EV charging technology and circular battery life jumpstart the EV revolution

Electric vehicles are gaining popularity, but face barriers to adoption. See how two companies are innovating EV charging technology and battery recycling.

“Within a year, I hope, we shall begin the manufacture of an electric automobile.” That was Henry Ford talking to the New York Times in 1914. The Ford Motor Company had introduced the gas-powered Model T in 1908. But a friendship with Thomas Edison led to Ford’s next big plans: popularizing electric vehicles (EVs), which had been puttering around since the 19th century. Even Ford’s wife, Clara, preferred to drive Ford’s Detroit Electric. But the idea didn’t catch on, and Ford ran into the same problem modern car manufacturers have: to design a battery that would “operate for long distances without recharging.” After more than a century since Ford’s attempt, electric vehicles are finally having their moment, and thanks to energy and materials advances, this time, it’s for good.

The world has reached a critical moment in terms of human impacts on the climate, and 28% of all greenhouse gas emissions come from transportation. In fact, the average car contributes 4.6 metric tons of CO2 to the atmosphere every year. The environmental consequences have tipped the scales away from fossil fuels in favor of EVs. Automakers are producing them at a feverish pace, and the White House recently announced a mission to ensure that by 2030 50% of all vehicle sales are electric.

There are still some hurdles to clear before EVs are the predominant cars on the road. First, there is a deficit of widespread reliable charging stations, with 25 EVs for every public port in the US and a minimum charge time of about 20 minutes. Then there’s the tradeoff of leaving gas-powered vehicles for ones that run on lithium-ion batteries, which deplete the earth’s mineral resources using environmentally damaging mining practices. These obstacles are where forward-thinking entrepreneurs and innovators see opportunities to transform the automotive industry and accelerate the mass adoption of EVs once and for all.

Strengthening EV charging technology to attract buyers

According to the Pew Research Center, half of the car-buying population in the US is unlikely to purchase an electric vehicle. One reason? Not knowing where to charge up on the road. EV stations haven’t quite caught up with gas stations: There are 141,000 charging stations across the country compared to 168,000 gas stations (each with six to twelve pumps), reinforcing the reliance on gas-powered vehicles. But the federal government is investing in 500,000 EV chargers, along with a mandate that stations have 97% uptime—the percentage of time that a user can arrive at a station, plug in, and successfully charge their vehicle. But a recent study by UC Berkeley found that 27% of charging ports in the San Francisco Bay Area alone, a mecca for EVs, don’t function properly, if at all.

ChargerHelp! was created by Kameale Terry and Evette Ellis to pave the way for an electrified infrastructure. “We saw the manufacturing of charging stations, we saw the deployment of charging stations, we saw the installation of charging stations. There was a gaping hole for operations and maintenance after they were installed,” says Kianna Scott, senior vice president of Learning & Development at ChargerHelp!

The startup, which is part of the Autodesk Foundation’s Work and Prosperity portfolio, offers reliability as a service (RaaS) for charging locations. Station operators can contract with ChargerHelp! and have EVSE (electric vehicle supply equipment) reliability technicians come out to get the software running again using ChargerHelp!’s Empwr app on their mobile devices. In its first three years, ChargerHelp! has had 18,000 touch points with stations, giving them insight into what makes machines fail. “The data consistently says about 96% of the time it is a software issue,” Scott says. Those analytics “mitigate the time that the tech is in the field and thereby contribute to the uptime of 97%.”

“Within a year, I hope, we shall begin the manufacture of an electric automobile.” That was Henry Ford talking to the New York Times in 1914. The Ford Motor Company had introduced the gas-powered Model T in 1908. But a friendship with Thomas Edison led to Ford’s next big plans: popularizing electric vehicles (EVs), which had been puttering around since the 19th century. Even Ford’s wife, Clara, preferred to drive Ford’s Detroit Electric. But the idea didn’t catch on, and Ford ran into the same problem modern car manufacturers have: to design a battery that would “operate for long distances without recharging.” After more than a century since Ford’s attempt, electric vehicles are finally having their moment, and thanks to energy and materials advances, this time, it’s for good.

The world has reached a critical moment in terms of human impacts on the climate, and 28% of all greenhouse gas emissions come from transportation. In fact, the average car contributes 4.6 metric tons of CO2 to the atmosphere every year. The environmental consequences have tipped the scales away from fossil fuels in favor of EVs. Automakers are producing them at a feverish pace, and the White House recently announced a mission to ensure that by 2030 50% of all vehicle sales are electric.

There are still some hurdles to clear before EVs are the predominant cars on the road. First, there is a deficit of widespread reliable charging stations, with 25 EVs for every public port in the US and a minimum charge time of about 20 minutes. Then there’s the tradeoff of leaving gas-powered vehicles for ones that run on lithium-ion batteries, which deplete the earth’s mineral resources using environmentally damaging mining practices. These obstacles are where forward-thinking entrepreneurs and innovators see opportunities to transform the automotive industry and accelerate the mass adoption of EVs once and for all.

Strengthening EV charging technology to attract buyers

According to the Pew Research Center, half of the car-buying population in the US is unlikely to purchase an electric vehicle. One reason? Not knowing where to charge up on the road. EV stations haven’t quite caught up with gas stations: There are 141,000 charging stations across the country compared to 168,000 gas stations (each with six to twelve pumps), reinforcing the reliance on gas-powered vehicles. But the federal government is investing in 500,000 EV chargers, along with a mandate that stations have 97% uptime—the percentage of time that a user can arrive at a station, plug in, and successfully charge their vehicle. But a recent study by UC Berkeley found that 27% of charging ports in the San Francisco Bay Area alone, a mecca for EVs, don’t function properly, if at all.

ChargerHelp! was created by Kameale Terry and Evette Ellis to pave the way for an electrified infrastructure. “We saw the manufacturing of charging stations, we saw the deployment of charging stations, we saw the installation of charging stations. There was a gaping hole for operations and maintenance after they were installed,” says Kianna Scott, senior vice president of Learning & Development at ChargerHelp!

The startup, which is part of the Autodesk Foundation’s Work and Prosperity portfolio, offers reliability as a service (RaaS) for charging locations. Station operators can contract with ChargerHelp! and have EVSE (electric vehicle supply equipment) reliability technicians come out to get the software running again using ChargerHelp!’s Empwr app on their mobile devices. In its first three years, ChargerHelp! has had 18,000 touch points with stations, giving them insight into what makes machines fail. “The data consistently says about 96% of the time it is a software issue,” Scott says. Those analytics “mitigate the time that the tech is in the field and thereby contribute to the uptime of 97%.”

The company partners with workforce development agencies to reskill people often underrepresented in the technology sector. ChargerHelp! developed a groundbreaking curriculum that the Society of Automotive Engineers (SAE) has adopted as a training standard and is designed to get technicians in the field quickly. It is equipping people with the skills to support mass EV adoption, but also to benefit individuals with living-wage careers in this new, sustainable world.

“ChargerHelp! wants to continue to be a part of supporting the confidence that people need in mass EV adoption,” Scott says. “But we really take to heart that there are individuals in this space that we want to help learn, grow and upskill, and empower to be just as impactful in this climate correction.”

Driving sustainability in the automotive industry with circular battery technology

Like most positive moves forward, tradeoffs come with the electrification of the automotive industry. While EVs reduce greenhouse gas emissions, producing them requires a huge amount of critical resources. They require six times the amount of minerals than conventional cars to manufacture, and 300 new mines will be needed to meet the growing demand by 2035.

Lithium-ion batteries require lithium, nickel, cobalt, manganese, and graphite. When they reach the end of their lifecycle, 95% of them are discarded, taking all those valuable resources with them. In fact, more than 15 million tons of batteries will be disposed of by 2030, with metals valued at more than $18 billion. As the push for automotive electrification ramps up, these weak spots are where Nth Cycle saw an opportunity to create a circular use of resources and a better way to extract them.

“Nth Cycle differs from traditional battery recyclers in the market because of two things: our decentralized business model is about partnering to locate where the feedstock is, and the technology we use called ‘Electro-Extraction’ is modernizing how metals are refined,” says Colin Mahoney, Nth Cycle’s head of public relations. “This allows Nth Cycle to be upstream with miners, co-locating at their sites to ensure higher-purity products are sent to the market, decreasing the reliance of the environment to produce more and more. It also provides recyclers the most efficient way to refine metals at the end-of-life because we’re not shipping used materials across the globe to be smelted but created a solution for refining domestically and locally. In both instances, an enormous amount of GHG are saved through our modular asset, the Oyster.”

The Oyster targets, retrieves, and refines specific metals from feedstock, such as cell phones, magnets, and EV batteries. The core technology, designed with Autodesk Fusion 360, uses just electricity and water, and its refining emissions are 92% lower than traditional mining and 44% lower than current recycling methods. Not only does Nth Cycle have its own standalone production center in Fairfield, Ohio, but with a small (approximately 2,000 square-foot) physical footprint, the modular system can be easily installed in a battery manufacturing facility’s plant to extract and recycle metals in house.

“Our business model will be partnering with miners, scrap recyclers, and OEMS on their metal refining needs to ensure they have a sustainable solution in place,” Gammon says. “Our novel design features fast processing times, a small footprint, and a high recovery, focusing on minimal waste and self-generating consumables.” And, it keeps that $18 billion in minerals out of the landfill and in circulation indefinitely.

With its invention, Nth Cycle is the first company in the United States to produce MHP (mixed hydroxide precipitate), a nickel product that is a necessary ingredient for domestic EV batteries. Most MHP comes from overseas and has inconsistent purity levels, whereas Nth Cycles’ MHP has close to 90% nickel concentration.

Having a reliable, local source of MHP creates a stronger supply chain for the EV boom that’s coming. It’s also in the best interest for auto manufacturers. The Inflation Reduction Act of 2022 requires greater investment in domestic clean energy, and by 2029, auto manufacturers must obtain 100% of EV battery components from domestic sources. Nth Cycle’s technology will ensure that happens. “As more regulations come to fruition, and as the automotive industry finds a greater need to secure their metal supply, we only see a greater need for Nth Cycle to be part of their circular economy,” says Gammon.

The clean energy transition is finally taking hold in the automotive industry. And it's been a long time coming. Transportation is a key factor in achieving global sustainability goals and decarbonizing the environment. Companies like Nth Cycle and ChargerHelp! are paving the way to this electrified future—and building the workforce to secure it.