Nanotechnology involves the production, manipulation and use of materials ranging in size from less than a micron to that of individual atoms. Although nanomaterials may be synthesized using chemical approaches, it is now possible to include the use of biological materials. In this review, we critically assess the role of microorganisms and plants in the synthesis of nanoparticles.

Biosynthesis of nanoparticles: technological concepts and future applications

Transparent conductors as solar energy materials: A panoramic review

https://www.oocities.org/gazerwho/Bacteriaasworkersintheliving.pdf

Bacteria as workers in the living factory: metal-accumulating bacteria and their potential for materials science.

This report describes the concentrating solar power (CSP) systems using solar absorbers to convert concentrated sunlight to thermal electric power. It is possible to achieve solar absorber surfaces for efficient photothermal conversion having high solar absorptance (a) for solar radiation and a low thermal emittance (e) at the operational temperature. A low reflectance (?'' 0) at wavelengths (?) 3 mm and a high reflectance (?'' 1) at l 3 mm characterize spectrally selective surfaces. The operational temperature ranges of these materials for solar applications can be categorized as low temperature (T 400 C). High- and mid-temperature applications are needed for CSP applications. For CSP applications, the ideal spectrally selective surface would be low-cost and easy to manufacture, chemically and thermally stable in air at elevated operating temperatures (T= 500 C), and have a solar absorptance= 0.98 and a thermal emittance= 0.05 at 500 C.

/pdf/review-of-mid-to-high-temperature-solar-selective-absorber-3b1c7v216u.pdf

Review of Mid- to High-Temperature Solar Selective Absorber Materials

Review of physical vapor deposited (PVD) spectrally selective coatings for mid- and high-temperature solar thermal applications

Condensation of water by radiative cooling

Heat transfer occurs via radiation, conduction and convection. When the radiative exchange is significant- which holds true for many important applications — one can achieve energy efficiency by exploiting surfaces with spectral selectivity. This term is taken to imply that the radiative properties (i.e. the absorptance A, emittance E, reflectance R, and transmittance T) are qualitatively different within different parts of the electromagnetic spectrum. Spectral selectivity is often obtained by use of coatings onto substrates which are either transparent or opaque metallic.

Spectrally Selective Surfaces for Heating and Cooling Applications

LiyV2O5 films were produced by reactive de magnetron sputtering followed by electrochemical posttreatment in LiClO4. X-ray diffraction showed an orthorhombic structure. Spectrophotometric transmittance and reflectance measurements demonstrated that the luminous and solar absorptance increased moderately when y increased from zero to unity. It is argued that LiyV2O5 is useful as an ion storage material operating in conjunction with electrochromic films.

Electrochemically lithiated V2O5 films: An optically passive ion storage for transparent electrochromic devices

Noise in nanotechnology

Thin films were made by spinning a dispersion of tin-doped indium oxide particles, having an average diameter of 14 nm, onto glass substrates. As-deposited thin films displayed a resistivity ρ of 0.3 Ω m and some optical absorption. Annealing in vacuum at 200–400oC for 2 h, and subsequently in air at 500oC for 2 h, produced films with ρ ≈ 10−3 Ω m and a visible transmittance exceeding 90%. Leaving out the vacuum treatment yielded higher resistivity.

https://iopscience.iop.org/article/10.1088/0964-1726/11/5/308/pdf

Claes-Goeran Granqvist

Papers

Condensation of water by radiative cooling

Spectrally Selective Surfaces for Heating and Cooling Applications

Electrochemically lithiated V2O5 films: An optically passive ion storage for transparent electrochromic devices

Noise in nanotechnology

Electrical and optical properties of thin films prepared by spin coating a dispersion of nano-sized tin-doped indium oxide particles