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Deep space radiations-like effects on VO2 smart nano-coatings for heat management in small satelittes

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dc.contributor.advisor Maaza, Malik
dc.contributor.advisor Vallabhapurapu, Vijaya Srinivasu
dc.contributor.author Mathevula, Langutani Eulenda
dc.date.accessioned 2015-03-19T10:43:50Z
dc.date.available 2015-03-19T10:43:50Z
dc.date.issued 2014-01
dc.identifier.citation Mathevula, Langutani Eulenda (2014) Deep space radiations-like effects on VO2 smart nano-coatings for heat management in small satelittes, University of South Africa, Pretoria, <http://hdl.handle.net/10500/18408> en
dc.identifier.uri http://hdl.handle.net/10500/18408
dc.description.abstract Thermal control in spacecraft will be increasingly important as the spacecraft grows smaller and more compact. Such spacecraft with low thermal mass will have to be designed to retain or reject heat more efficiently. The passive smart radiation device (SRD) is a new type of thermal control material for spacecraft. Current space thermal control systems require heaters with an additional power penalty to maintain spacecraft temperatures during cold swings. Because its emissivity can be changed without electrical instruments or mechanical part, the use of SRD decreases the request of spacecraft power budget. The (SRD) based on VO2 films is one of the most important structures of the functional thermal control surface, being lighter, more advanced and without a moving devices. A large portion of the heat exchange between an object in space and the environment is performed throughout radiation, which is in turn determined by the object surface properties. The modulation device is coated on the spacecraft surface and thus provides a thermal window that can adapt to the changing conditions in orbit. VO2 is well known to have a temperature driven metal to insulator transition ≈ 68ᴼC accompanying a transformation of crystallographic structure, from monoclinic (M-phase, semiconductor) at temperature below 68ᴼC to tetragonal (R-phase, metal) at temperature above 68ᴼC. This transition temperature is accompanied by an increase of infrared reflectivity and a decrease of infrared emissivity with increasing temperature. This flexibility makes VO2 potentially interesting for optical, electrical, and electro-optical switches devices, and as window for energy efficiency buildings applications. This study reports on effect of thickness on VO2 as well as the effect of proton irradiation on VO2 for active smart radiation device (SRD) application. VO2 was deposited on mica by Pulsed laser deposition techniques. The thickness of the film was varied by varying the deposition time. To characterize VO2 the following techniques were performed: XRD, AFM, SEM, TEM, XPS, RBS, RAMAN and transport measurements for optical properties. The effect of proton irradiation was observed using the SEM, where the change in structure, from crystal grains to rods, was observed. en
dc.format.extent 1 online resource (xi, 90 leaves) : illustrations en
dc.language.iso en en
dc.subject Vanadium dioxide en
dc.subject Transition temperature en
dc.subject Thin film en
dc.subject Proton irradiation en
dc.subject Smart radiation device en
dc.subject Tetragonal en
dc.subject Monoclinic en
dc.subject.ddc 546.522
dc.subject.lcsh Space vehicles -- Design and construction en
dc.subject.lcsh Nanotechnology en
dc.subject.lcsh Astrodynamics en
dc.subject.lcsh Space vehicles -- Thermodynamics en
dc.subject.lcsh Space vehicles -- Control systems en
dc.subject.lcsh Vanadium compounds en
dc.title Deep space radiations-like effects on VO2 smart nano-coatings for heat management in small satelittes en
dc.type Dissertation en
dc.description.department Physics en
dc.description.degree M.Sc. (Physics)


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