skip to primary navigationskip to content
 

Can bacteria save the world

Understanding how natural biocatalysts extracted from bacteria can be used for solar driven water splitting and optimising them for utilising hydrogen generation as the future fuel.

Sunlight provides us with a practically inexhaustible flow of energy, and the photochemical conversion of solar to chemical energy (e.g. hydrogen) attracts much interest. Direct conversion of solar energy to a fuel is important, because the majority of the world's energy is used in the form of a fuel, and not electricity.

My research focuses on combining recent advances in the field of nanotechnology and nature-made machines to efficiently produce hydrogen, which is a fuel of the future. Nanotechnology allows us to manipulate matter on the smallest scale, enabling many opportunities. We use self-assembly to fabricate high surface area electrodes: an array of nano-sized spheres is assembled on a substrate using capillary forces and this acts as a template to grow an electrode around them. After removal of the spheres, high surface area electrodes are obtained which support many more catalyst per square centimetre than the conventional electrodes, assuring high efficiency of our devices. The catalysts which make water splitting happen are directly extracted from biological systems. Catalysts for the oxygen-producing half-reaction are taken out of cyanobacterium and are the so-called ‘Photosystem II’. The hydrogen-producing half is driven by enzymes called hydrogenases, extracted from bacteria of the family Desulfomicrobiaceae. We are able to investigate these processes directly in our devices.

Natural catalysts extracted from two different bacteria types split water when are connected via an electrode and upon sun irradiation. The produced hydrogen can be used as fuel for hydrogen cars. B) Scanning Electron Microscope image of the high surface area electrode (top view)

 

A) Natural catalysts extracted from two different bacteria types split water when are connected via an electrode and upon sun irradiation. The produced hydrogen can be used as fuel for hydrogen cars.

 

 

B) Scanning Electron Microscope image of the high surface area electrode (top view)

With this research we aim to gain a better understanding of such biological catalysts and the way they interact with the artificially-made materials, so we can make better solar-driven water splitting cells.

Dirk Mersch

RSS Feed Latest news

Call for Midi+PhD proposals

Dec 20, 2016

The NanoDTC invites Midi+PhD proposals from Cambridge Academics for its 2016 cohort. Submission deadline is 20th Feb 2017.

Admissions for Oct 2017 - 4th Jan Deadline

Dec 15, 2016

We are accepting applications for Oct 2017 entry. The deadline for applications to be considered in the 2nd round is 4th Jan. Please email team@nanodtc.cam.ac.uk if you have questions.

Helmholtz Prize for Nicholas Bell (NanoDTC Alumnus c2009)

Jun 27, 2016

Dr Nicholas Bell along with his PhD Supervisor Prof. Ulrich Keyser has received the 2016 Helmholtz Prize for groundbreaking work on identification and quantification of proteins in complex mixtures using nanopore sensing.

NanoDTC Translational Prize Fellows Selected

Jun 16, 2016

Students Richard Howe, Tarun Vemulkar and Jeroen Verheyen have been selected as the NanoDTC Translational Prize Fellows for 2016-17