Add to ORKGNanochannels of porous alumina films were used as nanoreactors for the reaction of hydrogen gas with a mixture of Fe nitrate and Pt chloride. This results in the formation of of FePt clusters within the nanochannels. Both the sizes of the clusters and the coercivity the cluster assembly increase with the increase of annealing temperature. In order to reduce excessive agglomeration at high temperature, carbon was introduced by chemical vapor deposition and FePt:C composites in nanoscale channels were created. When FePt clusters were synthesized with carbon and heat treated at high temperatures, cluster sizes were much smaller than those without carbon, suggesting that the introduced carbon serves effectively to block the agglomeration of clu...
This chapter focuses on a gas-aggregation technique to prepare magnetic nanoclusters with controllab...
A simple synthetic procedure involving the pyrolysis of Fe and Pt acetylacetonates mixed in trioctyl...
This chapter focuses on a gas-aggregation technique to prepare magnetic nanoclusters with controllab...
Nanochannels of porous alumina films were used as nanoreactors for the reaction of hydrogen gas with...
Nanochannels of porous alumina films were used as nanoreactors for the reaction of hydrogen gas with...
Magnetic properties and nanostructure of FePt : C cluster-deposited films with C volume fraction of ...
Magnetic properties and nanostructure of FePt : C cluster-deposited films with C volume fraction of ...
FePt and Fe3O4 nanotubes are produced by hydrogen reduction in nanochannels of porous alumina templa...
Nanocluster-assembled dilute (FePt) xC100-x films with 30≥x≥5 (x denotes volume fraction) were produ...
FePt and Fe3O4 nanotubes are produced by hydrogen reduction in nanochannels of porous alumina templa...
Nanocluster-assembled dilute (FePt) xC100-x films with 30≥x≥5 (x denotes volume fraction) were produ...
FePt and Fe3O4 nanotubes are produced by hydrogen reduction in nanochannels of porous alumina templa...
FePt and Fe3O4 nanotubes are produced by hydrogen reduction in nanochannels of porous alumina templa...
In this paper we report results on the synthesis and magnetic properties of L10 FePt nanocomposite f...
Stoichiometric FePt nanoparticles in the tetragonal L10 phase, (Ku = 6.6?107 erg/cm3) are one of the...
This chapter focuses on a gas-aggregation technique to prepare magnetic nanoclusters with controllab...
A simple synthetic procedure involving the pyrolysis of Fe and Pt acetylacetonates mixed in trioctyl...
This chapter focuses on a gas-aggregation technique to prepare magnetic nanoclusters with controllab...
Nanochannels of porous alumina films were used as nanoreactors for the reaction of hydrogen gas with...
Nanochannels of porous alumina films were used as nanoreactors for the reaction of hydrogen gas with...
Magnetic properties and nanostructure of FePt : C cluster-deposited films with C volume fraction of ...
Magnetic properties and nanostructure of FePt : C cluster-deposited films with C volume fraction of ...
FePt and Fe3O4 nanotubes are produced by hydrogen reduction in nanochannels of porous alumina templa...
Nanocluster-assembled dilute (FePt) xC100-x films with 30≥x≥5 (x denotes volume fraction) were produ...
FePt and Fe3O4 nanotubes are produced by hydrogen reduction in nanochannels of porous alumina templa...
Nanocluster-assembled dilute (FePt) xC100-x films with 30≥x≥5 (x denotes volume fraction) were produ...
FePt and Fe3O4 nanotubes are produced by hydrogen reduction in nanochannels of porous alumina templa...
FePt and Fe3O4 nanotubes are produced by hydrogen reduction in nanochannels of porous alumina templa...
In this paper we report results on the synthesis and magnetic properties of L10 FePt nanocomposite f...
Stoichiometric FePt nanoparticles in the tetragonal L10 phase, (Ku = 6.6?107 erg/cm3) are one of the...
This chapter focuses on a gas-aggregation technique to prepare magnetic nanoclusters with controllab...
A simple synthetic procedure involving the pyrolysis of Fe and Pt acetylacetonates mixed in trioctyl...
This chapter focuses on a gas-aggregation technique to prepare magnetic nanoclusters with controllab...