Bulk ZnO is a diamagnetic material but ferromagnetism (FM) has been observed by several groups in its nanostructures. In order to elucidate the room temperature (RT) FM of ZnO nanostructures, magnetic property of mechanically milled and subsequently annealed nano-ZnO powder has been investigated. Sample that has been milled and then annealed at 200 °C in ambient condition shows highest value of saturation magnetization (Ms), whereas lowest value of Ms has been noticed for the sample pre-annealed at 500 °C before milling. The variation of Ms with annealing temperatures closely resembles with the variation of average positron lifetime (τav) and S-parameter reported earlier for these nano-systems. It has also been found that Ms decreases systematically for increasing average grain size of the ZnO nanoparticles. Room temperature photoluminescence of the as-milled sample shows broad defect related emission centered ∼2.23 eV. Enhancement of such emission has been observed due to 200 °C annealing. Results altogether indicate that ferromagnetism in ZnO depends critically on the nature of disorder (open volume defects as well as defect clusters) at the grain surface region. In this connection, the possible role of zinc vacancy defects has also been emphasized.
Metal–semiconductor
hybrid nanoheterostructures have the
possibility to exhibit new synergic properties other than the combination
of properties from discrete components due to the interaction of metal
and semiconductor components at the interfaces. Here, we have synthesized
Ag–Cu2O eyeball-shaped quantum nanoheterostructures
with diameter ranging between 8 and 12 nm using a single-step low-cost
solvothermal process. It is observed that the presence of a minimum
3% of Ag is required for the formation of Ag–Cu2O quantum nanoheterostructures. The formation of nanoheterostructures
has introduced new synergic properties like intense blue luminescence
and surface-enhanced Raman scattering due to the interactions between
Ag and Cu2O atoms at the interfaces. The significant presence
of charge transfer through the interfaces is identified from the peak
shift of Raman modes. The increase in the electron density at the
metal surface due to the charge transfer and the recombination of
these electrons with sp- or d-band holes of Ag could be the effective
mechanism of the observed blue luminescence. The blue luminescence
of Ag–Cu2O quantum nanoheterostructures together
with its low band gap value (≈2.3 eV) is believed to have important
applications in optoelectronic devices.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.