OAK RIDGE, Tenn., Aug. 10, 2015 - A microscope being developed at the Department of Energy's Oak Ridge National Laboratory will allow scientists studying biological and synthetic materials to simultaneously observe chemical and physical properties on and beneath the surface.
The Hybrid Photonic Mode-Synthesizing Atomic Force Microscope is unique, according to principal investigator Ali Passian of ORNL's Quantum Information System group. As a hybrid, the instrument, described in a paper published in Nature Nanotechnology, combines the disciplines of nanospectroscopy and nanomechanical microscopy.
"Our microscope offers a noninvasive rapid method to explore materials simultaneously for their chemical and physical properties," Passian said. "It allows researchers to study the surface and subsurface of synthetic and biological samples, which is a capability that until now didn't exist."
ORNL's instrument retains all of the advantages of an atomic force microscope while simultaneously offering the potential for discoveries through its high resolution and subsurface spectroscopic capabilities.
"The originality of the instrument and technique lies in its ability to provide information about a material's chemical composition in the broad infrared spectrum of the chemical composition while showing the morphology of a material's interior and exterior with nanoscale - a billionth of a meter - resolution," Passian said.
Researchers will be able to study samples ranging from engineered nanoparticles and nanostructures to naturally occurring biological polymers, tissues and plant cells.
The first application as part of DOE's BioEnergy Science Center was in the examination of plant cell walls under several treatments to provide submicron characterization. The plant cell wall is a layered nanostructure of biopolymers such as cellulose. Scientists want to convert such biopolymers to free the useful sugars and release energy.
An earlier instrument, also invented at ORNL, provided imaging of poplar cell wall structures that yielded unprecedented topological information, advancing fundamental research in sustainable biofuels.
Because of this new instrument's impressive capabilities, the researcher team envisions broad applications.
"An urgent need exists for new platforms that can tackle the challenges of subsurface and chemical characterization at the nanometer scale," said co-author Rubye Farahi. "Hybrid approaches such as ours bring together multiple capabilities, in this case, spectroscopy and high-resolution microscopy."
Looking inside, the hybrid microscope consists of a photonic module that is incorporated into a mode-synthesizing atomic force microscope. The modular aspect of the system makes it possible to accommodate various radiation sources such as tunable lasers and non-coherent monochromatic or polychromatic sources.
Other contributors to the article, titled "Opto-nanomechanical spectroscopic material characterization," are Brian Davison of ORNL and former ORNL researchers Laurene Tetard and Thomas Thundat. The paper is available at http://www.
Funding was provided by DOE's BioEnergy Sciences Center at ORNL. BESC is one of three DOE Bioenergy Research Centers established by the DOE's Office of Science in 2007. The centers support multidisciplinary, multi-institutional research teams pursuing the fundamental scientific breakthroughs needed to make production of cellulosic biofuels, or biofuels from nonfood plant fiber, cost-effective on a national scale. The centers are led by ORNL, Lawrence Berkeley National Laboratory and the University of Wisconsin-Madison in partnership with Michigan State University.
UT-Battelle manages ORNL for the DOE's Office of Science. The Office of Science is the single largest supporter of basic research in the physical sciences in the United States, and is working to address some of the most pressing challenges of our time. For more information, please visit http://science.
Cutline: A combination of carefully tuned mechanical and photonic excitations of the sample and probe allow for decoding of chemical and physical properties.
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