Category: U.S. Department of Defense
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Minuscule robots for targeted drug delivery
(Funded by the National Institutes of Health, the U.S. Department of Defense, and the U.S. National Science Foundation)
Researchers from Caltech, the University of Southern California, Santa Clara University, and the National University of Singapore have developed microrobots that decreased the size of bladder tumors in mice by delivering therapeutic drugs directly to the bladders. The microrobots incorporated magnetic nanoparticles and the therapeutic drug within the outer structure of the spheres. The magnetic nanoparticles allowed the scientists to direct the robots to a desired location using an external magnetic field. When the microrobots reached their targets, they remained in that spot, and the drug passively diffused out. -
Scientists develop coating for enhanced thermal imaging through hot windows
(Funded by the U.S. Department of Defense)
Scientists at Rice University have made it possible to capture clear images of objects through hot windows. The core of this breakthrough lies in the design of nanoscale resonators, which work like miniature tuning forks trapping and enhancing electromagnetic waves within specific frequencies. The resonators are made from silicon and organized in a precise array that allows fine control over how the window emits and transmits thermal radiation. One immediate application is in chemical processing, in which chemical reactions inside high-temperature chambers need to be monitored. -
Discovery of new growth-directed graphene stacking domains may precede new era for quantum applications
(Funded by the U.S. Department of Energy and the U.S. Department of Defense)
Researchers from New York University and Charles University in Prague, Czech Republic, have observed growth-induced self-organized stacking domains when three graphene layers are stacked and twisted with precision. The findings demonstrate how specific stacking arrangements in three-layer graphene systems emerge naturally – eliminating the need for complex, non-scalable techniques traditionally used in graphene twisting fabrication. The size and shape of these stacking domains are influenced by the interplay of strain and the geometry of the three-layer graphene regions. Some domains form as stripe-like structures, tens of nanometers wide and extending over microns. -
Nanoscale bumps and grooves trigger big changes in cell behavior
(Funded by the National Science Foundation, the U.S. Department of Defense, and the National Institutes of Health)
Researchers at the University of California San Diego have developed a platform for studying how nanoscale growing surfaces can impact cellular behavior. While previous studies have shown how surface structures can change cellular shape, little is known about their specific effects on cell metabolism. The research team found that cells grown on engineered nanopillar surfaces show dramatically different metabolic profiles than cells not grown on such surfaces. Also, the researchers found that growing cells on different engineered nanopillar surfaces could change how cells produce and modify lipids, the primary components of cell membranes. -
Physics experiment proves patterns in chaos in peculiar quantum realm
(Funded by the U.S. Department of Defense and the National Science Foundation)
Scientists from the University of California, Berkeley; the University of California, Santa Cruz; Harvard University; the University of Manchester in the United Kingdom; and the National Institute for Materials Science in Tsukuba, Japan, have conducted an experiment that confirms a theory first put forth 40 years ago stating that electrons confined in quantum space would move along common paths rather than producing a chaotic jumble of trajectories. To conduct this experiment, the scientists combined advanced imaging techniques and precise control over electron behavior within graphene, a two-dimensional material made of carbon atoms. The scientists used the finely tipped probe of a scanning tunneling microscope to first create a trap for electrons and then hover close to a graphene surface to detect electron movements without physically disturbing them.