Lithium-ion battery technology is a critically important component of the emerging renewable energy infrastructure. Since battery technology was first commercialized in the 1990s, significant progress has been made in materials development, motivated by the prospect of higher energy and power densities, increased cycling longevity, and faster charging and discharging rates....
Colloidal crystals engineered with DNA are fascinating structures that constitute an emerging form of programmable matter. Indeed, the use of DNA as a programmable bond has led to thousands of new crystal types, with exquisite control over crystal symmetry and lattice parameters. However, synthesizing large (> 100 µm) single-crystals has...
Uranium is a unique, multifaceted element that possesses rich chemistry and promise for challenging reactions. Pressing demands within nuclear stockpile stewardship and the nuclear energy sector call for development of this relatively understudied element. Uranium metal–organic frameworks (U-MOFs), a class of nanoscale hybrid materials, harness the exceptional attributes of uranium...
Shale gas is a critical energy resource that is comprised primarily of light gases that are expensive to transport. Because these gases are geographically spread-out and there is insufficient capacity to transport them to centralized processing facilities, they must often be flared, leading to great sources of resource waste and...
Uranium is a unique, multifaceted element that possesses rich chemistry and promise for challenging reactions. Pressing demands within nuclear stockpile stewardship and the nuclear energy sector call for development of this relatively understudied element. Uranium metal–organic frameworks (U-MOFs), a class of nanoscale hybrid materials, harness the exceptional attributes of uranium...
DNA is extremely versatile and powerful, both as a construct in biological applications and as a ligand in materials design due to the fact that its recognition properties can be programmed through sequence and length. Spherical nucleic acids (SNAs), nanoparticles surrounded by a dense shell of DNA or RNA, are...
In the face of a changing climate caused by anthropomorphic release of carbon dioxide and other greenhouse gases, major governments have committed to the reduction of CO2 and other emissions over time, requiring increased reliance on forms of carbon-free renewable energy. The inherent intermittency of renewable electricity sources creates a...
Nanocarriers, structures with at least one dimension on the nanoscale (1-1000 nm), have been engineered for delivery of various cargoes. The shape and flexibility of nanocarriers are important parameters that influence their biological performance. Self-assembling polymeric filamentous nanocarriers, known as filomicelles (FM), are of great interest to nanomedicine due to...
Nanomaterials offer unique properties not seen in their macroscopic kin. They can be used in printed electronics, as catalysts, and so much more. However, their diminutive size complicates materials processing techniques. They can easily aggregate become no longer useful. A solution to this is to use a polymeric surfactant such...
Nanocarriers as structures with at least one dimension in the nanometer scale are capable of loading small molecule therapeutics that would otherwise have poor bioavailability, non- specific uptake, and off target effects. Polymeric nanocarriers can be modified to tune their chemical and biological behavior to better suit the intended application....