By genetically encoding affinity for inorganic materials into the capsid proteins of the M13 bacteriophage, the virus can act as a template for the synthesis of nanomaterial composites for use in various device applications. Herein, the M13 bacteriophage is employed to build a multifunctional and three-dimensional scaffold capable of improving both electron collection and light harvesting in dye-sensitized solar cells (DSSCs). This has been accomplished by binding gold nanoparticles (AuNPs) to the virus proteins and encapsulating the AuNP-virus complexes in TiO2 to produce a plasmon-enhanced and nanowire (NW)-based photoanode. The NW morphology exhibits an improved electron diffusion length compared to traditional nanoparticle-based DSSCs and the AuNPs increase the light absorption of the dye-molecules through the phenomenon of localized surface plasmon resonance. Consequently, we report a virus-templated and plasmon-enhanced DSSC with an efficiency of 8.46%, which is achieved through optimizing both the NW morphology and the concentration of AuNPs loaded into the solar cells. In addition, we propose a theoretical model that predicts the experimentally observed trends of plasmon-enhancement.
Nobel metal composite aerogel fibers made from flexible and porous biopolymers offer a wide range of applications, such as in catalysis and sensing, by functionalizing the nanostructure. However, producing these composite aerogels in a defined shape is challenging for many protein-based biopolymers, especially ones that are not fibrous proteins. Here, we present the synthesis of silk fibroin composite aerogel fibers up to 2 cm in length and a diameter of ~300 μm decorated with noble metal nanoparticles. Lyophilized silk fibroin dissolved in hexafluoro-2-propanol (HFIP) was cast in silicon tubes and physically crosslinked with ethanol to produce porous silk gels. Composite silk aerogel fibers with noble metals were created by equilibrating the gels in noble metal salt solutions reduced with sodium borohydride, followed by supercritical drying. These porous aerogel fibers provide a platform for incorporating noble metals into silk fibroin materials, while also providing a new method to produce porous silk fibers. Noble metal silk aerogel fibers can be used for biological sensing and energy storage applications.
First responders and military personnel require protection against multiple hazards. However, the structure of conventional materials only provides protection against a single threat. By combining a porous network with aligned fibers, this work demonstrates a multifunctional material with a high insulation and high ballistic resistance. Overcoming the limitations of conventional materials, this approach enables simultaneous thermal insulation and mechanical protection, serving as an ideal material platform for the design of high-performance protective equipment for aerospace and warfare applications.
A spoof
fingerprint was fabricated on paper and applied for a spoofing
attack to unlock a smartphone on which a capacitive array of sensors
had been embedded with a fingerprint recognition algorithm. Using
an inkjet printer with an ink made of carbon nanotubes (CNTs), we
printed a spoof fingerprint having an electrical and geometric pattern
of ridges and furrows comparable to that of the real fingerprint.
With this printed spoof fingerprint, we were able to unlock a smartphone
successfully; this was due to the good quality of the printed CNT
material, which provided electrical conductivities and structural
patterns similar to those of the real fingerprint. This result confirms
that inkjet-printing CNTs to fabricate a spoof fingerprint on paper
is an easy, simple spoofing route from the real fingerprint and suggests
a new method for outputting the physical ridges and furrows on a two-dimensional
plane.
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