Freigeist Fellowship for Tristan Petit

Dr. Tristan Petit will broaden his research on nanocarbon materials with the Freigeist Fellowship.

Dr. Tristan Petit will broaden his research on nanocarbon materials with the Freigeist Fellowship. © HZB

For his project on nanodiamond materials and nanocarbon, Dr. Tristan Petit has been awarded a Freigeist Fellowship from the VolkswagenStiftung. The grant covers a five-year period and will enable him to establish his own research team. The VolkswagenStiftung is funding with these prestigious fellowships outstanding postdocs planning original research that transcends the bounds of their own field.

Following his doctoral studies, Dr. Tristan Petit joined the HZB team of Prof. Emad Aziz supported by a post-doctoral stipend from the Alexander von Humboldt Foundation. He had already investigated surface modification of nanodiamonds while exploring their potential for biomedical applications during his doctoral research at the Diamond Sensors Laboratory (CEA) in Gif sur Yvette, France. Petit has since expanded his research interests. This is because nanodiamond materials can also exhibit catalytic effects, in particular when irradiated by sunlight. One dream is to develop synthetic nanodiamond materials for manufacturing solar fuels like methane using sunlight and carbon dioxide, thereby storing solar energy chemically. Aziz and Petit are now working on this project under the European DIACAT research programme.

As a Freigeist Fellow, Petit will investigate how nanocarbon materials in aqueous solutions interact with their environment. These interactions have hardly been studied so far, but they are essential for developing new applications and being better able to assess risks.

It is very difficult to study nanocarbon materials in aqueous solutions experimentally, though. Spectrographic methods using X-ray light can provide information about the electrochemical and photochemical processes. Petit relies on specialised setups for this such as LiXEdrom at BESSY II that were developed at HZB specifically for these kinds of experiments. He intends to use infrared spectroscopy to determine the configuration of water molecules surrounding the nanoparticles. Petit also plans to carry out sequential laser-based pump-probe measurements in order to observe ultrafast electronic processes in the nanoparticles. The methods have already proven themselves in nanocarbon solid-state experiments, but their utilisation in studying nanocarbon in liquids is new, however.

“The Freigeist Fellowship makes it possible for me to research these problems comprehensively. Once we better understand the complex interactions between nanocarbon particles in an aqueous environment, we will be able to develop a new generation of carbon-based nanomaterials for different applications – from photocatalysis of solar fuels to medical applications”, says Petit. The Freigeist Fellowship is accompanied by funding of 805,000 EUR, of which 375,000 EUR is provided by HZB in-house resources and 430,000 EUR by the VolkswagenStiftung.

As a result, there are now two Freigeist Fellows on Aziz’ team. Dr. Annika Bande also received a Freigeist Fellowship last year and has since been working at the HZB Institute for Methods of Material Development headed by Aziz.

Further information on the Freigeist Fellowships:


You might also be interested in

  • Key role of nickel ions in the Simons process discovered
    Key role of nickel ions in the Simons process discovered
    Researchers at the Federal Institute for Materials Research and Testing (BAM) and Freie Universität Berlin have discovered the exact mechanism of the Simons process for the first time. The interdisciplinary research team used the BESSY II light source at the Helmholtz Zentrum Berlin for this study.

  • Watching indium phosphide at work
    Science Highlight
    Watching indium phosphide at work
    Indium phosphide is a versatile semiconductor. The material can be used for solar cells, for hydrogen production and even for quantum computers – and with record-breaking efficiency. However, little research has been conducted into what happens on its surface. Researchers have now closed this gap and used ultra-fast lasers to scrutinise the dynamics of the electrons in the material.
  • Freeze casting - a guide to creating hierarchically structured materials
    Science Highlight
    Freeze casting - a guide to creating hierarchically structured materials
    Freeze casting is an elegant, cost-effective manufacturing technique to produce highly porous materials with custom-designed hierarchical architectures, well-defined pore orientation, and multifunctional surface structures. Freeze-cast materials are suitable for many applications, from biomedicine to environmental engineering and energy technologies. An article in "Nature Reviews Methods Primer" now provides a guide to freeze-casting methods that includes an overview on current and future applications and highlights characterization techniques with a focus on X-ray tomoscopy.