New class of materials for energy storage researched at HZB: 2D titanium carbides store large amounts of electrical energy and can be charged and discharged in a matter of seconds

02. March 2020

New class of materials for energy storage researched at HZB

2D titanium carbides store large amounts of electrical energy and can be charged and discharged in a matter of seconds

MXene © Martin Künsting/HZB

MXenes are 2D materials forming multi-layered particles (left) from which pseudocapacitors are made. Shining X-ray light on MXenes revealed changes of their chemical structure upon intercalation of urea molecules (right) compared to pristine MXenes (center). © Martin Künsting/HZB

Two dimensional titanium carbides, so-called MXenes, are being discussed as candidates for the rapid storage of electrical energy. Like a battery, MXenes can store large amounts of electrical energy through electrochemical reactions – but unlike batteries, can be charged and discharged in a matter of seconds. In collaboration with Drexel University, a team at HZB showed that the intercalation of urea molecules between the MXene layers can increase the capacity of such “pseudo-capacitors” by more than 50 percent. At BESSY II they have analysed how changes of the MXene surface chemistry after urea intercalation are responsible for this.

There are different solutions for storing electrical energy: Lithium-based electrochemical batteries, for example, store large amounts of energy, but require long charging times. Supercapacitors, on the other hand, are able to absorb or release electrical energy extremely quickly – but store much less electrical energy.

Pseudocapacitors MXene

A further option is on the horizon since 2011: A new class of 2D materials that could store enormous amounts of charge was discovered at Drexel University, USA. These were so-called MXenes, Ti3C2Tx nanosheets that form a two-dimensional network together, similar to graphene. While titanium (Ti) and carbon (C) are elements, Tx describes different chemical groups that seal the surface, for example OH-groups. MXenes are highly conductive materials with hydrophilic surfaces and can form dispersions resembling black ink, composed of stacked layered particles in water.

Ti3C2Tx MXene can store as much energy as batteries, but can be charged or discharged within tens of seconds. While similarly fast (or faster) supercapacitors absorb their energy by electrostatic adsorption of electrical charges, the energy is stored in chemical bonds at the surface of MXenes. Energy storage is therefore much more efficient.

New insights into chemistry by soft X-ray methods

In cooperation with the group of Yuri Gogotsi at Drexel University, the HZB scientists Dr. Tristan Petit and Ameer Al-Temimy have now for the first time used soft X‑ray absorption spectroscopy to investigate MXene samples at two experimental stations LiXEdrom and X-PEEM at BESSY II. With these methods, the chemical environment of MXene surface groups was analyzed over individual MXene flakes in vacuum but also directly in water environment. They found dramatic differences between pristine MXenes and MXenes between which urea molecules were intercalated.

Urea increases the capacity

The presence of urea molecules also significantly changes the electrochemical properties of MXenes. The area capacity increased to 1100 mF/cm2, which is 56 percent higher than pristineTi3C2Tx electrodes prepared similarly. The XAS analyses at BESSY II showed that surface chemistry is changed by the presence of the urea molecules. "We could also observe the oxidation state of the Ti atoms on the Ti3C2Tx MXene surfaces by using X-PEEM. This oxidation state was higher with the presence of urea which may facilitate to store more energy" says Ameer Al-Temimy, who performed the measurements as part of his doctorate.

Publication:

J. Phys. Chem. C (2020): Enhancement of Ti3C2 MXene Pseudocapacitance After Urea Intercalation Studied by Soft X-ray Absorption Spectroscopy, Ameer Al-Temimy, Babak Anasori, Katherine A. Mazzio, Florian Kronast, Mykola Seredych, Narendra Kurra, Mohamad-Assaad Mawass, Simone Raoux, Yury Gogotsi, and Tristan Petit
DOI: 10.1021/acs.jpcc.9b11766

 

Contact:

Helmholtz-Zentrum Berlin für Materialien und Energie
Institute Nanospectroscopy

Ameer Al-Temimy
Phone: +49 30 8062-12904
Email: ameer.al-temimy@helmholtz-berlin.de

Dr. Tristan Petit
Phone: +49 30 8062-15805 / -43038
Email: tristan.petit@helmholtz-berlin.de

Press Officer:
Dr. Antonia Rötger
Phone: +49 30 8062-43733
Email: antonia.roetger@helmholtz-berlin.de

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