Skip to main content

Lanthanum Nickel Oxide Sputtering Targets and Applications

Lanthanum nickel oxide with the chemical formula of LaNiO3 is an important perovskite-type oxide with metallic conductivity.
Lanthanum nickel oxide is a ternary compound with unique chemical and physical properties. It shows an extended range of oxygen-deficient compositions, an uncommon intrinsic n-type metallic conductance, a perovskite crystal structure and thermal and chemical stability. These characteristics make LNO a technologically important perovskite oxide electrode in many potential applications such as ferroelectric thin film capacitors, solid oxide fuel cells, nonvolatile ferroelectric random access memories and multilayer actuators.
Furthermore, LNO films have potential to be used as oxygen pressure and ethanol active sensing layers. Also, the reduced La–Ni mixed oxides are reported to be good catalyst precursors to synthesized organic compounds and to grow large amounts of regular diameter distribution controlled carbon nanotubes. Different chemical and physical thin film deposition techniques have been used to prepare LNO on various substrates. Chemical methods such as chemical vapor deposition, metallo-organic chemical vapor deposition and chemical solution deposition have been used to prepare LNO films. Physical methods such as sputtering, pulsed laser deposition and mist plasma evaporation have also been reported. Wet chemical solution deposition techniques provide simple and versatile alternative methods for thin film preparation.
As a summary we can state that lanthanum nickel oxide forms films with excellent properties and ths compound is one of the promising candidates of the oxide electrodes for thin-film ferroelectric devices. Also in fuel cells lanthanum nickel oxide sputtering targets can be used. If you need lanthanum nickel oxide for your research needs, you can clink the links given on the table below and give an order.
TypeSizeThicknessPurityLinkLanthanum Nickel Oxide1'0.125'’99.9%https://nanografi.com/sputtering-targets/lanthanum-nickel-oxide-lanio3-sputtering-targets-size-1-thickness-0-125-purity-99-9/Lanthanum Nickel Oxide1'0.250'’99.9%https://nanografi.com/sputtering-targets/lanthanum-nickel-oxide-lanio3-sputtering-targets-size-1-thickness-0-250-purity-99-9/Lanthanum Nickel Oxide2'0.125'’99.9%https://nanografi.com/sputtering-targets/lanthanum-nickel-oxide-lanio3-sputtering-targets-size-2-thickness-0-125-purity-99-9/Lanthanum Nickel Oxide2'0.250'’99.9%https://nanografi.com/sputtering-targets/lanthanum-nickel-oxide-lanio3-sputtering-targets-size-2-thickness-0-250-purity-99-9/Lanthanum Nickel Oxide3'0.125'’99.9%https://nanografi.com/sputtering-targets/lanthanum-nickel-oxide-lanio3-sputtering-targets-size-3-thickness-0-250-purity-99-9/Lanthanum Nickel Oxide3'0.250'’99.9%https://nanografi.com/sputtering-targets/lanthanum-nickel-oxide-lanio3-sputtering-targets-size-3-thickness-0-125-purity-99-9/Lanthanum Nickel Oxide4'0.125'’99.9%https://nanografi.com/sputtering-targets/lanthanum-nickel-oxide-lanio3-sputtering-targets-size-4-thickness-0-125-purity-99-9/Lanthanum Nickel Oxide4'0.250'’99.9%https://nanografi.com/sputtering-targets/lanthanum-nickel-oxide-lanio3-sputtering-targets-size-4-thickness-0-250-purity-99-9/Lanthanum Nickel Oxide5'0.125'’99.9%https://nanografi.com/sputtering-targets/lanthanum-nickel-oxide-lanio3-sputtering-targets-size-5-thickness-0-125-purity-99-9/Lanthanum Nickel Oxide5'0.250'’99.9%https://nanografi.com/sputtering-targets/lanthanum-nickel-oxide-lanio3-sputtering-targets-size-5-thickness-0-250-purity-99-9/Lanthanum Nickel Oxide6'0.125'’99.9%https://nanografi.com/sputtering-targets/lanthanum-nickel-oxide-lanio3-sputtering-targets-size-6-thickness-0-125-purity-99-9/Lanthanum Nickel Oxide6'0.250'’99.9%https://nanografi.com/sputtering-targets/lanthanum-nickel-oxide-lanio3-sputtering-targets-size-6-thickness-0-250-purity-99-9/Lanthanum Nickel Oxide7'0.125'’99.9%https://nanografi.com/sputtering-targets/lanthanum-nickel-oxide-lanio3-sputtering-targets-size-7-thickness-0-125-purity-99-9/Lanthanum Nickel Oxide7'0.250'’99.9%https://nanografi.com/sputtering-targets/lanthanum-nickel-oxide-lanio3-sputtering-targets-size-7-thickness-0-250-purity-99-9/Lanthanum Nickel Oxide8'0.125'’99.9%https://nanografi.com/sputtering-targets/lanthanum-nickel-oxide-lanio3-sputtering-targets-size-8-thickness-0-125-purity-99-9/Lanthanum Nickel Oxide8'0.250'’99.9%https://nanografi.com/sputtering-targets/lanthanum-nickel-oxide-lanio3-sputtering-targets-size-8-thickness-0-250-purity-99-9/Lanthanum Nickel Oxide (Indium)1'0.125'’99.9%https://nanografi.com/sputtering-targets/lanthanum-nickel-oxide-indium-lanio3-sputtering-targets-size-1-thickness-0-125-purity-99-9/Lanthanum Nickel Oxide (Indium)1'0.125'’99.9%https://nanografi.com/sputtering-targets/lanthanum-nickel-oxide-indium-lanio3-sputtering-targets-size-2-thickness-0-125-purity-99-9/
Labels:

Comments

Post a Comment

Popular posts from this blog

Molybdenum Trioxide Nanoparticles/Nanopowder and Applications

General Information about Molybdenum Trioxide                                                     Molybdenum trioxide is chemical compound with the formula MoO3. Its chief application is as an oxidation catalyst and as a raw material for the production of molybdenum metal.  Molybdenum Trioxide  is a very light blue powder. Molybdenum Trioxide Nanoparticles/Nanopowder and Their Applications                                                    Like many  nanoparticles/nanopowder , Molybdenum Trioxide nanoparticles/nanopowder are used as catalysts. These catalysis reactions include hydrogenation catalysis and cracking catalysis. Molybdenum Trioxide nanoparticles/  nanopowder are useful for...
Post a Comment
Read more

Graphene Tyres and Graphene Brake Pads

Could Graphene Use Create A Distruptive Technology In Tyre Sector? Almost every day, we see new applications emerging from graphene. The fact is certain; graphene is a disruptive technology that holds huge potential for commercialization. Graphene has abilities to open new markets and even replace existing materials or material technologies. A brand new application of graphene came out which is producing graphene tyres and brake pads. https://www.canadacarbon.com/brake-linings-gasket... In 2016 GraphChina (Graphene Innovation Conference); Sentury and Huagao launched their first electrostatic conducting graphene tyre on September 22nd. 2-3 weeks before the conference Sentury and Huagao officially announced their cooperation on the product. During the press conference, Sentury’s engineers (which is branded with the Landsail moniker), revealed that the latest test data shows their graphene-enhanced tyre offers; 1.8 meters shorter stopping distances (6 % improvement on conv...
1 comment
Read more

Characterization and potential uses of Hydroxyapatite Nanopowder/Nanoparticle

   Hydroxylapatite , also referred to as hydroxyapatite (HA), is a calcium apatite in its naturally occurring mineral form with the formula Ca5(PO4)3(OH). A fluorapatite or chlorapatite may be produced if the OH−ion is replaced by fluoride, chloride or carbonate. Hydroxylapatite crystallizes in the hexagonal crystal pattern. Pure hydroxylapatite powder is of white color. However, naturally occurring apatites can also have brown, yellow, or green hue, resembling the coloration of dental fluorosis. Hydroxyapatite Nanopowder/Nanoparticle (HApN) , nanodots or nanocrystals are spherical or faceted high surface area oxide magnetic nanostructured particles. Nanoscale Hydroxyapatite Nanopowder/Nanoparticle (HApN) are normally 20-80 nanometers (nm) with specific surface area (SSA) in the 15 - 50 m2/g range but sometimes available with an average particle size of 100 nm range with a specific surface area of approximately 5 - 10 m2/g. Hydroxyapatite Nanopowder/Nanoparticle (HApN...
Post a Comment
Read more