Repo Dosen ULM

Turnitin Room Temperature Synthesis of Magnetite Particles by an Oil Membrane Layer-Assisted Reverse Co-Precipitation Approach

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dc.contributor.author Santoso, Uripto Trisno
dc.contributor.author Abdullah, Abdullah
dc.contributor.author Mujiyanti, Dwi Rasy
dc.contributor.author Ariyani, Dahlena
dc.contributor.author Waskito, Joyo
dc.date.accessioned 2021-08-18T01:50:04Z
dc.date.available 2021-08-18T01:50:04Z
dc.date.issued 2021-04
dc.identifier.issn print 1022-6680
dc.identifier.uri https://repo-dosen.ulm.ac.id//handle/123456789/20897
dc.description.abstract Reverse co-precipitation (RCP) in ambient atmosphere is one of the strategies to produce magnetite nanoparticles in a rapid, simple, and cost-effective synthesis route without applying temperature surfactants or inert gases. However, RCP of ferrous/ferric blended salt in sodium hydroxide (NaOH) solution in an oxidizing medium produced of maghemite as a dominant phase rather than magnetite because of the oxidation of Fe2+ to Fe3+ happened. Based on this background, an oil membrane layer-assisted reverse co-precipitation approach has been examined to synthesis of magnetite in ambient atmosphere at room temperature. The result showed that although addition of benzene as an oil membrane layer was effective to prevent oxidation of magnetite to maghemite, but the magnetite particle size for the samples from the oil membrane layer-assisted reverse co-precipitation method was much larger than that from a reverse co-precipitation method without addition of oil membrane layer. en_US
dc.publisher Scientific.net en_US
dc.subject Reverse co-precipitation en_US
dc.title Turnitin Room Temperature Synthesis of Magnetite Particles by an Oil Membrane Layer-Assisted Reverse Co-Precipitation Approach en_US
dc.type Other en_US


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