Researchers have developed a technique for creating new kinds of optical materials and devices that could lead to light-bending and cloaking devices.
“Chemists and physicists will be able to build an almost infinite number of new structures with all sorts of interesting properties…”
Using DNA as a key tool, the team took gold nanoparticles of different sizes and shapes and arranged them in two and three dimensions to form optically active superlattices. Structures with specific configurations could be programmed through choice of particle type and both DNA-pattern and sequence to exhibit almost any color across the visible spectrum, the scientists report.
“Architecture is everything when designing new materials, and we now have a new way to precisely control particle architectures over large areas,” says Chad A. Mirkin, professor of chemistry in the Weinberg College of Arts and Sciences at Northwestern University. “Chemists and physicists will be able to build an almost infinite number of new structures with all sorts of interesting properties. These structures cannot be made by any known technique.”
Combining the new and old
The technique combines an old fabrication method—top-down lithography, the same method used to make computer chips—with a new one—programmable self-assembly driven by DNA. The research team is the first to combine the two to achieve individual particle control in three dimensions.
Scientists will be able to use the powerful and flexible technique to build metamaterials—materials not found in nature—for a range of applications including sensors for medical and environmental uses.
The researchers used a combination of numerical simulations and optical spectroscopy techniques to identify particular nanoparticle superlattices that absorb specific wavelengths of visible light. The DNA-modified nanoparticles—gold in this case—are positioned on a pre-patterned template made of complementary DNA. Stacks of structures can be made by introducing a second and then a third DNA-modified particle with DNA that is complementary to the subsequent layers.
In addition to being unusual architectures, these materials are stimuli-responsive: the DNA strands that hold them together change in length when exposed to new environments, such as solutions of ethanol that vary in concentration. The change in DNA length, the researchers found, resulted in a change of color from black to red to green, providing extreme tunability of optical properties.
“Tuning the optical properties of metamaterials is a significant challenge, and our study achieves one of the highest tunability ranges achieved to date in optical metamaterials,” says Koray Aydin, assistant professor of electrical engineering and computer science.
“Our novel metamaterial platform—enabled by precise and extreme control of gold nanoparticle shape, size, and spacing—holds significant promise for next-generation optical metamaterials and metasurfaces,” Aydin says.
DNA ‘landing pads’ for nanoparticles
The study describes a new way to organize nanoparticles in two and three dimensions. The researchers used lithography methods to drill tiny holes—only one nanoparticle wide—in a polymer resist, creating “landing pads” for nanoparticle components modified with strands of DNA. The landing pads are essential, Mirkin says, since they keep the structures that are grown vertical.
The nanoscopic landing pads are modified with one sequence of DNA, and the gold nanoparticles are modified with complementary DNA. By alternating nanoparticles with complementary DNA, the researchers built nanoparticle stacks with tremendous positional control and over a large area. The particles can be different sizes and shapes (spheres, cubes, and disks, for example).
“This approach can be used to build periodic lattices from optically active particles, such as gold, silver, and any other material that can be modified with DNA, with extraordinary nanoscale precision,” says Mirkin, director of Northwestern’s International Institute for Nanotechnology. Mirkin is also a professor of medicine at the university’s Feinberg School of Medicine and a professor of chemical and biological engineering, biomedical engineering, and materials science and engineering in the McCormick School.
The success of the reported DNA programmable assembly required expertise with hybrid (soft-hard) materials and exquisite nanopatterning and lithographic capabilities to achieve the requisite spatial resolution, definition, and fidelity across large substrate areas. The project team turned to Vinayak P. Dravid, a longtime collaborator of Mirkin’s who specializes in nanopatterning, advanced microscopy, and characterization of soft, hard, and hybrid nanostructures.
Dravid, professor of materials science and engineering and the founding director of the NUANCE center, which houses the advanced patterning, lithography, and characterization used in the DNA-programmed structures, contributed his expertise and assisted in designing the nanopatterning and lithography strategy and the associated characterization of the new exotic structures.
The researchers report their findings in the journal Science.
The Center for Bio-Inspired Energy Science, the US Department of Energy, Office of Science, Basic Energy Sciences, and the Air Force Office of Scientific Research supported the research.