G. Bodurov scite author profile

Laser-induced breakdown spectroscopy (LIBS) enables the direct measurement of cell electrolyte concentrations. The utility of LIBS spectra in biomarker studies is limited because these studies rarely consider basic physical principles. The aim of this study was to test the suitability of LIBS spectra as an analytical method for biomarker assays and to evaluate the composition of electrolyte elements in human biomaterial. LIBS as an analytical method was evaluated by establishing KCl calibration curves to demonstrate linearity, by the correct identification of emission lines with corresponding reference spectra, and by the feasibility to use LIBS in human biomaterial, analyzing striated muscle tissues from the oral regions of two patients. Lorentzian peak fit and peak area calculations resulted in better linearity and reduced shot-to-shot variance. Correct quantitative measurement allowed for differentiation of human biomaterial between patients, and determination of the concentration ratios of main electrolytes within human tissue. The clinical significance of LIBS spectra should be evaluated using peak area rather than peak intensity. LIBS might be a promising tool for analyzing a small group of living cells. Due to linearity, specificity and robustness of the proposed analytical method, LIBS could be a component of future biomarker studies.

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Technologies for deposition of transition metal oxide thin films: application as functional layers in “Smart windows” and photocatalytic systems

Gesheva

Ivanova

Bodurov

et al. 2016

J. Phys.: Conf. Ser.

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Abstract. "Smart windows" are envisaged for future low-energy, high-efficient architectural buildings, as well as for the car industry. By switching from coloured to fully bleached state, these windows regulate the energy of solar flux entering the interior. Functional layers in these devices are the transition metals oxides. The materials (transitional metal oxides) used in smart windows can be also applied as photoelectrodes in water splitting photocells for hydrogen production or as photocatalytic materials for self-cleaning surfaces, waste water treatment and pollution removal. Solar energy utilization is recently in the main scope of numerous world research laboratories and energy organizations, working on protection against conventional fuel exhaustion. The paper presents results from research on transition metal oxide thin films, fabricated by different methods -atomic layer deposition, atmospheric pressure chemical vapour deposition, physical vapour deposition, and wet chemical methods, suitable for flowthrough production process. The lower price of the chemical deposition processes is especially important when the method is related to large-scale glazing applications. Conclusions are derived about which processes are recently considered as most prospective, related to electrochromic materials and devices manufacturing. Transition metal oxidesTransition metal oxides (TMO) are claimed to be one of the most interesting classes of solids, exhibiting varieties of properties, structures and applications [1]. Their properties are determined by the unique nature of their outer d-electrons. Transition-metal oxides can be insulators, semiconductors, metals, or undergo semiconductor-metal transitions. Transition metal oxides possess unusual and useful electronic, optical and magnetic properties. Many of these properties strongly depend on materials defects like vacancies, dislocations, stacking faults and grain boundaries [2].

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Optical, structural and electrochromic properties of sputter- deposited W-Mo oxide thin films

Gesheva

Arvizu

Bodurov

et al. 2016

J. Phys.: Conf. Ser.

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APCVD Transition Metal Oxides – Functional Layers in "Smart windows"

Gesheva

Ivanova

Bodurov

2014

J. Phys.: Conf. Ser.

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Thin Film Optical Coatings of Vanadium Oxide and Mixed Tungsten/Vanadium Oxide Deposited by APCVD Employing Precursors of Vanadyl Acetylacetonate and a Mixture with Tungsten Hexacarbonyl

et al. 2013

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Technology and Application of Transition Metal Oxide of W-V-O as Functional Layers and NiO Thin Films as Counter Electrode Material in Electrochromic “Smart Windows”

Bodurov¹,

Ivanova²,

Gesheva³

2013

Physics Procedia

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G. Bodurov

Transition metal oxide films: Technology and “Smart Windows” electrochromic device performance

Investigation of electrodeposited NiO films as electrochromic material for counter electrodes in “Smart Windows”

Evaluation of electrolyte element composition in human tissue by laser-induced breakdown spectroscopy (LIBS)

Technologies for deposition of transition metal oxide thin films: application as functional layers in “Smart windows” and photocatalytic systems

Optical, structural and electrochromic properties of sputter- deposited W-Mo oxide thin films

APCVD Transition Metal Oxides – Functional Layers in "Smart windows"

Thin Film Optical Coatings of Vanadium Oxide and Mixed Tungsten/Vanadium Oxide Deposited by APCVD Employing Precursors of Vanadyl Acetylacetonate and a Mixture with Tungsten Hexacarbonyl

Technology and Application of Transition Metal Oxide of W-V-O as Functional Layers and NiO Thin Films as Counter Electrode Material in Electrochromic “Smart Windows”

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