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Kezi Cheng, Tobias Egleand 1 more

June 24, 2021

7 Min Read
BigBattery Project Aims to Tackle E-waste Challenge
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Editor's Note: The Role Of Battery Recycling In The Circular Economy is a three-part series. Part 1 focuses on Key Technologies. Part 2 focuses on the Battery Supply Chain, Logistics and Profitability. Part 3 focuses on Challenges and the Role of Policy.

The current battery supply chain is shown in red in Figure 2. Low grade (e.g. 50%) material from mines is refined by a smelter to 97-99%, and further upgraded to battery specifications (99.9% or greater), before being sent to cathode manufacturers. As of 2019, upstream/mining (23%), midstream chemical refining (80%), cathode/anode production (66%), and downstream lithium ion battery cell production (73%) are all primarily located in China [10], with Europe slowly becoming the second largest Li-ion battery producer. In Europe, more than 1,000 GWh of cell manufacturing capacities have been announced as of March 2021. Elements such as nickel and cobalt are increasingly mined in the Democratic Republic of the Congo (DRC) by Chinese-owned companies, with forced child labor issues at many mines [11]. By 2030, cathodes made of NMC-811 and LFP will likely dominate production to increase nickel content in order to achieve high energy density and lower reliance on cobalt. Nonetheless, there is an anticipated 50% deficit for elements like cobalt in the next 5-10 years as low cobalt and cobalt-free cathodes are still under development.

The companies discussed in this article are shifting away from the traditional supply chain and working towards a more circular, diversified supply chain to decrease waste output, gain more price control, and avoid geopolitical negotiations. By collecting multiple materials that are inputs to batteries, recycling facilities can be set up like “the perfect mines,” with better unit economics and co-location of all the critical materials (see Figure 2 in green).

batterrecyclingfigure2.jpg

Figure 2. Incumbent battery production chain compared to the circular loop explored by companies in this article.
Note battery manufacturing, high-volume users, and aggregators

Recycling Logistics and Profitability

While all focused on the same challenge, the companies interviewed have adopted multiple different approaches to their business models and value proposition. Key considerations for profitability and scope include: rate and volume of take-back and adoption, transportation costs (shipping, handling, storage), safety requirements (shredding, separation, purification, need for inert conditions), value of waste output (disposal tipping fee) and recycled inputs (grade, purity), and location of buyers and sellers. For some companies (Nth Cycle), modularity allows for flexibility in location, low initial take-back volume, and customization to each customer’s feedstock. For others (American Battery Metals Corporation, Redwood Materials), centralization near battery producers or car manufacturers allows for large volume processing, ease of coordination, and onsite recycling.

Li-Cycle relies on a spoke and hub model, distributing the pre-processing into different collection points and centralizing the post-processing (see Figure 3). The spoke portion feeds in batteries and outputs black mass, and the hub portion feeds in black mass and outputs battery-grade materials. Compared to Li-ion batteries, black mass is easier to transport and safer due to fewer hazardous waste concerns. Li-Cycle has developed extensive IP around their spoke development to avoid dismantling, sorting, and discharging batteries. Instead, they shred under a neutralizing solution to absorb the energy generated in a safe manner. The current spokes located in Kingston, ON and Rochester, NY have 5,000 tons/yr capacity for an estimate of recycling demand of ~100,000-500,000/yr now (largely from manufacturing scrap), approaching 1-5 million tons in 2030. Note that based on Li-Cycle estimates, manufacturing scrap currently represents 29% of the battery waste stream, but is expected to increase to 68% by 2025, with auto OEMs also representing a high percentage (16 to 25%).

batteryrecyclingfigure3.jpg

Figure 3. Spoke and Hub model for discarded Li-ion batteries.

Li-Cycle will soon have a network of three spokes to feed the $175 million commercial hub at the Eastman Business Park (formerly housing Eastman Kodak, Xerox and Bausch & Lomb) in Rochester, with the plan to eventually hit economies of scale at one hub per continent. The locations of where spokes and hubs are built are related to where batteries are, EV penetration, and proximity to battery manufacturing to collect scrap. At their hubs, Li-Cycle utilizes hydrometallurgy to produce battery-grade lithium, nickel, and cobalt at >95% recovery rate. Li-Cycle has 12 formalized trade secrets in converting black mass into battery grade materials, with cobalt, nickel, and lithium all undergoing crystallization processes. In addition to the battery materials, significant revenue can also be obtained by building a fully circular loop of all key components. For example, Li-Cycle is also able to collect plastics for reuse or fuel production as well as copper and aluminum foils. These materials provide additional revenue streams which help the companies buffer themselves against changes in commodity pricing that impact the core cathode/battery materials.

American Battery Metals Corporation (ABMC) is currently exploring both mechanical-hydrometallurgical-based battery recycling and primary extraction of battery metals from virgin resources. This relies on the assumption that low-impact extraction methods for battery metals from virgin primary resources, in addition to recycling, will be necessary to meet demand at scale. ABMC is currently constructing a plant in Nevada with the ability to recycle 20,000 tons of batteries annually. Redwood Materials also operates in Nevada, close to Tesla’s Gigafactory and the expected high volume of end-of-life EVs from California.

Table 1. Comparison metrics for companies and organizations interviewed. Note hydro refers to hydrometallurgy and electro refers to Nth Cycle’s electrochemical extraction process.

table1batteryrecycling.jpg

Although recycling is crucial for sustainability, mining will continue to play a central role in providing minerals for Li-ion batteries as long as the rate of new batteries being manufactured and entering the  market is greater than the rate of batteries reaching end-of-life and leaving the field. This is expected to be the case for several more decades. As a result, new mines will need to be established, a lengthy procedure of exploration and discovery, excavations, resource estimation, feasibility studies, pilot plants, obtaining environmental permits, and construction of processing plants. This whole process can take over a decade. The Cauchari-Olaroz lithium brine, for example, began construction in 2010 and anticipates first production in 2022. To improve the pace and efficacy of natural resources exploration, KoBold Metals, founded in 2018, plans to apply statistical modeling, big data aggregation, and foundational ore-deposit science.

Even after a mine is established, extraction of the minerals can also be a very slow process. For lithium brines, for example, the brines are pumped from underground aquifers into shallow holding ponds to be evaporated under sunlight which can take several months. To expedite this process, Lilac Solutions, founded in 2016, developed a new ion exchange technology which uses hydrochloric acid to produce lithium chloride. This direct lithium extraction method drastically reduces the extraction time and can increase the lithium recovery rate from 40% (using evaporation ponds) to 99% [12].

Avoiding the costs of exploration and excavation, battery recycling plants are expected to have lower CAPEX than conventional mines. Moreover, given the high concentration of the minerals, recyclers should also have lower operating costs. Additionally, battery recycling plants can optimize their location near consumers, whereas mines tend to be in remote areas, increasing transportation costs. While a mine typically only produces one or two elements per location, a battery recycling facility can produce all of the elements needed to manufacture a new battery in the exact ratio of elements needed. These economic disadvantages are in addition to the geopolitical considerations and labor practice issues for many mines. Furthermore, recycling is estimated to reduce GHG emissions by 90% (using hydrometallurgical processes or electro-extraction, closer to 50% for pyrometallurgy).

“A recycling facility [is] essentially the "perfect mine" from which to harvest materials at a lower cost, lower environmental footprint, and enhanced security of supply compared to primary mines.” - Ryan Melsert, CTO, ABMC

Resources

[10] China controls sway of electric vehicle power through battery chemicals, cathode and anode
production. (2020, May 6). Benchmark Mineral Intelligence.
https://www.benchmarkminerals.com/membership/china-controls-sway-of-electric-vehicle-power-thro
ugh-battery-chemicals-cathode-and-anode-production/

[11] Findings on the Worst Forms of Child Labor - Democratic Republic of the Congo | U.S.
Department of Labor. (2019). Bureau of International Labor Affairs.
https://www.dol.gov/agencies/ilab/resources/reports/child-labor/congo-democratic-republic-drc#:%7E
:text=Children%20in%20the%20Democratic%20Republic,or%20abduction%20by%20non%2Dstate

[12] Corporation, L. S. D. (2021, April 13). Lilac Solutions Achieves 99% Lithium Recovery With Ion
Exchange Process. PRNewswire.
https://www.prnewswire.com/news-releases/lilac-solutions-achieves-99-lithium-recovery-with-ion-exc
hange-process-301267282.html

About the Author(s)

Kezi Cheng

Kezi Cheng is a Ph.D. candidate at Harvard's School of Engineering and Applied Sciences where her research focuses  on photo-induced dynamic covalent chemistries for elastomersand polymer networks. She is an NSF graduate research fellow, a Harvard Graduate Energy and Environment Consortium fellow, and is on the organizing team for the inaugural Harvard Circular Economy Symposium. Cheng holds a bachelor's degree in materials science and engineering with a minor in management from MIT. She has experience in technology licensing and working with industry partners to bring lab innovations to market. Cheng is a Cohort 2021 Activate Fellow and co-founder of Flo.Materials, a startup commercializing a new class of infinitely recyclable polymers and offering recycling as a service.

Tobias Egle

Tobias Egle is a Harvard Ph.D. working at the intersection of Materials Science, Chemistry, and applied energy technology. He is very passionate about climate tech aiming to help us get to zero-emission. Besides his surface science and catalysis research, his  experience is at the nexus of pro-bono consulting and climate tech. In the energy and climate world, he has gained experience working at an early-stage startup and also dabbled with being a founder himself. Prior to his Ph.D., he studied Chemical Engineering in Germany. He has previously worked in various settings worldwide, from the Lawrence Livermore Laboratory in California to BASF in Shanghai to a community-driven poverty alleviation project in Namibia.

Janina Motter

Janina Motter is a recent graduate of Harvard’s MS/MBA Engineering Sciences program (‘21). She holds a Bachelor's degree in Chemistry and a Master's degree in Materials Science & Engineering from Stanford. Over the past 4 years, she worked in R&D and operations at several materials-focused startups in the Bay Area, from 3D printing materials to energy-efficient smart windows. Janina was on the organizing team for the inaugural Harvard Circular Economy Symposium, along with the pilot launch of student-run incubator Activate Eco (now Nucleate Eco).

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