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SpareBank 1 Nord-Norge ( OTCMKTS:SPXXF – Get Free Report ) was the target of a large increase in short interest in December. As of December 15th, there was short interest totalling 400 shares, an increase of 100.0% from the November 30th total of 200 shares. Based on an average daily volume of 0 shares, the short-interest ratio is presently ∞ days. SpareBank 1 Nord-Norge Price Performance Shares of SPXXF stock opened at $7.78 on Friday. SpareBank 1 Nord-Norge has a 12 month low of $7.78 and a 12 month high of $7.78. The business’s 50-day moving average price is $7.78 and its 200-day moving average price is $8.17. SpareBank 1 Nord-Norge Company Profile ( Get Free Report ) Featured Articles Receive News & Ratings for SpareBank 1 Nord-Norge Daily - Enter your email address below to receive a concise daily summary of the latest news and analysts' ratings for SpareBank 1 Nord-Norge and related companies with MarketBeat.com's FREE daily email newsletter .
If you're looking for a billionaire, you might as well be looking for a , trust fund, 6'5", blue eyes. Well, not exactly, but the typical member of the three-comma club isn't that different from the stereotype. The typical billionaire is a man in his 60s, who lives in New York City, loves sports, and works in banking or finance, according to , which looked at the world's richest citizens as of 2023. Most of his wealth is probably tied up in public companies, though he also has a penchant for private jets, , and valuable cars. He is also, unlike the man in the TikTok jingle, self-made. There are more billionaires than ever in the world, a total of 3,323. Their cumulative net worth is $12.1 trillion, up 9% from last year thanks to a stock-market rebound. The United States is home to nearly one third of them, the largest concentration of any country. New York City alone has 144 billionaire inhabitants — more than any country besides the US, , and Germany. Most — 87% — of billionaires are male, and have amassed their fortunes in different ways than the world's 431 female billionaires. While the majority of all billionaires, about 60%, are fully self-made, men are more likely to be than . In fact, 76% of the world's female billionaires have inherited at least part of their wealth, compared to 35% of male ones. Male billionaires are more likely to have public assets make up the largest share, or about 40%, of their wealth. Male tech billionaires whose fortunes are tied up in the companies they control or founded — like Elon Musk and — skewed that number, according to the report. Meanwhile, liquid assets, like cash and private holdings, are the largest asset classes for women. Both are more typically tied to , Altrata found. The largest share of all billionaires, about 22%, work in finance or banking, but the largest portion, about 17%, of female billionaires spend most of their professional time in the nonprofit sector. The interests of male and female billionaires follow suit: 71% of women billionaires count philanthropy as a top interest, while sports was the most popular one for male billionaires. Among all billionaires, the top philanthropic cause was education, which includes gifts to alma maters — an especially popular form of giving in the US. Billionaires are also more likely to splurge on different high-value items depending on their gender. Men prefer luxury vehicles — jets, yachts, cars — while women prefer property and art. In fact, male billionaires are almost four times as likely to own a worth more than $1 million than their female counterparts. So, if you are looking for a man or woman, finance isn't a bad place to start. Failing that, why not try a gala or classic car show? We'll leave the choice of eye color up to you. Read the original article on
Where Are The US Air Force's A-10 Warthogs Based?IDAHO FALLS – As nations explore ways to reduce carbon emissions, nuclear energy is increasingly recognized as a safe, reliable option for coping with the increase in electricity use. Further, tomorrow’s advanced nuclear reactors are smaller and more flexible than today’s reactor fleet, which allows them to integrate more renewables with the grid, provide heat for industry, and power remote applications, such as mines and data centers. Just as the world needs the next generation of nuclear reactors to meet climate goals, it needs new options for safely and securely storing radioactive materials. As of 2022, there were approximately 400,000 metric tons of spent fuel being stored globally, with roughly 90,000 tons in the U.S. alone. Nuclear experts say deep geological repositories are a necessary long-term solution for securely storing nuclear waste. While no commercial nuclear repositories currently exist, Finland plans to open the world’s first deep geological repository by the middle of this decade. Switzerland, Canada and France are licensing their own disposal facilities. The research team, led by David Chichester, developed TRIPWIRE to enable detecting radiation over large and inaccessible areas like nuclear material repositories. In the U.S., consolidated spent fuel storage facilities will bridge the gap between on-site storage and a national repository. Likewise, nations need to secure nuclear materials for arms control purposes, to meet treaty obligations and to prevent proliferation of nuclear materials in an increasingly volatile world. These nuclear storage scenarios will need reliable detection equipment to ensure public trust and the nonproliferation of nuclear materials. At Idaho National Laboratory, researchers developed TRIPWIRE to enable detecting radiation over large and inaccessible areas like nuclear material repositories. TRIPWIRE won a 2024 R&D 100 Award and provides governments and industry with an inexpensive, durable, one-of-a-kind option for monitoring radioactive materials. INL’s Laboratory Directed Research and Development program initially funded the work. TRIPWIRE has also received funding from the National Nuclear Security Administration. TRIPWIRE uses thin scintillating fibers to detect radiation. Made of plastic, big blocks of scintillating materials are sometimes used to detect radiation at above-ground locations like border crossings. “The radiation excites the molecules in the scintillating fibers” said David Chichester, a nuclear engineer and directorate fellow at INL. “When they de-excite, they will give off visible photons, there’s a sensor to detect that light.” With TRIPWIRE, the scintillating plastic is drawn out to fibers that are about 1 mm thin. At that thickness, the fibers exhibit a similar property to glass fiber optics called total internal reflection. Total internal reflection means the light will reflect down the length of the fiber until it reaches the end. “With these plastic scintillators, the maximum length that will transmit light effectively is something less than 50 meters,” Chichester said. “But we can couple the scintillating fiber to a glass fiber optic, then the sensor can be kilometers away.” That 50 meters — the length of an Olympic swimming pool — allows detection over a much greater length and orders of magnitude longer than current gamma radiation detectors, which are typically limited to just a few inches. The upshot of TRIPWIRE is that the technology eliminates the need to bury electronic equipment within the repository. Instead, the electronic equipment remains on the surface, where it is easy to repair or replace, if necessary. “Originally our sponsor was interested in detecting undeclared activities,” Chichester said. “Imagine a repository that is sealed, and a host nation attempts to get back into it. Having a real-time sensor underground with the spent fuel provides a strong deterrent against theft or diversion.” With underground facilities and tunnels, TRIPWIRE can spread out like a spiderweb and cover a three-dimensional area. TRIPWIRE’s optical fibers are low-cost and readily available, which makes the technology a good option to significantly reduce personnel exposure to potentially dangerous radiation and maintenance costs in long-term nuclear storage facilities. The scintillating fibers are sheathed in protective materials that resist abrasion, chemical degradation, and changes in temperature and humidity. The fibers can withstand being stepped on or struck by falling rocks, which is essential for long-term deployment in a sealed repository where the fibers may need to function unattended for decades — or even centuries. TRIPWIRE also has applications beyond repositories, including monitoring the natural background radiation along oil and gas pipelines, monitoring radiation at ports of entry for national security, and perimeter awareness for emergency response. Researchers have even considered using TRIPWIRE inside the gloves used for moving and examining radioactive materials as a radiation safety monitor. “TRIPWIRE is a versatile cost-effective technology for radiation monitoring, it has the potential for tremendous impact in several fields, and we look forward to its potential deployment in the coming years,” Chichester said. To remove this article -
Sandfire Resources America Inc. (OTCMKTS:SRAFF) Sees Large Decline in Short Interest
