// RecycleMat-Projekt: More than just Recovering Metals

At present, the few lithium-ion batteries that are recycled are sent to existing plants to recover their non-ferrous metals. During this process, a large portion of the non-ferrous metals such as cobalt, nickel or copper can be recovered, while the lithium is lost in the slag. Since the situation is not satisfactory and the lithium especially needs to be recycled, alternative scenarios have been devised and a number of processes have been pre-developed in recent years.

The now most intensively researched process is as follows: the batteries are collected decentrally, deep discharged and then semi-automatically dismantled into modules and cells. Housing components and cables can already be collected separately. The cells are then mechanically crushed in a nitrogen atmosphere and the separator, copper and aluminium foils are separated using an air separation processes. What remains is a so-called “black powder”, that is a mixture of cathode and anode material as well as electrolyte. The electrolyte can be removed by vacuum treatment at a higher temperature. The dry black powder is then processed further using a wet chemical process. It is first dissolved in sulphuric acid and then the metals are individually fractionated. Recycling rates of > 85% can already be achieved for nickel and cobalt, while this value is currently closer to 70% for lithium. One problem is that traces of fluorine enter the cell via the lithium-containing conducting salt and various binders during battery construction. Fluorine and fluorine-containing compounds are difficult to eliminate during the recycling process and remain through all process stages, affecting the purity of the metals being recovered.

In the RecycleMat project, funded by the Baden-Württemberg Ministry of Economic Affairs, ZSW is trying to evaluate a different recycling route whereby the anode and cathode materials are recovered directly from the black powder to then be directly reused in less demanding batteries such as those used for stationary electricity storage.

This Website uses cookies and third-party content

On this website, we use cookies which are absolutely necessary for displaying its content. If you click on “Accept cookies chosen”, only these necessary cookies are used. Other cookies and content by third parties (such as YouTube videos or maps by Google Maps) are only set with your consent by choosing “Accept all cookies”. For further information, please refer to our data protection policy where you can withdraw your consent at any time.

Legal Information

Privacy Policy

learn more

Without necessary cookies, this website will not work properly. These cookies help to ensure basic functions such as navigating the pages and accessing protected parts of the website.


The cookie box saves information about which cookies you have activated.

learn more

We use tracking technologies for marketing purposes. To this end, we also use third party agents who use may use – across devices – cookies, fingerprints, tracking pixel and IP addresses. On our site, we also embed third-party content by other suppliers (e.g. social plug-ins, geographical map services). We cannot influence data processing and tracking by such third parties. Should you activate third-party content, on loading the respective page, such content is loaded from the web servers of third paty suppliers and data which are necessary for technical purposes for loading this content. Should this third-party content contain cookies, these will also be set. We try to implement such content in a way that uses data efficiently. In this context, we use service providers in third countries outside the EU without appropriate data protection policies. This carries the following risks: Access by authorities without information, no rights for the persons concerned, no remedies, loss of control.


We have embedded services by YouTube


We use map services provided by Google (Google Maps)


We use Matoma for visitor tracking.

Accept selection Accept all Decline all