Element Six and the University of Warwick Announce Development of
New Boron-Doped Synthetic Diamond Electrode for Extreme Electroanalysis Sensing Applications
Material Available to Commercial Partners for Enhanced Sensing Applications
Data provided by The University of Warwick showing reversible characteristics for
electrolysis of a redox mediator recorded using Element Six’s DIAFILM EA
March 18, 2013
PHILADELPHIA—Mar. XX, 2013—AT PITTCON 2013, Element Six, the world leader in synthetic diamond supermaterials and member of the De
Beers Group of Companies, today announced, that it has engineered
DIAFILM EA (Electroanalysis grade) in collaboration with
The University of Warwick.
The free-standing, solid boron doped microwave chemical vapor deposition (CVD) diamond electrode is expected to transform sensing technologies, allowing the development of next generation advanced electroanalysis sensing systems to benefit the biomedical, environmental, food, pharmaceutical, and oil and gas industries.
DIAFILM EA benefits from being chemically inert and stable, overcoming long-term stability issues in the harshest of environments such as in corrosive and elevated temperature and pressure operations. In many of the most demanding of electroanalysis applications, DIAFILM EA has the ability to perform thousands of cycles, whereas other electrode materials only survive a single use. This is combined with high phase purity and optimum levels of conductivity, enabling the highest level of sensitivity, selectivity and responsiveness.
With the introduction of the new DIAFILM EA, Element Six is now actively collaborating with commercial partners to enhanced electrochemical sensing applications leveraging the proven performance of this next generation sensing material. With the widest solvent window of any electrode material, and the lowest background current and capacitance, DIAFILM EA is expected to transform the business economics of electroanalytical sensing systems and technologies.
“For the past decade or so, thin-film boron doped diamond electrodes have not delivered on their technical promise, as the industry has struggled to combine the necessary level of conductivity with the required phase purity,” said Adrian Wilson, head of technologies at Element Six. “We have manufactured a grade of boron doped CVD diamond with the ideal optimal conductivity, combined with 100 percent phase purity to meet this market need. Given its unique properties, DIAFILM EA will advance tomorrow’s sensing systems.”
“The research and development of synthetic diamond as an electrode material has exposed its potential to transform the future of sensing technologies,” said Julie MacPherson, professor, the University of Warwick. “Element Six’s CVD diamond is an exciting material to work with, and one we’ve enjoyed working with throughout our six-year research collaboration with the company.”
The synthetic diamond technical work was completed by the Element Six R&D team based at Ascot in the United Kingdom, and is a result of more than 15 years of research and development. Electrochemical characterization testing of DIAFILM EA was carried out by the Electrochemistry and Interfaces Group in the Department of Chemistry, at the University of Warwick.
If you’re interested in learning more about Element Six’s CVD diamond electrode, please visit
About Element Six
Element Six is a synthetic diamond supermaterials company. Element Six is a member of the De Beers Group of Companies, its majority shareholder. Element Six designs, develops and produces synthetic diamond supermaterials, and operates worldwide with its head office registered in Luxembourg, and primary manufacturing facilities in China, Germany, Ireland, Sweden, South Africa, U.S. and the U.K.
Element Six supermaterial solutions are used in applications such as cutting, grinding, drilling,
shearing and polishing, while the extreme properties of synthetic diamond beyond hardness are already
opening up new applications in a wide array of industries such as optics, power transmission, water treatment,
semi-conductors and sensors.