Vanadiumcorp Resource Inc V.VRB

Alternate Symbol(s): VRBFD

Metals & Mining Industrial Metals & Minerals

VanadiumCorp Resource Inc. is a Canada-based critical metals company. The Company is engaged in the acquisition and exploration of mineral properties in Canada, with a primary focus on the exploration of the Lac Dore and Iron-T Properties in Quebec. The Company produces a stream of quality vanadium electrolytes for Vanadium Redox Flow Batteries (VRFB). The Iron-T Property is located in the Nord-du-Quebec administrative region in the Province of Quebec, approximately 15 kilometers (km) east of Matagami and 780 km northwest of Montreal. The Lac Dore Property is located approximately 27 km east-southeast from the City of Chibougamau, in Eeyou Istchee James Bay Territory, Nord-du-Quebec administrative region, Province of Quebec, Canada. The Lac Dore Project comprises two claim blocks, referred to as Lac Dore Main and Lac Dore North. The Lac Dore Main claims cover an area of 648.82 hectares (Ha), and the Lac Dore North claims cover an area of 4,637.87 Ha.

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Vanadiumcorp Resource Inc

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Post by ivanhoe2on Mar 24, 2014 12:51pm

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Post# 22359565

Very interesting use of Vanadium....

New magnetic material could boost electronics

By James MorganScience reporter, BBC News, Denver

Computer hard drives are just one possible application of the new material

A highly sensitive magnetic material that could transform computer hard drives and energy storage devices has been discovered.

The metal bilayer needs only a small shift in temperature to dramatically alter its magnetism - a tremendously useful property in electronic engineering.

"No other material known to man can do this. It's a huge effect. And we can engineer it," said Ivan Schuller, of the University of California, San Diego.

He presented his findings at the American Physical Society meeting in Denver.

The material combines thin layers of nickel and vanadium oxide, creating a structure that is surprisingly responsive to heat.

"We can control the magnetism in just a narrow range of temperature - without applying a magnetic field. And in principle we could also control it with voltage or current," said Prof Schuller.

"At low temperatures, the oxide is an insulator. At high temperatures it's a metal. And in between it becomes this strange material," he said.

Although it's too early to say exactly how it will be used, Prof Schuller sees an obvious opportunity in computing memory systems.

"A problem with magnetic memory is reversibility - you want it to be reversible but also stable.

"Today's best systems are heat-assisted, but they use lasers, which involves a lot of heat. But with this new material, you barely need to heat it by 20 degrees (Kelvin) to get a five-fold change in coercivity (magnetic resistance)," he told the conference.

Another potential use is in electricity networks. Prof Schuller envisions a new type of transformer which can cope with sudden surges in current - such as during a lightning strike or a power surge.

But he points out that new phenomena such as this often lead to entirely unexpected technologies.

He gave the example of giant magnetoresistance - a discovery that radically miniaturised hard drives in digital devices, and won the 2007 Nobel prize.

"Without it, that computer you're writing on would not work," he told the meeting.

"So if you want to find the next transformative technology, this is the type of research you do. We don't know what the best application is yet," he said.

"I'm not saying it's going to solve world's energy crisis but it's certainly going to help us."

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