SemOpenAlex |

SemOpenAlex

Matches in SemOpenAlex for { <https://semopenalex.org/work/W2016111636> ?p ?o ?g. }

Showing items 1 to 100 of ±141 with 100 items per page.

W2016111636 endingPage "136" @default.
W2016111636 startingPage "130" @default.
W2016111636 abstract "Gadolinium doped ceria (Gd–CeO2) nanoparticles have been synthesized by an reverse microemulsion system using cyclohexane as the oil phase, a non-ionic surfactant Igepal CO 520 and their mixed aqueous solutions of gadolinium III nitrate hexahydrate and cerium III nitrate hexahydrate as the water phase. The control of particle size was achieved by varying the water to surfactant molar ratio. The synthesized and calcined powders were characterized by thermogravimetry-differential thermal analysis (TGA-DTA), X-ray diffraction analysis (XRD), scanning electron microscopy (SEM), transmission electron microscopy (TEM), energy dispersive spectroscopy (EDS), Fourier transform infrared spectroscopy (FTIR) and Raman spectroscopy. The XRD results show that all the samples calcined at 700 °C were single phase cubic fluorite structure. The average size of the particle was found to increase with increase in water to surfactant molar ratio (R). The mean diameter of the particle for various value of R varies between 8–15 nm (SEM) and 7.5–11 nm (TEM), respectively. EDS confirm the presence of gadolinia and ceria phase in the nanopowder calcined at 700 °C. FTIR analysis was carried to monitor the elimination of residual oil and surfactant phases from the microemulsion-derived precursor and calcined powder. Raman spectroscopy and DTA evidenced the formation of a solid solution of gadolinium doped ceria at room temperature." @default.
W2016111636 created "2016-06-24" @default.
W2016111636 creator A5033833256 @default.
W2016111636 creator A5045214064 @default.
W2016111636 creator A5075120015 @default.
W2016111636 date "2009-09-01" @default.
W2016111636 modified "2023-09-23" @default.
W2016111636 title "Fine tuning of gadolinium doped ceria electrolyte nanoparticles via reverse microemulsion process" @default.
W2016111636 cites W1561111074 @default.
W2016111636 cites W1561981814 @default.
W2016111636 cites W1596647409 @default.
W2016111636 cites W1896960378 @default.
W2016111636 cites W1963492996 @default.
W2016111636 cites W1964108069 @default.
W2016111636 cites W1967225374 @default.
W2016111636 cites W1969855921 @default.
W2016111636 cites W1971200136 @default.
W2016111636 cites W1971830608 @default.
W2016111636 cites W1973552340 @default.
W2016111636 cites W1976836348 @default.
W2016111636 cites W1979002068 @default.
W2016111636 cites W1981595238 @default.
W2016111636 cites W1984225645 @default.
W2016111636 cites W1985543228 @default.
W2016111636 cites W1988899321 @default.
W2016111636 cites W1995228750 @default.
W2016111636 cites W1999783925 @default.
W2016111636 cites W2004343194 @default.
W2016111636 cites W2008147573 @default.
W2016111636 cites W2016779481 @default.
W2016111636 cites W2021342302 @default.
W2016111636 cites W2032351872 @default.
W2016111636 cites W2037043063 @default.
W2016111636 cites W2046416604 @default.
W2016111636 cites W2049759518 @default.
W2016111636 cites W2053007926 @default.
W2016111636 cites W2056644496 @default.
W2016111636 cites W2060732989 @default.
W2016111636 cites W2068443239 @default.
W2016111636 cites W2077476769 @default.
W2016111636 cites W2080054818 @default.
W2016111636 cites W2087624112 @default.
W2016111636 cites W2088578173 @default.
W2016111636 cites W2089352566 @default.
W2016111636 cites W2091195688 @default.
W2016111636 cites W2094767713 @default.
W2016111636 cites W2094908972 @default.
W2016111636 cites W2112831795 @default.
W2016111636 cites W2116332028 @default.
W2016111636 cites W2120266768 @default.
W2016111636 cites W2123795537 @default.
W2016111636 cites W2142866843 @default.
W2016111636 cites W2146104995 @default.
W2016111636 cites W2148888953 @default.
W2016111636 cites W2316736488 @default.
W2016111636 cites W2318945578 @default.
W2016111636 doi "https://doi.org/10.1016/j.colsurfa.2009.07.012" @default.
W2016111636 hasPublicationYear "2009" @default.
W2016111636 type Work @default.
W2016111636 sameAs 2016111636 @default.
W2016111636 citedByCount "43" @default.
W2016111636 countsByYear W20161116362012 @default.
W2016111636 countsByYear W20161116362013 @default.
W2016111636 countsByYear W20161116362014 @default.
W2016111636 countsByYear W20161116362015 @default.
W2016111636 countsByYear W20161116362017 @default.
W2016111636 countsByYear W20161116362018 @default.
W2016111636 countsByYear W20161116362019 @default.
W2016111636 countsByYear W20161116362020 @default.
W2016111636 countsByYear W20161116362021 @default.
W2016111636 countsByYear W20161116362022 @default.
W2016111636 countsByYear W20161116362023 @default.
W2016111636 crossrefType "journal-article" @default.
W2016111636 hasAuthorship W2016111636A5033833256 @default.
W2016111636 hasAuthorship W2016111636A5045214064 @default.
W2016111636 hasAuthorship W2016111636A5075120015 @default.
W2016111636 hasConcept C113196181 @default.
W2016111636 hasConcept C120665830 @default.
W2016111636 hasConcept C121332964 @default.
W2016111636 hasConcept C127413603 @default.
W2016111636 hasConcept C13965031 @default.
W2016111636 hasConcept C147789679 @default.
W2016111636 hasConcept C160892712 @default.
W2016111636 hasConcept C161790260 @default.
W2016111636 hasConcept C178790620 @default.
W2016111636 hasConcept C179104552 @default.
W2016111636 hasConcept C185592680 @default.
W2016111636 hasConcept C187530423 @default.
W2016111636 hasConcept C190119865 @default.
W2016111636 hasConcept C191897082 @default.
W2016111636 hasConcept C192562407 @default.
W2016111636 hasConcept C207114421 @default.
W2016111636 hasConcept C42360764 @default.
W2016111636 hasConcept C43617362 @default.
W2016111636 hasConcept C557651011 @default.
W2016111636 hasConcept C58226133 @default.
W2016111636 hasConcept C7082614 @default.
W2016111636 hasConcept C76804077 @default.