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Petrovic S., Bundaleski N., Perusko D., Radovic M., Kovac J., Mitric M., Gakovic B., Rakocevic Z


Petrovic S., Bundaleski N., Perusko D., Radovic M., Kovac J., Mitric M., Gakovic B., Rakocevic Z.



Surface analysis of the nanostructured W-Ti thin film deposited on silicon



2007, Applied Surface Science, (12) 5196-5202



1. Jiao H, Wang QX, Fan ZK. A study on the nanostructured W-ti thin films deposited on si. Synthesis and Reactivity in Inorganic, Metal-Organic and Nano-Metal Chemistry. 2012;42(5):671-7.

2. Jie X, Liang S, Wang Q, Zhao X, Fan Z, Wang X. The effect of sintering temperature on mechanical and electrical properties of a W-10Ti alloy prepared by hot press sintering. Journal of Materials Engineering and Performance. 2012;21(1):101-4.

3. Petrović S, Peruško D, Milovanović D, Siketić Z, Jakšić M, Kovač J, et al. Chemical and structural modifications of laser treated WTi surfaces at different ambient conditions. Appl Phy B. 2011;105(3):593-7.

4. Wang Y-, Song J, Jia D-, Zhou Y. Effect of sintering temperature on microstructure and hardness of W-10Ti alloy. Cailiao Rechuli Xuebao/Transactions of Materials and Heat Treatment. 2011;32(8):37,40+46.

5. Yao L-, Tian L-, Wang S, Li L, Xu R, Fang X. In: Preparation and characterizaion of CTAB-templated large pore silica nano-composite films. Proceedings of SPIE - the international society for optical engineering; ; 2011.

6. Petrović S, Peruško D, Milovanović D, Kovač J, Čekada M, Panjan P, et al. Effects of the pulse duration in laser modification of nano-sized WTi film on si substrate. Journal of Optics. 2010;12(7).

7. Qingxiang W, Shuhua L, Xianhui W, Zhikang F. Diffusion barrier performance of amorphous WTiN films in cu metallization. Vacuum. 2010;84(11):1270-4.

8. Wang QX, Fan ZK, Liang SH. Thermal stability of nanocrystalline W-ti diffusion barrier thin films. Science China Technological Sciences. 2010;53(4):1049-55.

9. Petrović S, Gaković B, Peruško D, Desai T, Batani D, Čekada M, et al. Picosecond laser ablation of nano-sized WTi thin film. Laser Physics. 2009;19(8):1844-9.

10. Allam NK, Grimes CA. Effect of cathode material on the morphology and photoelectrochemical properties of vertically oriented TiO2 nanotube arrays. Solar Energy Mater Solar Cells. 2008;92(11):1468-75.

11. Bundaleski N, Petrović S, Peruško D, Kovač J, Zalar A. Composition of the sputter deposited W-ti thin films. Appl Surf Sci. 2008;254(20):6390-4.

12. Bathe SR, Patil PS. Titanium doping effects in electrochromic pulsed spray pyrolysed WO3 thin films. Solid State Ionics. 2008;179(9-10):314-23.

13. Petrović S, Gaković B, Peruško D, Trtica M, Radak B, Panjan P, et al. Surface modification of a WTi thin film on si substrate by nanosecond laser pulses. Appl Surf Sci. 2008;254(13):4013-7.

Mitric M., Kremenovic A., Dimitrijevic R., Rodic D.



Structure and microstructure of SmxY2-xO3



1997, Solid State Ionics, (PART 1) 495-501



1. Zhu H, Ma Y, Yang H, Zhu P, Du J, Ji C, et al. Ultrastable structure and luminescence properties of Y 2O 3 nanotubes. Solid State Commun. 2010;150(27-28):1208-12.

2. Bharathy M, Fox AH, Mugavero SJ, zur Loye H-. Crystal growth of inter-lanthanide LaLn′O3 (ln′ = Y, ho-lu) perovskites from hydroxide fluxes. Solid State Sciences. 2009;11(3):651-4.

3. Tang Y, Dai S, Fang Y. Electron structure and photoluminescence behavior of ti 0.09Y 1.91O 2S. J Appl Phys. 2009;105(3).

4. Mao Y, Bargar J, Toney M, Chang JP. Correlation between luminescent properties and local coordination environment for erbium dopant in yttrium oxide nanotubes. J Appl Phys. 2008;103(9).

5. Heiba ZK, Arda L. X-ray diffraction analysis of powder and thin film of (gd 1-xyx)2O3 prepared by sol-gel process. Crystal Research and Technology. 2008;43(3):282-8.

6. Fowlkes JD, Fitz-Gerald JM, Rack PD. Ultraviolet emitting (Y1-xGdx)2O3 - δ thin films deposited by radio frequency magnetron sputtering; structure-property-thin film processing relationships. Thin Solid Films. 2007;515(7-8):3488-98.

7. de Biasi RS, Grillo MLN. Electron spin resonance of diluted solid solutions of MnO2 in Y2O3. Journal of Physics and Chemistry of Solids. 2006;67(11):2382-5.

8. Van TT, Bargar JR, Chang JP. Er coordination in y 2O 3 thin films studied by extended x-ray absorption fine structure. J Appl Phys. 2006;100(2).

9. De Biasi RS, Grillo MLN. Electron spin resonance of chromia-yttria solid solutions. Journal of Physics and Chemistry of Solids. 2005;66(10):1806-9.

10. Heiba ZK, Arda L, Hascicek YS. Structure and microstructure characterization of the mixed sesquioxides (Gd1-xYbx)2O3 and (gd 1-xHox)2O3 prepared by sol-gel process. Journal of Applied Crystallography. 2005;38(2):306-10.

11. Fowlkes JD, Rack PD, Bansal R, Fitz-Gerald JM. In: Cathodoluminescence study of gadolinium-doped yttrium oxide thin films deposited by radio-frequency magnetron sputtering. Materials research society symposium - proceedings; ; 2003. p. 419-24.

12. Polizzi S, Fagherazzi G, Battagliarin M, Bettinelli M, Speghini A. Fractal aggregates of lanthanide-doped Y2O3 nanoparticles obtained by propellant synthesis. J Mater Res. 2001;16(1):146-54.

13. Allieri B, Depero LE, Marino A, Sangaletti L, Caporaso L, Speghini A, et al. Growth and microstructural analysis of nanosized Y2O3 doped with rare-earths. Mater Chem Phys. 2000;66(2):164-71.

Stanic V., Dimitrijevic S., Antic-Stankovic J., Mitric M., Jokic B., Plecas I.B., Raicevic S.



Synthesis, characterization and antimicrobial activity of copper and zinc-doped hydroxyapatite nanopowders



2010, Applied Surface Science, (20) 6083-6089



1. Pham Minh D, Lyczko N, Sebei H, Nzihou A, Sharrock P. Synthesis of calcium hydroxyapatite from calcium carbonate and different orthophosphate sources: A comparative study. Materials Science and Engineering B: Solid-State Materials for Advanced Technology. 2012;177(13):1080-9.

2. Pham Minh D, Sebei H, Nzihou A, Sharrock P. Apatitic calcium phosphates: Synthesis, characterization and reactivity in the removal of lead(II) from aqueous solution. Chem Eng J. 2012;198-199:180-90.

3. Bir F, Khireddine H, Touati A, Sidane D, Yala S, Oudadesse H. Electrochemical depositions of fluorohydroxyapatite doped by cu 2+, zn 2+, ag + on stainless steel substrates. Appl Surf Sci. 2012;258(18):7021-30.

4. Gopi D, Nithiya S, Shinyjoy E, Kavitha L. Spectroscopic investigation on formation and growth of mineralized nanohydroxyapatite for bone tissue engineering applications. Spectrochimica Acta - Part A: Molecular and Biomolecular Spectroscopy. 2012;92:194-200.

5. Llorens A, Lloret E, Picouet PA, Trbojevich R, Fernandez A. Metallic-based micro and nanocomposites in food contact materials and active food packaging. Trends in Food Science and Technology. 2012;24(1):19-29.

6. Adzila S, Murad MC, Sopyan I. Doping metal into calcium phosphate phase for better performance of bone implant materials. Recent Patents on Materials Science. 2012;5(1):18-47.

7. Tank KP, Sharma P, Kanchan DK, Joshi MJ. FTIR, powder XRD, TEM and dielectric studies of pure and zinc doped nano-hydroxyapatite. Crystal Research and Technology. 2011;46(12):1309-16.

8. Rabadjieva D, Tepavitcharova S, Gergulova R, Sezanova K, Titorenkova R, Petrov O, et al. Mg- and zn-modified calcium phosphates prepared by biomimetic precipitation and subsequent treatment at high temperature. J Mater Sci Mater Med. 2011;22(10):2187-96.

9. Li C, Liang J, Niu J, Liu S, Li G, Bai J, et al. Characterization of hollow hydroxyapatite/copper microspheres prepared from the reduction of copper-modified hydroxyapatite by glucose. J Electron Microsc. 2011;60(5):301-5.

10. Cady NC, Behnke JL, Strickland AD. Copper-based nanostructured coatings on natural cellulose: Nanocomposites exhibiting rapid and efficient inhibition of a multi-drug resistant wound pathogen, A. baumannii, and mammalian cell biocompatibility in vitro. Advanced Functional Materials. 2011;21(13):2506-14.

11. Sheikh FA, Kanjwal MA, Saran S, Chung W-, Kim H. Polyurethane nanofibers containing copper nanoparticles as future materials. Appl Surf Sci. 2011;257(7):3020-6.

12. Vasant SR, Joshi MJ. Synthesis and characterization of pure and zinc doped calcium pyrophosphate dihydrate nanoparticles. EPJ Applied Physics. 2011;53(1).

Markovic S., Mitric M., Starcevic G., Uskokovic D.



Ultrasonic de-agglomeration of barium titanate powder



2008, Ultrasonics Sonochemistry, (1) 16-20



1. Ohno T, Numakura K, Suzuki H, Matsuda T. Preparation of the BaTiO 3-SiO 2 hybrid particles for the catalyst of methane steam reforming process. Mater Chem Phys. 2012;134(1):514-7.

2. Guillemin J-, Schaer E, Marchal P, Lemaître C, Nonnet H, Ledieu A. A mass conservative approach to model the ultrasonic de-agglomeration of ZnO nanoparticle suspension in water. Powder Technol. 2012;219:59-64.

3. Méndez M, Cesteros Y, Marsal LF, Martínez-Ferrero E, Salagre P, Formentín P, et al. Polymer composite P3HT:Eu 3+ doped la 2O 3 nanoparticles as a down-converter material to improve the solar spectrum energy. Optical Materials. 2011;33(7):1120-3.

4. Kim J-, Chang S-, Kim K-, Chung M-, Kim W-. Acoustic influence on aggregation and agglomeration of crystals in reaction crystallization of cerium carbonate. Colloids Surf Physicochem Eng Aspects. 2011;375(1-3):193-9.

5. Wagterveld RM, Boels L, Mayer MJ, Witkamp GJ. Visualization of acoustic cavitation effects on suspended calcite crystals. Ultrason Sonochem. 2011;18(1):216-25.

6. Méndez M, Carvajal JJ, Cesteros Y, Marsal LF, Martínez-Ferrero E, Salagre P, et al. In: Exploring the possibilities of Eu3+:La2O3 nanoparticles as an approach for down conversion processes in solar energy systems. Proceedings of SPIE - the international society for optical engineering; ; 2010.

7. Majhi A, Pugazhenthi G, Shukla A. Comparative study of ultrasound stimulation and conventional heating methods on the preparation of nanosized γ-Al2O3. Industrial and Engineering Chemistry Research. 2010;49(10):4710-9.

8. Ignjatović NL, Ninkov P, Sabetrasekh R, Uskoković DP. A novel nano drug delivery system based on tigecycline-loaded calciumphosphate coated with poly-DL-lactide-co-glycolide. J Mater Sci Mater Med. 2010;21(1):231-9.

9. Peng Y, Chen Q, Liu S. Preparation of barium titanate nanopowder through thermal decomposition of peroxide precursor and its formation mechanism. Chinese Journal of Chemistry. 2009;27(11):2291-5.

10. Marković S, Miljković M, Jovalekić C, Mentus S, Uskoković D. Densification, microstructure, and electrical properties of BaTiO 3 (BT) ceramics prepared from ultrasonically de-agglomerated BT powders. Mater Manuf Process. 2009;24(10-11):1114-23.

11. Liang Y, Ozawa M, Krueger A. A general procedure to functionalize agglomerating nanoparticles demonstrated on nanodiamond. ACS Nano. 2009;3(8):2288-96.

12. Sydorchuk VV, Zazhigalov VA, Khalameida SV, Wieczorek-Ciurowa K, Skubiszewska-Zieba J, Leboda R. Investigation of physicochemical transformation at mechanochemical, hydrothermal and microwave treatment of barium titanyloxalate. J Alloys Compounds. 2009;482(1-2):229-34.

Antic B., Goya G.F., Rechenberg H.R., Kusigerski V., Jovic N., Mitric M.



Spin glass formation in Li-substituted Co 2TiO 4 spinel



2004, Journal of Physics Condensed Matter, (4) 651-659



1. Ahuja BL, Dashora A, Heda NL, Tiwari S, Rajeevan NE, Itou M, et al. Reversal of orbital magnetic moment on substitution of bi in multiferroic co 2 MnO 4: A magnetic compton scattering study. Appl Phys Lett. 2010;97(21).

2. Xu Q, Zhou S, Wu D, Uhlarz M, Tang YK, Potzger K, et al. Cluster spin glass behavior in bi (fe 0.95 co 0.05) O 3. J Appl Phys. 2010;107(9).

3. Rajeevan NE, Kumar R, Shukla DK, Thakur P, Brookes NB, Chae KH, et al. Bi-substitution-induced magnetic moment distribution in spinel bi xCo 2-xMnO 4 multiferroic. Journal of Physics Condensed Matter. 2009;21(40).

4. Neves AIS, Dias JC, Vieira BJC, Santos IC, Castelo Branco MB, Pereira LCJ, et al. A new hybrid material exhibiting room temperature spin-crossover and ferromagnetic cluster-glass behavior. CrystEngComm. 2009;11(10):2160-8.

5. Rajeevan NE, Kumar R, Shukla DK, Pradyumnan PP, Arora SK, Shvets IV. Structural, electrical and magnetic properties of bi-substituted co 2MnO 4. Materials Science and Engineering B: Solid-State Materials for Advanced Technology. 2009;163(1):48-56.

6. Rajeevan NE, Kumar R, Kumar S, Shukla DK, Pradyumnan PP, Arora SK, et al. In: Multiferroic properties of bi-substituted co 2MnO 4. AIP conference proceedings; ; 2008. p. 124-6.

7. Akamatsu H, Tanaka K, Fujita K, Murai S. Magnetic phase transitions in Fe2O3-bi 2O3-B2O3 glasses. Journal of Physics Condensed Matter. 2008;20(23).

8. Gómez-Polo C, Pérez-Landazabal JI, Recarte V, Gil A, Korili SA, Trujillano R, et al. Magnetic properties of nickel and cobalt catalysts supported on nanoporous oxides. Journal of Nanoscience and Nanotechnology. 2008;8(6):2905-11.

9. Blanusa J, Antic B, Kremenovic A, Nikolic AS, Mazzerolles L, Mentus S, et al. Particle size effect on néel temperature in Er2O3 nanopowder synthesized by thermolysis of 2, 4-pentadione complex. Solid State Commun. 2007;144(7-8):310-4.

10. Gómez-Polo C, Gil A, Korili SA, Pérez-Landázabal JI, Recarte V, Trujillano R, et al. Effect of the metal support interactions on the physicochemical and magnetic properties of ni catalysts. J Magn Magn Mater. 2007;316(2 SPEC. ISS.):e783-6.

11. Reeves N, Pasero D, West AR. Order-disorder transition in the complex lithium spinel Li2CoTi3O8. Journal of Solid State Chemistry. 2007;180(6):1894-901.

12. Belo D, Figueira MJ, Nunes JPM, Santos IC, Pereira LC, Gama V, et al. Magnetic properties of RBzPy[ni(α-tpdt) 2] (R = H, br, F): Effects of cis-trans disorder. Journal of Materials Chemistry. 2006;16(26):2746-56.

Radjenovic B., Radmilovic-Radjenovic M., Mitric M.



Nonconvex Hamiltonians in three dimensional level set simulations of the wet etching of silicon



2006, Applied Physics Letters, (21)



1. Goslvez MA, Ferrando N, Xing Y, Pal P, Sato K, Cerdá J, et al. Simulating anisotropic etching of silicon in any etchant: Evolutionary algorithm for the calibration of the continuous cellular automaton. J Micromech Microengineering. 2011;21(6).

2. Radjenović B, Radmilović-Radjenović M. Top down nano technologies in surface modification of materials. Central European Journal of Physics. 2011;9(2):265-75.

3. Radjenović B, Radmilović-Radjenović M. Three-dimensional simulations of the anisotropic etching profile evolution for producing nanoscale devices. Acta Physica Polonica A. 2011;119(3):447-50.

4. Ferrando N, Gosálvez MA, Cerdá J, Gadea R, Sato K. Faster and exact implementation of the continuous cellular automaton for anisotropic etching simulations. J Micromech Microengineering. 2011;21(2).

5. Radjenović B, Radmilović-Radjenović M. Application of the level set method in three-dimensional simulations of the etching profile evolution for producing nano-scale devices. Optoelectronics and Advanced Materials, Rapid Communications. 2010;4(8):1193-5.

6. Radmilović-Radjenović M, Radjenović B. Determination of the etching rate from the silicon symmetry properties by extension of the level set method. International Review of Electrical Engineering. 2010;5(3):1045-52.

7. Gosálvez MA, Xing Y, Sato K, Nieminen RM. Discrete and continuous cellular automata for the simulation of propagating surfaces. Sens Actuators A Phys. 2009;155(1):98-112.

8. Zhou Z-, Huang Q-, Li W-. Modeling and simulations of anisotropic etching of silicon in alkaline solutions with experimental verification. J Electrochem Soc. 2009;156(2):F29-37.

9. Petrović ZLJ, Radjenović B, Radmilović-Radjenović M. In: Top down nano technologies in production of integrated circuits and surface modification of materials. "2008 26th international conference on microelectronics, proceedings, MIEL 2008"; ; 2008. p. 19-24.

10. Xing Y, Gosálvez MA, Sato K. Step flow-based cellular automaton for the simulation of anisotropic etching of complex MEMS structures. New Journal of Physics. 2007;9.

11. Zhou Z-, Huang Q-, Li W-. An atomic level model for silicon anisotropic etching processes: Cellular automaton simulation and experimental verification. Appl Phys Lett. 2007;91(17).
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