Tag: partnership

Article Retrieved from: Argus Metals

Article Retrieved from: Argus Metals

An agreement has been made to deploy energy storage systems using the novel chemistry batteries between manufacturer Ambri and TerraScale, a developer of sustainable infrastructure solutions for the energy and digital technology sectors.

Co-founded by MIT materials chemistry professor Donald Sadoway and part-funded to get off the ground by Bill Gates, Ambri has designed a battery that uses a liquid calcium alloy anode, molten salt electrolyte and a cathode made of solid particles of antimony. The company claims this enables a low number of steps in the cell assembly process while the materials are low-cost. Ambri also integrates the batteries into a containerised energy storage system solution.

TerraScale meanwhile is developing a project called Energos Reno. A 3,700 acre development near the city of Fernley in the Reno-Sparks metropolitan area, the site will include a microgrid with more than 500MW of renewable energy capacity powering a data centre that TerraScale anticipates will be used by government and commercial clients.

Renewable resources that Energos Reno can call on will be solar and geothermal: there is already 10MW of solar generation built at the site, which TerraScale intends to bring up to 500MW and 23MW of active geothermal power with a rated capacity of 48MW. While the first phase of the project is the buildout of roadways and utilities to enable the sustainable data centre to be sited there, TerraScale said in a press release that it hopes the data centre and its microgrid will be built and completed within 10 years.

“Our data centre technology partners are looking forward to deploying Ambri’s antimony technology to enable high-volume, reliable, and resilient energy storage with potentially the lowest levelised cost of storage in the industry,” TerraScale CEO Danny Hayes said.

“The collaboration is underway and includes delivery of 250MWh of Ambri systems to TerraScale’s first project in Reno, Nevada starting in 2021. The Ambri systems are particularly well suited for the project’s high-desert operations, for the shifting of its large amounts of renewable solar load, and for its grid-system peak shaving capability,” Ambri chief commercial officer Adam Briggs said.

In racing to commercialise its novel battery technology, Ambri is among a handful of non-flow battery players that are beginning to realise a scale-up in deployments as rivals to lithium. These include Eos Energy Storage, which has recently brokered a couple of gigawatts in contracts with US developers for its zinc aqueous battery and 24M which has recently signed a deal for a Norwegian startup to manufacture its semi-solid electrode lithium batteries under license. Japanese equipment maker Kyocera has also signed up to use 24M’s potentially disruptive lithium battery technology in residential energy storage systems in the Japanese market.

24M was also started up by an MIT professor, Yet-Ming Chiang, who in turn has also involved been involved with Form Energy, which has recently emerged from stealth mode touting the potential of its aqueous air battery, claiming that it can store up to 150 hours of energy. Form Energy has also been backed by tech magnate Bill Gates, via the former Microsoft chief’s Breakthrough Energy Ventures fund.

Ambri meanwhile had been selected by the Massachusetts-headquartered energy storage system integrator arm of NEC as a potential technology solution for projects that required more than four hours’ duration of storage, with NEC Energy Solutions announcing a minimum purchase order of 200MWh of cells from Ambri in 2019. However despite a strong early leader position, NEC exited the energy storage industry earlier this year.

Ambri’s Donald Sadoway has said in the past few days via Twitterthat the company’s batteries can operate in the desert “without need for air conditioning or fire suppression,” claimed that there was “no question that liquid metal battery can undercut lithium-ion,” and that the technology “offers resistance to capacity fade and immunity to thermal runaway while constructed of ethically sourced materials. All at the lowest price point”.

Article Retrieved from: Energy Storage News

PUBLISHED MARCH 2, 2021

Perpetua Resources– Critical minerals like Antimony get a lot of attention. But why?

Minerals are a key part of our everyday lives. Without them we wouldn’t have iPhones, safe bridges to drive on, engines for our cars or a well-prepared military to keep us safe. However, the U.S. depends on foreign countries for half of the key minerals we use and our reliance on foreign nations for mineral resources has doubled in the last twenty years. This isn’t because the minerals do not exist in our country but because we aren’t currently tapping into some of the resources available to us.  

In 2017, the Department of the Interior declared 35 minerals vital to U.S. interests based on our economic and national security needs. The list includes minerals that are key components of electronics, military equipment and weapons, transportation devices, energy generation and many other industries that help power and protect our great nation. As the COVID-19 pandemic has demonstrated, our dependence on foreign nations to access these minerals and other important technologies leaves our country vulnerable.  

As recognized by multiple Presidential administrations and across political parties, our country’s economic growth, safety and way of life is dependent on our ability to access the minerals and metals that build satellites, missile defense systems, roads and bridges, computers, batteries and other technology. Yet, our dependance on other countries for materials and goods is creating vulnerability.   

The critical mineral antimony is one of the metals Perpetua Resources will produce if the Stibnite Gold Project moves forward, is included on the list of 35 Critical Minerals because it is essential to the energy, technology, and defense industries. Right now, the U.S. gets most of this mineral from China and Russia – which controls more than 80 percent of the world’s antimony production. Recent headlines regarding China’s desire to limit exports of rare earth minerals as well as the associated technology demonstrates that our dependency on China for critical minerals leaves the U.S. vulnerable.  Today, there is not an active antimony mine in America. The Stibnite Gold Project would be the only domestic source of mined antimony and the Project can help us take back control over one key part of our mineral future. 

WHY ANTIMONY? 

Our current way of life is dependent upon antimony. From wind and hydro turbines to semiconductors and cellphones, Antimony is a key component of the technology that powers our nation, that keeps us entertained and, on the move, as well as the technology that keeps our country safe.  

Designated as one of the 35 critical minerals antimony is a very important mineral. It strengthens alloys and makes them resistant to corrosion and is a key ingredient in flame retardants. These properties make it a highly valuable mineral for our military and energy sectors, as well as preventing our homes and belongings from being fire hazards. In fact, Antimony has always been an important mineral for national defense. During World War II, young men could complete their military service up at Stibnite because antimony was critical to winning the war.  

Antimony powers our nation: Solar panels, wind turbines, generators, motors, batteries, nuclear reactors and other energy sources that our nation depends upon contain antimony.  

Antimony keeps us entertained and on the go: Smartphones, computers, semi-conductors, cars and other high-tech devices and machines depend on antimony to operate efficiently.  

Antimony keeps our nation safe: Communication systems, night vision goggles, ammunition, tanks, infrared sensors, submarines, warships, camouflage, flame retardants and many other military technologies are dependent upon antimony to operate effectively. 

ANTIMONY FOR THE FUTURE GREEN GRID 

We are also excited about the future of antimony and its use in next generation technology; technology that will allow us to achieve a more sustainable and efficient future. Recent research has demonstrated antimony’s applicability in molten-salt batteries, solid-state batteries, semi-conductors, and even self-healing solar panels.  

Researchers at MIT have developed an antimony based liquid battery that will allow for the large-scale storage of renewable energy. The technology is currently being used at a Nevada data center and is in development as a tool for sustainable infrastructure development. This development will help renewable energy sources compete with traditional power plants and further increase the need for a domestic source of antimony.  

Researchers from Texas, Germany, and India have also created various solid-state batteries that use Magnesium-Antimony and Silver-Antimony-Telluride compounds to capture and convert what is known as waste heat into electricity. Waste heat refers to the excess energy generated by power plants and other machines or processes that is not converted into usable energy and is typically released as heat. This new development will help reduce the amount of wasted energy and further support a more sustainable future. 

Some experts have even theorized that antimony will replace silicon as the key semi-conductor for microchips. This is so, because 2D antimony is incredibly thin but also maintains a high charge mobility. Meaning, that the speed at which the charge moves through the antimony is very high. In fact, Antimony’s charge mobility is higher than that of silicon and thus will allow for microchips and next generation processors to become ever smaller.  

Today, antimony plays a role in solar panels for its transparent, infrared insulating and electrical conduction properties.  New research from the University of York has also demonstrated how antimony selenide may become a key component in solar panels. This compound is known as a solar absorbing material which means it can be used to turn light into electricity. What is unique about this semi-conducting compound is that it can self-heal. Keith Mckenna who helped discover this characteristic, compared antimony-selenide’s self-healing capability to a salamander’s ability to regenerate severed limbs. This self-healing characteristic is incredibly unusual and will likely allow the antimony-selenide compound to find widespread application in electronics, solar panels and other photovoltaics, as well as lighting and display systems.  

Antimony’s future uses are ever evolving, and their implications for our future are exciting. What is the most notable, is that the critical mineral antimony will play a key role in achieving a more sustainable future powered by renewable energy and that the lack of a domestic supply of antimony threatens both our economic and national securities.  

2021 UPDATE ON ANTIMONY: ANTIMONY REMAINS CRITICAL 

President Joe Biden issued an Executive Order on February 24, 2021 to further study our reliance on foreign nations and the need for a more resilient supply chain. We are excited by the news because, like the President, we know access to critical minerals is key to a secure and sustainable future for all of us. The Administration will evaluate supply chain risks in four specific areas – semiconductor manufacturing, high-capacity batteries, critical minerals, and pharmaceuticals.  

We fully anticipate this review will place a national focus on critical minerals, and antimony is a key mineral used in essential technology like semiconductors and large-scale battery storage. Currently, we are in the process of permitting America’s only mined source of this mineral. 

The Stibnite Gold Project could supply approximately 30 percent of the American demand for antimony in the first six years of production. Today, we are reliant on China and Russia to meet our antimony demands.  

Article Retrieved from: Perpetua Resources

The substance, called antimony selenide (Sb2Se3), is a solar absorber material that can be used for turning light energy into electricity.

Professor Keith McKenna from the Department of Physics said: “The process by which this semi-conducting material self-heals is rather like how a salamander is able to re-grow limbs when one is severed. Antimony selenide repairs broken bonds created when it is cleaved by forming new ones.

“This ability is as unusual in the materials world as it is in the animal kingdom and has important implications for applications of these materials in optoelectronics and photochemistry.”

The paper discusses how broken bonds in many other semiconducting materials usually results in poor performance. Researchers cite as an example, another semiconductor called CdTe that has to be chemically treated to fix the problem.

Professor McKenna added: “We discovered that antimony selenide and the closely related material, antimony sulphide, are able to readily heal broken bonds at surfaces through structural reconstructions, thereby eliminating the problematic electronic states.

“Covalently-bonded semiconductors like antimony selenide find widespread applications in electronics, photochemistry, photovoltaics and optoelectronics for example solar panels and component for lighting and displays.

Article Retrieved from: Science Daily

Antimony production at Hunan Chenzhou Mining, one of the largest producers in China, fell in 2020 because of a shortage of feedstock supplies.

The company produced 29,000t of antimony products last year, down by 17.96pc from a year earlier. It was hit by a shortage of ore supplies following lower shipments from major supply countries during the global Covid-19 pandemic.

It also produced 33.8t of gold and 2,181t of tungsten products in 2020, compared with 38.5t and 4,305t a year earlier. Chenzhou Mining produced 35,347t of antimony products in 2019, up by 11pc from 2018, including 10,620t of antimony metal, 2,404t of ethylene glycol antimony and 22,105t of other antimony products. Detailed output data for 2020 are unavailable. The company produced 1,913t of tungsten concentrate and 2,392t of ammonium paratungstate (APT) in 2019.

Fellow major antimony producer Hsikwangshan Twinkling Star plans to maintain production levels at 30,000 t/yr for antimony products and 3-5t/yr for gold in the coming five years.

Antimony resources have been falling in China after many years of overexploitation, with ore grades in main deposits owned by Chenzhou Mining and Hsikwangshan Twinkling Star decreasing significantly in recent years. This has added to mining costs for antimony concentrate and reduced production, as well as increasing China’s reliance on imported ores from countries including Russia, Tajikistan, Australia and Myanmar (Burma).

Ore shortages have sent antimony prices to a 21-month high at 44,000-45,000 yuan/t. There is further upside potential ahead of the 11-17 February lunar new year holiday amid renewed stockpiling interest from domestic downstream industries and seaborne purchasers.