Lutz Kirste scite author profile

Photonic active diamond nanoparticles attract increasing attention from a wide community for applications in drug delivery and monitoring experiments as they do not bleach or blink over extended periods of time. To be utilized, the size of these diamond nanoparticles needs to be around 4 nm. Cluster formation is therefore the major problem. In this paper we introduce a new technique to modify the surface of particles with hydrogen, which prevents cluster formation in buffer solution and which is a perfect starting condition for chemical surface modifications. By annealing aggregated nanodiamond powder in hydrogen gas, the large (>100 nm) aggregates are broken down into their core ( approximately 4 nm) particles. Dispersion of these particles into water via high power ultrasound and high speed centrifugation, results in a monodisperse nanodiamond colloid, with exceptional long time stability in a wide range of pH, and with high positive zeta potential (>60 mV). The large change in zeta potential resulting from this gas treatment demonstrates that nanodiamond particle surfaces are able to react with molecular hydrogen at relatively low temperatures, a phenomenon not witnessed with larger (20 nm) diamond particles or bulk diamond surfaces.

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Chemically orderedAlxGa1−xNalloys: Spontaneous formation of natural quantum wells

Albrecht

Lymperakis

Neugebauer

et al. 2005

Phys. Rev. B

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We combine transmission electron microscopy, high-resolution x-ray diffraction, cathodoluminescence, and photoluminescence experiments with first-principles calculations to study the formation, thermodynamic stability, structural, and optical properties of chemically ordered Al x Ga 1−x N alloys ͑0 Ͻ x Ͻ 1͒. Our results reveal that group-III-nitride surfaces exhibit chemically highly sensitive adsorption sites at step edges and that these sites can be used to kinetically engineer chemically ordered Al x Ga 1−x N alloys. The ordered alloys have unique properties: ͑i͒ the band gap is redshifted up to 110 meV with respect to the disordered alloy of the same composition and ͑ii͒ the band gap reduction is caused by localization of the band edge wave functions in the GaN layer. Ordered Al x Ga 1−x N thus can be seen as a natural quantum well structure where electrons and holes are localized and confined in monolayer GaN quantum wells.

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Preparation of deep UV transparent AlN substrates with high structural perfection for optoelectronic devices

et al. 2016

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In this paper, the optimal growth conditions during the physical vapour transport of bulk AlN crystals are evaluated with regard to significantly increased deep UV transparency, while maintaining the high structural quality of the AlN crystals which are grown on N-polar c-facets. We show that carbon concentration [C], oxygen concentration [O], and the ratio between both concentrations [C]/[O] have a significant influence on the deep UV transparency. At 3[C] < [O] with [C] + [O] < 1019 cm−3, deep UV transparent AlN single crystals with absorption coefficients at around 265 nm (α265nm) smaller than 15 cm−1 can be prepared. These conditions can be achieved in the N-polar grown volume parts of the AlN crystals using growth temperatures in the range of TG = 2030–2050 °C and tungsten and tantalum carbide as getter materials for carbon and oxygen, respectively. Deep UV transparent AlN substrates (α265nm < 30 cm−1) ≥10 mm in diameter and of high crystalline perfection (rocking curve FWHM < 15 arcsec) are shown for the first time

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Densification of Thin Aluminum Oxide Films by Thermal Treatments

Cimalla

Baeumler²,

Kirste³

et al. 2014

MSA

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Thin AlO x films were grown on 4H-SiC by plasma-assisted atomic layer deposition (ALD) and plasma assisted electron-beam evaporation at 300˚C. After deposition, the films were annealed in nitrogen at temperatures between 500˚C and 1050˚C. The films were analyzed by X-ray reflectivity (XRR) and atomic force microscopy (AFM) in order to determine film thickness, surface roughness and density of the AlO x layer. No differences were found in the behavior of AlO x films upon annealing for the two different employed deposition techniques. Annealing results in film densification, which is most prominent above the crystallization temperature (800˚C). In addition to the increasing density, a mass loss of ~5% was determined and attributed to the presence of aluminum oxyhydroxide in as deposited films. All changes in film properties after high temperature annealing appear to be independent of the deposition technique.

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The role of surface electron accumulation and bulk doping for gas-sensing explored with single-crystalline In2O3 thin films

Rombach

Papadogianni

Mischo

et al. 2016

Sensors and Actuators B: Chemical

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Lutz Kirste

Size-Dependent Reactivity of Diamond Nanoparticles

Chemically orderedAlxGa1−xNalloys: Spontaneous formation of natural quantum wells

Preparation of deep UV transparent AlN substrates with high structural perfection for optoelectronic devices

Densification of Thin Aluminum Oxide Films by Thermal Treatments

The role of surface electron accumulation and bulk doping for gas-sensing explored with single-crystalline In2O3 thin films

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