Over the years, vanadium dioxide, (VO2(M1)), has been extensively utilised to fabricate thermochromic thin films with the focus on using external stimuli, such as heat, to modulate the visible through near-infrared transmittance for energy efficiency of buildings and indoor comfort. It is thus valuable to extend the study of thermochromic materials into the mid-infrared (MIR) wavelengths for applications such as smart radiative devices. On top of this, there are numerous challenges with synthesising pure VO2 (M1) thin films, as most fabrication techniques require the post-annealing of a deposited thin film to convert amorphous VO2 into a crystalline phase. Here, we present a direct method to fabricate thicker VO2(M1) thin films onto hot silica substrates (at substrate temperatures of 400 °C and 700 °C) from vanadium pentoxide (V2O5) precursor material. A high repetition rate (10 kHz) femtosecond laser is used to deposit the V2O5 leading to the formation of VO2 (M1) without any post-annealing steps. Surface morphology, structural properties, and UV–visible optical properties, including optical band gap and complex refractive index, as a function of the substrate temperature, were studied and reported below. The transmission electron microscopic (TEM) and X-ray diffraction studies confirm that VO2 (M1) thin films deposited at 700 °C are dominated by a highly texturized polycrystalline monoclinic crystalline structure. The thermochromic characteristics in the mid-infrared (MIR) at a wavelength range of 2.5–5.0 μm are presented using temperature-dependent transmittance measurements. The first-order phase transition from metal-to-semiconductor and the hysteresis bandwidth of the transition were confirmed to be 64.4 °C and 12.6 °C respectively, for a sample fabricated at 700 °C. Thermo-optical emissivity properties indicate that these VO2 (M1) thin films fabricated with femtosecond laser deposition have strong potential for both radiative thermal management or control via active energy-saving windows for buildings, and satellites and spacecraft.
Erbium-doped nanocrystal
(NC)-dispersed polymer thin films are
attractive core materials for use in optical waveguides as they can
provide high optical gain and enable the formation of compact waveguide
amplifiers. Nonetheless, there are significant challenges associated
with obtaining good dispersibility of NCs into a polymer matrix and
favorable optical properties. Therefore, in this paper, we report
the fabrication of Er3+-doped ceria (EGC) NCs employing
the Leeds alginate process (LAP) and their incorporation into a siloxane
polymer matrix. The surface morphology and compositional, structural,
and optical properties of the fabricated films are evaluated to assess
the NC dispersion and their suitability for the waveguide amplifier.
The photoluminescence (PL) and lifetime measurements of the NCs–polymer
nanocomposite thin film samples show intense, broadband PL emission
of the Er3+ ions at 1534 nm (4I13/2 → 4I15/3 transition) with a full width
at half-maximum (fwhm) of ∼64 nm and lifetime in the range
of 2.6–3.0 ms. The inhomogeneously broadened PL spectra and
improvement in lifetime of NCs in the polymer are important results
that we report. The EGC NCs–polymer nanocomposite thin films
also exhibit excellent transparency in the NIR wavelength range and
a refractive index in the range of 1.53–1.58 in the visible
wavelength. The work presented here clearly demonstrates the potential
of using high-quality Er-doped nanocomposite polymer thin films for
interesting applications such as compact low-cost waveguide amplifiers
and lasers.
The amount of moisture in wood fuel has a significant influence on the emissions of particulate matter (PM) and gaseous pollutants when burned in small-scale domestic appliances. Previous studies have shown that higher moisture content generally produces higher particulate emissions factors. As well as quantity of material emitted, it is also important to understand the effects of moisture on particle qualities including size, composition and morphology -since these can influence the human-toxicity and environmental impacts of the particles. In this study, emissions were quantified and the particulate qualities were also examined using chemical, optical and thermogravimetric analysis as well as size-graded sampling. By comparing the results from the use of batches of beech wood fuel with differing moisture content, it was shown that there are consistent and significant differences in both the quantity and qualities of the resulting emissions when burned under the same conditions. This has important consequences for emission inventories which currently only assume an emission factor from a proscribed combustion situation ARTICLE HISTORY
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