June 6, 2013 report
Researchers use Raman spectroscopy and STM to allow chemical mapping of molecules to 1nm resolution
(Phys.org) —A team of researchers working at China's University of Science and Technology has succeeded in developing a chemical mapping technique capable of revealing the constituent atoms of a single molecule. In their paper published in the journal Nature, the team describes how they combined Raman spectroscopy with a scanning tunneling microscope (STM) to allow for chemical mapping of a molecule to a resolution of less than 1nm.
Raman spectroscopy is where chemists shine a laser on a small group of molecules and then measure the light as it's bounced back. The photons from the light source cause the molecules to vibrate and to interact with the bonds that hold molecules together causing a shift in their frequency—the scattering that results is unique for each type of molecule and thus allows for the method to be used as a means of identifying molecule types.
A STM is a device that allows for creating images of materials at the atomic level—one of its unique features is the very tiny metal tip used at the point of scanning. In this new effort the researchers combined Raman spectroscopy with STM to allow for unprecedented levels of molecular mapping.
Prior research has shown that when a STM tip is placed within nanometers of certain metals, plasmonic excitation occurs that when combined with Raman scattering can allow for mapping molecules to within 10nm. In this new research, the team has found that if the frequency of the plasmonic excitation is adjusted to match the molecular vibrations caused by photons from the laser light, the Raman signal is increased sharply, resulting in an ability to map the molecule being studied to less than 1nm.
The researchers note their technique is still in the very early stages of development—thus far they've only been able to use it on one molecule—a ring-shaped porphyrin. The process they note, is difficult and can take weeks or months carry out making its application impractical at this point for general research efforts. Also it only works when the molecule under study is held in a vacuum and in a -200° C environment. If the technique can be fined tuned however, it will allow future chemists to identify the atoms in individual molecules. Such a tool could open the door to new ways to study molecules at the nano-scale level as well as the bonds that hold them together.
More information: Chemical mapping of a single molecule by plasmon-enhanced Raman scattering, Nature 498, 82–86 (06 June 2013) doi:10.1038/nature12151
Abstract
Visualizing individual molecules with chemical recognition is a longstanding target in catalysis, molecular nanotechnology and biotechnology. Molecular vibrations provide a valuable 'fingerprint' for such identification. Vibrational spectroscopy based on tip-enhanced Raman scattering allows us to access the spectral signals of molecular species very efficiently via the strong localized plasmonic fields produced at the tip apex. However, the best spatial resolution of the tip-enhanced Raman scattering imaging is still limited to 3−15 nanometres, which is not adequate for resolving a single molecule chemically. Here we demonstrate Raman spectral imaging with spatial resolution below one nanometre, resolving the inner structure and surface configuration of a single molecule. This is achieved by spectrally matching the resonance of the nanocavity plasmon to the molecular vibronic transitions, particularly the downward transition responsible for the emission of Raman photons. This matching is made possible by the extremely precise tuning capability provided by scanning tunnelling microscopy. Experimental evidence suggests that the highly confined and broadband nature of the nanocavity plasmon field in the tunnelling gap is essential for ultrahigh-resolution imaging through the generation of an efficient double-resonance enhancement for both Raman excitation and Raman emission. Our technique not only allows for chemical imaging at the single-molecule level, but also offers a new way to study the optical processes and photochemistry of a single molecule.
Journal information: Nature
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