy: “Civilization is in imminent danger and has to use nuclear power, the one safe, available, energy source now or suffer the pain soon to be inflicted by an outraged planet.”
“In the core of just one reactor, the power density is about 338 million watts per square meter. To equal that with wind energy, which has a power density of 1 watt per square meter, you’d need about 772 square miles of wind turbines….
“Some opponents still claim that nuclear energy is too dangerous. Debunking that argument requires only a close look at the facts about Fukushima….
“Here’s the reality: The tsunami caused two deaths – two workers who drowned at the plant.
“It was feared that radiation from the plant would contaminate large areas of Japan and even reach the U.S. That didn’t happen. In 2013, the World Health Organization concluded: ‘Outside of the geographical areas most affected by radiation, even within Fukushima prefecture, the predicted risks remain low and no observable increases in cancer above natural variation in baseline rates are anticipated.
“High on my list of well intentioned dupes are those who praise science and are eager to confront Climate Change but refuse to accept nuclear power as an essential part of carbon-reduction strategies. They dismiss new reactor designs that they don’t understand, and then talk about how wind and solar power can ‘supply our needs.’
“They are wrong, but nuclear can supply our needs when people conquer their fears, educate themselves on the safety of nuclear power – and constructively join the fray. Until they do, they must accept their culpability in creating an overheated planet with millions of climate refugees.”
Only at the “illegal” plant at Chernobyl, which was designed to also make plutonium for bombs, with electricity being a by-product, has anyone died from radiation from nuclear power, but we’ve had tens of millions of coal, gas and petroleum-related, early deaths. Furthermore, our reactors, by generating electricity from the 20,000 Russian warheads we purchased in the Megatons to Megawatts program, have become the ultimate in weapons-reduction techniques.
What about 3-Mile Island, Chernobyl and Fukushima? We’ll examine each of them, but it is important to remember that nuclear plants have been supplying 15% of the world’s electricity, while creating no CO2, for 16,000 reactor-years of almost accident-free operation. And the reactors that have powered our nuclear Navy for more than 50 years have similar safety records. (Naval reactor fuel can be up to 90% U-235.)
In March, 1979, two weeks after the release of the popular movie, The China Syndrome, a partial meltdown of a reactor core due to a stuck coolant valve and design flaws that confused the operators, caused mildly radioactive gases to accumulate inside one of the reactor buildings.
After the gases were treated with charcoal, they were vented, and a small amount of contaminated water was released into the Susquehanna River. No one died or was harmed.
However, when an AP reporter described a “bubble” of hydrogen inside the reactor building in a way that led people to think that the plant was a “hydrogen bomb,” many residents fled, which caused more harm than the accident.
In fact, radiation exposure from Three Mile Island was far less than the amount of radiation that pilots and airline passengers receive during a round-trip flight between New York and Los Angeles [1 mrem, or 1 microSivert – 100 times less than average yearly background exposure in the area around Three Mile Island]. Furthermore, in the following decades, more than a dozen studies have found no short or long-term ill effects for anyone, whether they were downwind or downstream from the plant or at it – and since then, operator training and safety measures have greatly improved.
President Carter—who had specialized in nuclear power while in the United States Navy—told his cabinet after visiting the plant that the [Three Mile Island] accident was minor, but reportedly declined to do so in public in order to avoid offending Democrats who opposed nuclear power.
Over the years, many people have asked me how I run the Naval Reactors Program [55 years safe operation], so that they might find some benefit for their own work. I am always chagrined at the tendency of people to expect that I have a simple, easy gimmick that makes my program function. Any successful program functions as an integrated whole of many factors. Trying to select one aspect as the key one will not work. Each element depends on all the others.
Despite all of the fear and panic, nothing happened. No one died, and no one got cancer, but the media-hyped event at Three Mile Island came very close to shutting down all progress in American nuclear power. Because of the radiophobia generated by our sensation-seeking press and fervent greens, neither of whom bothered to check the facts, many proposed reactors were replaced by coal plants, and in the following decades, pollution from those plants brought premature death to at least 500,000 Americans.
In 1986, during a test ordered by Moscow that involved disabling the safety systems, a portion of the core of the reactor, which had design hazards not present in Western reactors, was inadvertently exposed. (The RKMB reactor at Chernobyl was long judged to be dangerous by scientists outside of the Soviet Union.)
As Dr. Spencer Weart wrote in The Rise of Nuclear Fear, “In short, for Soviet reactor designers, safety was less important than building ‘civilian’ reactors that could produce military plutonium if desired, and building them cheaply.”
This negligence led to a steam/hydrogen explosion that released radioactive gases into the atmosphere because the reactor had no effective containment structure. In contrast, no U.S. reactor contains flammables. Each has a reinforced concrete containment structure that can survive an airliner hit, and every plant is strictly regulated by the NRC.
There has never been a source of energy as safe or kind to the environment as nuclear power, and the reason for the safety is regulation.
Every responsible nation similarly regulates its nuclear power plants and shares information and training practices via international agencies. This cooperation, which was expanded after Three Mile Island, resulted in so many improvements that civilian nuclear power climbed from 60% up-time in the sixties to at least 90% today.
For three days, Soviet authorities hid the [Chernobyl] disaster and delayed evacuating the area, coming clean when radiation readings across Europe began to rise. (The government also failed to distribute iodine tablets, which could have protected thousands from airborne Iodine-131, which is readily absorbed by the thyroid, particularly in the young. (A body with an abundance of benign I-127 is less likely to absorb I-131.)
Chernobyl failed due to bad design, Moscow’s interference, poor training and a system that forbade operators from sharing essential information about reactor problems. It is the only “civilian” reactor accident where radiation directly killed anyone. Initially, approximately eighteen firefighters died from intense radiation. Yet, with design changes and proper procedures, several similar reactors still operate in the former Soviet Union.
Metsamor, a nuclear power plant in Armenia, (former USSR), also has no containment structure. The European Union has urged Armenia to close down the site for years, and offered $289 million to finance shutting down the plant…
(A round trip flight for the U. S. to Chernobyl will expose travellers to twice as much additional background radiation as their 2-day tour in the exclusion zone, which even includes a tour of the damaged plant).
Furthermore, the deformed and brain-damaged “Chernobyl children” that sensation-seeking TV programs occasionally feature are no different from similarly afflicted children elsewhere in Europe who received no fallout, but that information is never provided by anti-nuclear activists and the media. (Since Chernobyl, cancer rates in the Ukraine have been about 2/3 of the rate in Australia.)
Because of the erroneous, dangerous LNT theory and many dire predictions from people like Helen Caldicott (coming up in future episodes), many thousands of badly frightened European women endured needless abortions because they had become convinced that they were carrying monster babies.
Tepco’s Fukushima reactors began operation in 1971 and ran safely for 40 years, generating huge amounts of electricity without creating any CO2 or air pollution, but then, in 2011, came a record-setting earthquake – Tōhoku.
However, the quake destroyed the plant’s connections to the electrical grid, which required emergency generators to power the systems that cooled the still-hot reactors.
Although three of Tepco’s six nuclear reactors were off-line when the quake struck, five were eventually doomed because: 1. In 1967, Tepco removed 25 meters from the site’s 35-meter seawall to ease bringing equipment ashore. 2. Tepco replaced the original seawall with only a six-meter seawall. 3. The Japanese government advised Tepco to raise it, but Tepco declined – and the government did nothing. 4. Tepco had inexplicably placed five of its six emergency generators in the basements. 5. The tsunami flooded all but #6. 6. Batteries powered the controls for about 8 hours, and then failed. Without coolant, meltdown was assured.
Reactors 1 – 4 are useless, and number 5 is damaged, but reactor 6 was unaffected because its back-up equipment was intelligently sited well above the tsunami’s reach. Reactor 6 is capable of producing power, but it has not been started, largely because of the anti-nuclear hysteria fanned by most of the Japanese press.
There were warnings: All along the coast, ancient “Sendai stones” have been warning residents to avoid building below 150 feet above sea level for centuries.
The Onagawa nuclear plant, which was closer to the epicenter of the quake, also survived the quake, and its 45-foot high seawall easily blocked the tsunami. The tsunami took more than 15,000 lives, but Fukushima’s seawall failure took the lives of just two workers who drowned.
Dr. Zbigniew Jaworowski, MD PhD, DSc, former Chairman of the United Nationals Scientific Committee on the Effects of Atomic Radiation (UNSCEAR): “What is really surprising, however, is that data collected by UNSCEAR and the Forum show 15% to 30% fewer cancer deaths among Chernobyl emergency workers and about 5% lower solid cancer incidences among the people on the Bryansk district (the most contaminated in Russia) in comparison with the general population. In most irradiated group of these people (mean dose of 40 mSv) the deficit of cancer incidence was 17%.”
Because of their daily exposure to low levels of radiation, which seems to stimulate the DNA repair system, nuclear power plant workers get one third fewer cancers than other workers. They also lose fewer workdays to accidents than office workers.
Knowing this, it is not surprising that, when steel containing cobalt-60 was used to build Taiwan apartments, which exposed 8,000 people to an additional 400 mSv of radiation during some twenty years, cancer incidence was sharply down, not up 30% as Linear No Threshold Theory would have predicted.Instead, the residents’ adaptive response to low- level radiation seems to have provided health benefits. The following chart reveals lower cancer rates for those who receive extra low-level radiation vs. those who only get background radiation.
In 2015, a study of bacteria grown at a dose rate 1/400 of normal background radiation yielded a reduction in growth, but when the cells were returned to normal background radiation levels, growth rates recovered. The conclusion: Insufficient radiation can yield harmful results.
Therefore, it seems reasonable that radiation limits should be the same regardless of the source of the radiation. Nevertheless, nuclear plants are held to a standard 100 times higher than coal plants, which actually emit moreradiation than nuclear power plants. Per unit of electricity created, the fly ash emitted by a coal power plant exposes the environment to 100 times more radiation than a nuclear plant’s on-site-stored spent fuel – it’s so-called “waste”, 90% of which can be consumed in modern reactors. (Granite buildings irradiate their occupants more than nuclear power plants.)
“Workers employed in fifteen utilities that generate nuclear power in the U. S. have been followed for up to 18 years between 1979 and 1997.
“Their cumulative dose from whole body radiation has been determined from records maintained by the facilities and by the Nuclear Regulatory Comm. and the Energy Department.
“Mortality in the cohort … has been analyzed with respect to individual radiation doses. The cohort displays a very substantial healthy worker effect, i.e. considerably lower cancer and non-cancer mortality than the general population.”
In Radiation and Health, Hendrickson and Maillie wrote “…during radiation therapy for cancer, we’ve learned that chromosome damage to lymphocytes can be reduced by up to 50% if a small dose is given to the cells a few hours before the larger ‘cancer-killing’ dose is administered.”
In the southwest Indian state of Kerala, children under five have the lowest mortality rate in the country, and life expectancy is 74 despite background radiation rates that can range as high as 30 times the global average.
For thousands of years, Keralites have lived with radiation three times the level that caused the evacuation at Fukushima, where the limit was, on July, 2016, just 20 mSv. In contrast, some sections of Kerala experience 70 mSv, with a few areas measuring 500 – and many Keralites also eat food that is five times as radioactive as food in the United States.
Kerala Beach People Live Longer
Despite these radiation levels, cancer incidence in Kerala is the same as the rate in greater India, which is about 1/2 that of Japan’s and less than a third of the rate in Australia. As the linked article says, “Cancer experts know a great deal about the drivers of these huge differences, and radiation isn’t on the list.”
Kerala Beach
In Kerala, scientists have been working with a genuinely low rate of radiation exposure that mirrors what would have been the case in Fukushima if the Japanese officials hadn’t panicked and needlessly evacuated so many thousands of people.
So, why did they? Partly from fear, but primarily because most radiation protection standards have been derived from LNT bias and studies of Japanese atomic bomb victims who received their dose in a very short time, and being bombed is very different from living for years with a slightly higher radiation level.
Kerala also confirms our modern knowledge of DNA repair- namely that radiation damage is not cumulative at background dose rates up to 30 times normal, and that 70 mSv over a lifetime does nothing. In fact, the concepts of an “annual dose” or a “cumulative dose” are misleading. Instead, evidence reveals that an annual exposure to 100 mSv is comparable to a dose of zero because it doesn’t exceed a person’s capacity for repair.
In the past, when experts discussed these issues they couldn’t consider delivery rates or DNA repair because the power and mechanisms of DNA repair were not known until long after Muller’s LNT theory became dogma. As a consequence, the suffering caused by this obsolete “science” has been immense. (UK radiation expert Malcolm Grimston has characterised the Fukushima evacuation as being “stark raving mad”).
When the Japanese government lifted the evacuation orders because the radiation level had dropped to 20 mSv, 80 % of the residents refused to return because of their fear of radiation despite the fact that the most highly irradiated areas near the plant received only 1/5 of the lowest dose linked to a detectable increase in cancer. (At Guarapari beach in Brazil, residents often bury themselves in sand that yields 340 mSv without ill effect.)
Guarapari Beaches, Brazil
We should be concerned about genuinely dangerous isotopes, but we shouldn’t waste energy and money cleaning up minor radioactivity that doesn’t do anything – but that is what we are doing.
Despite our learning that our cells have amazing repair abilities, LNT advocates still create the radiophobia that caused the extreme evacuations at Fukushima and the flood of needless, fear-induced European abortions that followed Chernobyl. In my opinion, people who refuse to examine the evidence that negates this discredited illusion have abandoned their integrity.
October, 2020. New U.S. Department of Energy research indicates that at low doses, biological reactions are often unrelated to those that occur at high levels. The influential Linear-No-Threshold model, which predicted that acute exposure damage can be extrapolated linearly to low dose exposures—was flawed. In fact, small amounts can have an adaptive positive effect. In addition, it appears that cells communicate with each other and a dose to one affects the cells around it.
