YAG : R3+ (R = Ce, Dy, Yb) nanophosphor-based luminescent fibre-optic sensors for temperature measurements in the range 20–500 °C

We report the development of a group of luminescent fibre-optic temperature sensors that use Ce3+-, Dy3+-, and Yb3+-doped yttrium aluminium garnet (YAG) nanophosphors as thermosensitive materials. The nanophosphors have been prepared in the form of powders with a crystallite size from 19 to 27 nm by a polymer ? salt method and exhibit bright luminescence at 550 (YAG : Ce3+), 400, 480 (YAG : Dy3+), and 1030 nm (YAG : Yb3+). The sensor design includes a silica capillary, partially filled with a nanophosphor, and two large-aperture multimode optical fibres located in the capillary, which deliver excitation light and receive and transmit the photoluminescence signal. The photoluminescence signal amplitude of all the sensors decreases exponentially with increasing temperature, pointing to characteristic thermal quenching of photoluminescence and adequate operation of the devices up to 500 °C. The highest temperature sensitivity among the fibre-optic sensors is offered by the YAG : Ce3+ nanophosphor-based devices.

Soft X-ray spectra of Cerium laser-produced plasmas

Spectra of laser-produced plasmas of cerium have been recorded in the 1.5 to 15.5 nm spectral region. The plasmas were formed using the frequency doubled pulsed output of a neodymium-doped yttrium aluminium garnet (Nd:YAG) laser at 532 nm. At the power densities incident on-target, ranging from 8.6×109- 2.1×1013W cm-2, Ce4+ to Ce27+ ions gave rise to emission from ∆n = 0, 1 transitions to final states where n = 4. The spectra are dominated by an intense unresolved transition array (UTA) in the 8-10 nm region arising from n = 4 to n = 4 transitions. Two distinct components of this UTA are observed whose appearance is strongly dependent on laser power density, corresponding to transitions involving ions with open 4d and open 4f subshells, the latter at longer wavelengths. Multiple other transition arrays are identified and UTA statistics are given. The analysis was aided by atomic structure calculations and the use of a steady state collisional-radiative (CR) model.

Comparing the effects and safety of dorzolamide hydrochloride + timolol maleate versus brimonidine after neodymium-doped yttrium aluminium garnet laser capsulotomy posterior capsule opacification

Aim Posterior capsular opacification is treated using neodymium-doped yttrium aluminium garnet laser capsulotomy that leads to increased intraocular pressure. Here, we compare the effects of dorzolamide hydrochloride + timolol maleate versus brimonidine on intraocular pressure. We also investigate their side effects after neodymium-doped yttrium aluminium garnet laser capsulotomy. In these patients, there are no prior studies comparing the results of these two drugs. Materials Ninety patients with posterior capsule opacification contributed to the study. They received yttrium aluminium garnet laser capsulotomy. After yttrium aluminium garnet laser capsulotomy, they were randomized into three groups. Group 1 received dorzolamide hydrochloride + timolol maleate; Group 2 took brimonidine; and Group 3, the control group, took no drug. Group 1 took dorzolamide hydrochloride + timolol maleate eye drops 1 h before the procedure and on the third hour of the first day and two times per day between the second and the seventh days. Group 2 took brimonidine eye drops 1 h before the procedure and on the third hour of the first day, two times per day between the second and the seventh days. Results Brimonidine had a similar side effect profile to the fix combination. Intraocular pressure on the first ( p = 0.87) and third days ( p = 0.124) were similar in Group 1 (dorzolamide hydrochloride + timolol maleate), Group 2 (brimonidine) and the control group. The mean intraocular pressure value of the control group was significantly higher than Groups 1 and 2 because the anti-glaucomatous effects of the drugs become prominent on the seventh day ( p = 0.041). In Group 1 and Group 2, intraocular pressure was significantly lower than the control group on the seventh day ( p = 0.041). Stinging, itching, hyperemia and Tyndall rates were similar in Group 1, Group 2 and the control group. Watery eyes were less common in the brimonidine group than in the dorzolamide hydrochloride–timolol maleate and the control groups on the seventh day ( p = 0.02). Brimonidine also significantly lowered the chemosis rate on the third ( p = 0.04) and seventh ( p = 0.03) days. Conclusion We suggest that brimonidine and a combination of dorzolamide + timolol are similarly effective at reducing eye pressure for routine cases. In cases where intraocular pressure attacks might be at higher risk, using the dorzolamide + timolol combination would be more appropriate.

New reaction paths for advanced SiAlON/TiN composites

<p>This thesis demonstrates how selected ceramic additives, including titanium nitride (TiN), impact upon the “chemistry ↔ microstructure ↔ properties” relationship as it applies to composites in the generic Sialon-TiN composite field. Examination and optimisation of this feedback loop enables control of industrially important thermal, electrical and engineering properties of β-Sialon based ceramics. The effects of a range of additives on the nitridation and sintering of β-Sialon composite bodies have been studied and the chemical and mechanical properties of the sintered bodies have been measured. The additives can be divided in three groups: nitridation additives which improve the yield and the rate of the reaction; sintering aids; and additives that improve resistance to thermal shock. A suite of additives consisting of a mixture of calcium aluminate cement, yttrium aluminium garnet and boron nitride was found to deliver an optimum set of mechanical properties with a fracture toughness achieved of over 4 MPa.m-1/2. This thesis also reports a new reaction path for the formation of a β-Sialon/TiN composite by the reaction bonding of aluminium powder coated with nanosized titania. In this novel technique, the aluminium reacts under an inert atmosphere with titania to form alumina and a TixAly intermediate which is then nitrided to form aluminium nitride and titanium nitride. The addition of a suitable silicon phase enables the formation of a β-Sialon phase under nitrogen at high temperature. The TiN was added in the range 1 to 10 wt% (0.6 to 6 vol%). The effects of milling time on the aluminium powder particle size distribution and reactivity have been studied, with a minimum of two days milling time required to modify the particle shape and reduce melting coagulation during firing. Firing parameters have been optimised, using XRD and MAS-NMR to monitor the samples’ composition and SEM to observe their microstructure. The reduction of titania by aluminium was completed at 900 ºC for 4 hours in an argon atmosphere and the nitridation of the titanium aluminide at 1400 ºC for 3 hours in a nitrogen flow. The nitridation and sintering of the β-Sialon/TiN composite were both performed in nitrogen at 1400 ºC and 1600 ºC, respectively. A low level of addition of TiN (1 wt%) has shifted the composition toward the AlN corner of the Sialon behaviour diagram, forming α-Sialon and AlN polytypes. Other levels of addition in the studied range formed a dense β-Sialon/TiN composite. The TiN inclusions are found at the grain boundaries but are of insufficient volume fraction to form a continuous network in the Sialon matrix. Mechanical and electrical properties of the newly fabricated β-Sialon/TiN composites have been measured. These properties were generally improved by the highest levels of TiN addition: Young’s modulus (up to 210 GPa), hardness (up to 17.7 GPa), fracture toughness (up to 3.3 MPa.m-1/2) and compressive strength (up to 188 MPa). However the presence of TiN had no impact on the resistance to thermal shock and electrical conductivity of the β−Sialon. Finally, the oxidation process for β-Sialon/TiN composites has been observed by a combination of XRD, SEM and Ion Beam Analysis techniques. The results show early enrichment of yttrium and titanium in the first 0.1 μm of the samples’ surface; replacement of nitrogen by oxygen to form crystalline phases on the surface and in the glassy phase up to 1.5 μm deep; and, major crystalline and chemical changes in an outer layer of about 100 μm thickness at 1200 ºC. The partial depletion of SiO species from the external sample surface during sintering firing leaves this surface zone more vulnerable to oxidation than the protected body of the ceramic. The oxidation of TiN forms a TiO₂ skin which acts as a protection from further oxidation. The outcome of this research is a novel reaction path to fabricate new advanced Sialon composites and an improved understanding of the effect of a broad range of additives on the nitridation and sintering behaviour of β-Sialon and β-Sialon/TiN composites.</p>

New reaction paths for advanced SiAlON/TiN composites

<p>This thesis demonstrates how selected ceramic additives, including titanium nitride (TiN), impact upon the “chemistry ↔ microstructure ↔ properties” relationship as it applies to composites in the generic Sialon-TiN composite field. Examination and optimisation of this feedback loop enables control of industrially important thermal, electrical and engineering properties of β-Sialon based ceramics. The effects of a range of additives on the nitridation and sintering of β-Sialon composite bodies have been studied and the chemical and mechanical properties of the sintered bodies have been measured. The additives can be divided in three groups: nitridation additives which improve the yield and the rate of the reaction; sintering aids; and additives that improve resistance to thermal shock. A suite of additives consisting of a mixture of calcium aluminate cement, yttrium aluminium garnet and boron nitride was found to deliver an optimum set of mechanical properties with a fracture toughness achieved of over 4 MPa.m-1/2. This thesis also reports a new reaction path for the formation of a β-Sialon/TiN composite by the reaction bonding of aluminium powder coated with nanosized titania. In this novel technique, the aluminium reacts under an inert atmosphere with titania to form alumina and a TixAly intermediate which is then nitrided to form aluminium nitride and titanium nitride. The addition of a suitable silicon phase enables the formation of a β-Sialon phase under nitrogen at high temperature. The TiN was added in the range 1 to 10 wt% (0.6 to 6 vol%). The effects of milling time on the aluminium powder particle size distribution and reactivity have been studied, with a minimum of two days milling time required to modify the particle shape and reduce melting coagulation during firing. Firing parameters have been optimised, using XRD and MAS-NMR to monitor the samples’ composition and SEM to observe their microstructure. The reduction of titania by aluminium was completed at 900 ºC for 4 hours in an argon atmosphere and the nitridation of the titanium aluminide at 1400 ºC for 3 hours in a nitrogen flow. The nitridation and sintering of the β-Sialon/TiN composite were both performed in nitrogen at 1400 ºC and 1600 ºC, respectively. A low level of addition of TiN (1 wt%) has shifted the composition toward the AlN corner of the Sialon behaviour diagram, forming α-Sialon and AlN polytypes. Other levels of addition in the studied range formed a dense β-Sialon/TiN composite. The TiN inclusions are found at the grain boundaries but are of insufficient volume fraction to form a continuous network in the Sialon matrix. Mechanical and electrical properties of the newly fabricated β-Sialon/TiN composites have been measured. These properties were generally improved by the highest levels of TiN addition: Young’s modulus (up to 210 GPa), hardness (up to 17.7 GPa), fracture toughness (up to 3.3 MPa.m-1/2) and compressive strength (up to 188 MPa). However the presence of TiN had no impact on the resistance to thermal shock and electrical conductivity of the β−Sialon. Finally, the oxidation process for β-Sialon/TiN composites has been observed by a combination of XRD, SEM and Ion Beam Analysis techniques. The results show early enrichment of yttrium and titanium in the first 0.1 μm of the samples’ surface; replacement of nitrogen by oxygen to form crystalline phases on the surface and in the glassy phase up to 1.5 μm deep; and, major crystalline and chemical changes in an outer layer of about 100 μm thickness at 1200 ºC. The partial depletion of SiO species from the external sample surface during sintering firing leaves this surface zone more vulnerable to oxidation than the protected body of the ceramic. The oxidation of TiN forms a TiO₂ skin which acts as a protection from further oxidation. The outcome of this research is a novel reaction path to fabricate new advanced Sialon composites and an improved understanding of the effect of a broad range of additives on the nitridation and sintering behaviour of β-Sialon and β-Sialon/TiN composites.</p>

Direct-write piezoelectric coating transducers in combination with discrete ceramic transducer and laser pulse excitation for ultrasonic impact damage detection on composite plates

In this work, direct-write piezoelectric transducers (DWTs) were made by spraying piezoelectric poly(vinylidene fluoride-co-trifluoroethylene) coating with comb-shaped electrodes on carbon fibre reinforced polymer (CFRP) plates for drop weight impact damage detection. Their ability and performance were investigated and compared to discrete piezoelectric lead zirconate titanate (PZT) ceramic transducers that were adhesively bonded on the same CFRP plate. Guided wave signals were acquired with different combinations of actuator-sensor involving DWT, PZT and laser ultrasonic excitation, in pitch-catch configuration. DWTs allowed consistency and simplified signal interpretation due to an effective mode selection (A0 or S0 mode) with wavelengths of 10 and 12 mm. PZTs generated stronger but much more complex signals and mode selection with a larger wavelength (20 mm). The configuration with PZT as actuator and DWT as receiver showed the highest signal amplitude changes of A0 or S0 mode, allowing efficient detection of damage introduced by a 31 J impact. Further ultrasonic B- and C-scans revealed a 27 mm long crack on the plate’s backside developed in addition to internal cracks and delaminations of about 34 mm in length. For realizing contactless ultrasound excitation, a neodymium-doped yttrium aluminium garnet laser (wavelength of 1064 nm, 5.4 ns pulses) was used to replace the surface-mounted brittle PZT. The combination of the broadband laser excitation with the DWTs as sensors achieved more reliable damage detection than equivalent PZTs, attributed to DWT’s effective single mode selection. In addition to reduced weight, the polymeric coated DWTs allow large area implementation (scaling up), even on curved surfaces due to their flexibility and conformability, in contrast to adhesively bonded discrete transducers.

Novel Ideas for Thermal Management of Filament LED Light Bulbs

The thermal conditions of a filament LED retro light bulb has been investigated. In such light bulbs, LEDs are mounted on filaments which have glass or sapphire substrate and are surrounded by yttrium-aluminium-garnet (YAG). Heat management is challenging as a heatsink cannot normally be used. Instead, heat removal is enabled by using helium as the filling gas. As this provides less efficient heat removal than using a heatsink attached directly to an LED module, LEDs operate in filament LED bulbs typically at rather high temperatures. In this paper thermal performance of a typical filament LED bulb has been studied. LED temperatures and gas flows inside the bulb has been resolved for cases of different orientations of the bulb. Thermal conditions for different filling gases have been resolved. All this has been done using finite element method (FEM) simulations. The main target of this study has been to find out novel solutions for thermal management of filament LED bulbs. Two heat removal solutions have been studied, namely the use of an internal heatsink and an internal piezoelectric oscillating cantilever fan. The results show that solutions can indeed reduce temperature of LED chips and increase the lifespan of the LED bulb.