Ultrasonic synthesis of hydroxyapatite in non-cavitation and cavitation modes

•Interaction of low intensity ultrasound with liquid jet creates vortices.•The vortices serve as a template for the formation of hydroxyapatite crystals.•Ultrasound in non-cavitation mode makes smaller particles than in cavitation mode. The size control of materials is of great importance in researc...

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Veröffentlicht in:	Ultrasonics sonochemistry 2018-06, Vol.44, p.390-397
Hauptverfasser:	Nikolaev, A.L., Gopin, A.V., Severin, A.V., Rudin, V.N., Mironov, M.A., Dezhkunov, N.V.
Format:	Artikel
Sprache:	eng
Schlagworte:	Controlled synthesis of nanoparticles Crystal growth Hydroxyapatite crystallization Sonocrystallization Ultrasonic field
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container_title	Ultrasonics sonochemistry
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creator	Nikolaev, A.L. Gopin, A.V. Severin, A.V. Rudin, V.N. Mironov, M.A. Dezhkunov, N.V.
description	•Interaction of low intensity ultrasound with liquid jet creates vortices.•The vortices serve as a template for the formation of hydroxyapatite crystals.•Ultrasound in non-cavitation mode makes smaller particles than in cavitation mode. The size control of materials is of great importance in research and technology because materials of different size and shape have different properties and applications. This paper focuses on the synthesis of hydroxyapatite in ultrasound fields of different frequencies and intensities with the aim to find the conditions which allow control of the particles size. The results are evaluated by X-ray diffraction, Transmission Electron Microscopy, morphological and sedimentation analyses. It is shown that the hydroxyapatite particles synthesized at low intensity non-cavitation regime of ultrasound have smaller size than those prepared at high intensity cavitation regime. The explanation of observed results is based on the idea of formation of vortices at the interface between phosphoric acid and calcium hydroxide solution where the nucleation of hydroxyapatite particles is taken place. Smaller vortices formed at high frequency non-cavitation ultrasound regime provide smaller nucleation sites and smaller resulting particles, compared to vortices and particles obtained without ultrasound. Discovered method has a potential of industrial application of ultrasound for the controlled synthesis of nanoparticles.
doi_str_mv	10.1016/j.ultsonch.2018.02.047
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The size control of materials is of great importance in research and technology because materials of different size and shape have different properties and applications. This paper focuses on the synthesis of hydroxyapatite in ultrasound fields of different frequencies and intensities with the aim to find the conditions which allow control of the particles size. The results are evaluated by X-ray diffraction, Transmission Electron Microscopy, morphological and sedimentation analyses. It is shown that the hydroxyapatite particles synthesized at low intensity non-cavitation regime of ultrasound have smaller size than those prepared at high intensity cavitation regime. The explanation of observed results is based on the idea of formation of vortices at the interface between phosphoric acid and calcium hydroxide solution where the nucleation of hydroxyapatite particles is taken place. Smaller vortices formed at high frequency non-cavitation ultrasound regime provide smaller nucleation sites and smaller resulting particles, compared to vortices and particles obtained without ultrasound. Discovered method has a potential of industrial application of ultrasound for the controlled synthesis of nanoparticles.</description><identifier>ISSN: 1350-4177</identifier><identifier>EISSN: 1873-2828</identifier><identifier>DOI: 10.1016/j.ultsonch.2018.02.047</identifier><identifier>PMID: 29680625</identifier><language>eng</language><publisher>Netherlands: Elsevier B.V</publisher><subject>Controlled synthesis of nanoparticles ; Crystal growth ; Hydroxyapatite crystallization ; Sonocrystallization ; Ultrasonic field</subject><ispartof>Ultrasonics sonochemistry, 2018-06, Vol.44, p.390-397</ispartof><rights>2018 Elsevier B.V.</rights><rights>Copyright © 2018 Elsevier B.V. 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The size control of materials is of great importance in research and technology because materials of different size and shape have different properties and applications. This paper focuses on the synthesis of hydroxyapatite in ultrasound fields of different frequencies and intensities with the aim to find the conditions which allow control of the particles size. The results are evaluated by X-ray diffraction, Transmission Electron Microscopy, morphological and sedimentation analyses. It is shown that the hydroxyapatite particles synthesized at low intensity non-cavitation regime of ultrasound have smaller size than those prepared at high intensity cavitation regime. The explanation of observed results is based on the idea of formation of vortices at the interface between phosphoric acid and calcium hydroxide solution where the nucleation of hydroxyapatite particles is taken place. Smaller vortices formed at high frequency non-cavitation ultrasound regime provide smaller nucleation sites and smaller resulting particles, compared to vortices and particles obtained without ultrasound. 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The size control of materials is of great importance in research and technology because materials of different size and shape have different properties and applications. This paper focuses on the synthesis of hydroxyapatite in ultrasound fields of different frequencies and intensities with the aim to find the conditions which allow control of the particles size. The results are evaluated by X-ray diffraction, Transmission Electron Microscopy, morphological and sedimentation analyses. It is shown that the hydroxyapatite particles synthesized at low intensity non-cavitation regime of ultrasound have smaller size than those prepared at high intensity cavitation regime. The explanation of observed results is based on the idea of formation of vortices at the interface between phosphoric acid and calcium hydroxide solution where the nucleation of hydroxyapatite particles is taken place. 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subjects	Controlled synthesis of nanoparticles Crystal growth Hydroxyapatite crystallization Sonocrystallization Ultrasonic field
title	Ultrasonic synthesis of hydroxyapatite in non-cavitation and cavitation modes
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