A single gold plasmonic nanoantenna probes the hydrogen absorption in an adjacent palladium nanocube. Illustration by Ella Marushchenko and Alex Tokarev.
– We were able to show that you gain deeper insights into the physics of how nanomaterials interact with molecules in their environment by looking at the individual nanoparticle as opposed to looking at many of them at the same time, which is what is usually done, says Associate Professor Christoph Langhammer, who led the project.
By applying a new experimental approach called plasmonic nanospectroscopy, the group studied hydrogen absorption into single palladium nanoparticles and found that particles with exactly the same shape and size may exhibit differences as great as 40 millibars in the pressure at which hydrogen is absorbed. The development of sensors that can detect hydrogen leaks in fuel cell powered cars is one example of where this new understanding could become valuable in the future.
– One main challenge when working on hydrogen sensors is to design materials whose response to hydrogen is as linear and reversible as possible. In that way, the gained fundamental understanding of the reasons underlying the differences between seemingly identical individual particles and how this makes the response irreversible in a certain hydrogen concentration range can be helpful, says Langhammer.
Others have looked at single nanoparticles one at a time, but the new approach introduced by the Chalmers team uses visible light with low intensity to study the particles. This means that the method is non-invasive and does not disturb the system it is investigating by, for example, heating it up.
– When studying individual nanoparticles you have to send some kind of probe to ask the particle ‘what are you doing?’. This usually means focusing a beam of high-energy electrons or photons or a mechanical probe onto a very tiny volume. You then quickly get very high energy densities, which might perturb the process you want to look at. This effect is minimized in our new approach, which is also compatible with ambient conditions, meaning that we can study nanoparticles one at a time in as close to a realistic environment as possible.
A new scientific paradigm
The project has been a successful collaboration initiative within the Chalmers Area of Advance Nanoscience and Nanotechnology, with a strong ambition to work interdisciplinarily. It involves researchers from the groups of Christoph Langhammer, Fredrik Westerlund and Kasper Moth-Poulsen at the departments of Physics, Biology and Chemistry. The Area of Advance also funded PhD student and first author of the published paper, Svetlana Syrenova, who performed all the single particle experiments, and a postdoctoral fellow, Yuri Diaz Fernandez who developed the colloidal self-assembly process used to make the samples together with PhD student Tina Gschneidtner.
– Svetlana Syrenova has patiently done hundreds of experiments over the last three years. And though it has been tempting at times to publish the results earlier, she was always ready to give it one more try and improve things further. This was one of the keys to succeed with publishing our work in such a prestigious journal, together with the fantastic collaboration with the Moth-Poulsen group stimulated by the Area of Advance, says Langhammer.
Even though they have now reached the level where their results are ready to be published, Christoph Langhammer believes they have just scratched the surface of what their discovery and developed experimental methodology will lead to in relation to further research. He hopes that they have helped to establish a new experimental paradigm, where looking at nanoparticles individually will become standard in the scientific world.
– It is not good enough to look at, and thus obtain an average of, hundreds or millions of particles if you want to understand the details of how nanoparticles behave in different environments and applications. You have to look at individual ones, and we have found a new way to do that. My own long-term vision is to apply our method to more complex processes and materials, and to push the limits in terms of how small nanoparticles can be for us to be able to measure them. Hopefully, along the way, we will gain even deeper insights into the fascinating world of nanomaterials.
Text: Karin Weijdegård
Photo: Sabina Johansson
About: The method
Single particle plasmonic nanospectroscopy makes use of the fact that noble metal nanoparticles, such as gold, strongly interact with visible light through a phenomenon called localised surface plasmon resonance. This means that individual “plasmonic nanoantennas” are actually visible in a simple optical microscope. At the same time, created by the interaction with light, a strong electric field surrounds the nanoantenna and thus makes it a very sensitive probe for chemical processes occurring in its intimate surrounding. The combination of these two effects is in essence what the Chalmers researchers have utilized to study individual nanoparticles. Specifically, by linking a Palladium nanoparticle to a Gold plasmonic nanoantenna they used the antenna to probe the hydrogen absorption and hydride formation in the attached palladium nanoparticle, which had well-defined size and shapes such a cube, an octahedron or a nanorod.
About: Why each nanoparticle is unique
Size- and shape-selected nanoparticles may appear identical at first sight since they have the almost exact same size, the same shape and consist of the exact same element. In spite of this, the shape-selected palladium nanoparticles studied by the Chalmers team displayed significant particle-characteristic differences in the way they interact with hydrogen gas and when they form what is known as a hydride. The reason for this behaviour unearthed by the Chalmers researchers is the energetic interplay between dislocation formation and lattice strain generated at the metal-hydride interface during hydride formation. This interplay is unique to each nanoparticle because it is governed by the particle-specific defect structure at the atomic level and the availability of lattice dislocations to accommodate the lattice strain created during hydrogen absorption.
Read the paper in Nature Materials