CAS 7440-05-3 Pd nanopowder Ultrafine Palladium as catalyst
Size:20-30nm Purity:99.95% CAS No:7440-05-3 ENINEC No.:231-115-6 Appearance:black Powder Shape:spherical
13929258449
Size:20-30nm Purity:99.95% CAS No:7440-05-3 ENINEC No.:231-115-6 Appearance:black Powder Shape:spherical
We can supply different size products of niobium silicide powder according to client's requirements. Size:1-3um; Purity:99.5%;Shape:granular CAS No:12034-80-9;ENINEC No.:234-812-3
Ni2Si particle,99.5% purity,granular shape,is used for Microelectronic integrated circuit, nickel silicide film,etc. Size:1-10um; CAS No:12059-14-2;ENINEC No.:235-033-1
Diameter:100-200nm ; Length:>10um; Purity:99%
CAS No:enquiry ; ENINEC No.:enquiry
Appearance: yellowish-brown powder; Shape:fiber
Brand:
SAT NANOItem NO.:
OPSW-NWPayment:
TT, Paypal, WUProduct Origin:
ChinaColor:
yellow brown powderShipping Port:
Shenzhen, ShanghaiLead Time:
1-5daysMin Order:
10gSpecification of silicon nanowires:
Diameter:100-200nm
Length:>10um
Purity:99%
Color:yellowish-brown powder
.
As a typical representative of one-dimensional nanomaterials, silicon nanowires not only possess the special properties of semiconductors, but also exhibit physical properties such as field emission, thermal conductivity, and visible photoluminescence that differ from bulk silicon materials. They have enormous potential application value in nanoelectronic devices, optoelectronic devices, and new energy sources. More importantly, silicon nanowires have excellent compatibility with existing silicon technologies and thus have great market application potential. Therefore, silicon nanowires are a highly promising new material in the field of one-dimensional nanomaterials.
Silicon nanowires have many advantages such as environmental friendliness, biocompatibility, easy surface modification, and compatibility with the semiconductor industry.
Silicon nanowires are important materials for semiconductor biosensors. Silicon nanowires, as an important class of one-dimensional semiconductor nanomaterials, have unique optical properties such as fluorescence and ultraviolet, electrical properties such as field emission and electron transport, thermal conductivity, high surface activity, and quantum confinement effects, which make them have good application prospects in high-performance field-effect transistors, single electron detectors, and field emission display devices.
Silicon nanowires are also widely studied and used in applications such as lithium-ion batteries, thermoelectric, photovoltaic, nanowire batteries, and non-volatile memory.
Recently, scientists have demonstrated a new material with a thermal conductivity efficiency 150% higher than traditional materials used in advanced chip technology. This is ultra-fine silicon nanowire, which can be used to manufacture smaller and faster microelectronic devices, and its heat transfer efficiency exceeds current technology. Electronic devices powered by microchips that effectively dissipate heat, in turn, consume less energy - an improvement that helps reduce the energy consumption generated by burning carbon rich fossil fuels that contribute to global warming.