Product | Tin Sputtering Target | |
Stock No | NS6130-10-1191 | |
Purity | 99.99% | Confirm |
Diameter | 50.8 mm ± 1mm | Confirm |
Thickness | 3 mm ± 0.5mm | Confirm |
Molecular Weight | 118.71 g/mol | Confirm |
Density | 7.365 g/cm³ | Confirm |
Melting Point | 231.93 °C | Confirm |
Shape | Round | Confirm |
Backing Plate | Copper (as per customer requirement) | |
Size and Shape | Targets Diameter and thickness can be according to Customer Requirement | |
Conclusion | The specifications Confirm with enterprise standard | |
Quality Control | Each Lot of was tested successfully | |
Main Inspect Verifier | Manager QC |
Assay | 99.99% |
Tin Sputtering Target: We procured Tin Nanoparticles from Nanoshel and are the obtained nanoparticles are well synthesized as per the requirement. I have used tin nanoparticles to enhance the performance of lithium ion battery by incorporating tin nanoparticles in the anode electrode, owing to the increase in interfacial area and decrease in lithium ion transport path length. The melting point of tin can decrease dramatically with particle size reduction to several nanometers owing to its enhanced surface area to volume ratio. The decreased melting point of tin nanosolder is highly desirable for preventing damage to electronic devices, caused by high reflow temperatures. As per my opinion these particles are worth and significant.
Tin Sputtering Target: Nanoshel is very reliable company to get required nanomaterials. As I ordered Tin nanoparticles from Nanoshel, they exhibit many properties, such as grain size, large surface areas, homogeneity and highly reactive surfaces, malleable, flexible and ductile metal because of these properties tin nanoparticles resists oxygen and water and I used these nanoparticles to coat other metals to prevent corrosion. It is also considered to be non-toxic and is therefore used for food packaging, such as tin cans.
Tin Sputtering Target: The most promising candidates to displace commercialized graphite, the operating potential of metallic Sn are slightly higher than graphite, and the extrapolating potential is close to Li to improve the safety of LIBs. Also Sn can be reversibly lithiated up to the end compound Li4, 4 Sn with a theoretical reversible capacity of 994 mAh g-1, almost three times higher than the theoretical value of the conventional graphite anode. However, the practical use of Sn anodes has been hindered by the short cycle life due to a large volume expansion of Sn during lithiation-delithiation process. Almost 300% of its initial volume expansion would result in serious mechanical stress causing rapid cracking and collapse of the structure, and loose contact between the anode and the current collector, thereby drastic capacity fading.