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Silver, with the chemical symbol Ag and atomic number 47, is a lustrous and precious transition metal. It is highly valued for its exceptional electrical and thermal conductivity, malleability, and ductility, which enable it to be shaped into various forms such as coins, jewelry, and silverware. Silver also finds applications in chemical compounds, photographic film, and mirror production.

12595-26-5

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12595-26-5 Usage

Uses

Used in Electronics Industry:
Silver is used as a conductor in the electronics industry for its high electrical conductivity, which is the highest of all metals. It is employed in various components, including printed circuit boards, switches, and connectors, to ensure efficient and reliable electrical connections.
Used in Thermal Management:
Due to its excellent thermal conductivity, silver is used as a thermal conductor in applications requiring efficient heat dissipation, such as heat sinks, heat spreaders, and thermal interface materials in electronic devices and power electronics.
Used in Jewelry and Silverware:
Silver is used as a material in the production of jewelry and silverware for its lustrous appearance, durability, and resistance to tarnish. It is valued for its aesthetic appeal and is often used in various decorative items, tableware, and ornaments.
Used in Photography and Mirrors:
Silver is used in the production of photographic film and mirrors due to its ability to form a thin, reflective layer when coated onto a glass or plastic substrate. This property allows for the creation of high-quality images and reflective surfaces.
Used in Chemical Compounds:
Silver is used in various chemical compounds, such as silver nitrate, silver chloride, and silver sulfadiazine, which have applications in fields like medicine, water treatment, and photography.
Used in Antibacterial Applications:
Silver and its compounds have antimicrobial properties, making them useful in various antibacterial applications, such as wound dressings, medical devices, and water purification systems. They help prevent the growth of bacteria and other microorganisms, promoting healing and maintaining cleanliness.
Used in Renewable Energy:
Silver is used in the manufacturing of solar panels, specifically in the form of silver paste, which is applied to solar cells to create electrical connections. Its high electrical conductivity makes it an essential component in the production of efficient solar energy systems.

Check Digit Verification of cas no

The CAS Registry Mumber 12595-26-5 includes 8 digits separated into 3 groups by hyphens. The first part of the number,starting from the left, has 5 digits, 1,2,5,9 and 5 respectively; the second part has 2 digits, 2 and 6 respectively.
Calculate Digit Verification of CAS Registry Number 12595-26:
(7*1)+(6*2)+(5*5)+(4*9)+(3*5)+(2*2)+(1*6)=105
105 % 10 = 5
So 12595-26-5 is a valid CAS Registry Number.
InChI:InChI=1/3Ag

12595-26-5Upstream product

12595-26-5Downstream Products

12595-26-5Related news

silver (cas 12595-26-5) nanoparticles-clays nanocomposites as feed additives: Characterization of silver (cas 12595-26-5) species released during in vitro digestions. Effects on silver (cas 12595-26-5) retention in pigs08/14/2019

Two different clay nanocomposites, as sepiolite-Ag and kaolinite-Ag, are studied as carriers for silver nanoparticles (AgNPs) oral administration as antimicrobial agent in additives for animal feed. A three-step digestibility assay, corresponding to stomach, small and large intestine simulations...detailed

Plasmon-enhanced fluorescence provided by silver (cas 12595-26-5) nanoprisms for sensitive detection of sulfide08/12/2019

Noble metallic nanostructures, such as silver, play an important role in fluorescent enhancement. In this paper, a serial of silver nanoprisms were fabricated by using seed-mediated growth method, and their surface plasmon resonance (SPR) peak could be controlled from 500 nm to 900 nm through ad...detailed

Modelling of silver (cas 12595-26-5) anode dissolution and the effect of gold as impurity under simulated industrial silver (cas 12595-26-5) electrorefining conditions08/11/2019

As Au content causes passivation during silver electrorefining process, a kinetic study and modelling of AuAg alloy in synthetic silver electrolyte is presented. In this research, the possibility to process high gold Doré efficiently through the simple adjustment of electrolyte conditions and t...detailed

The role of size and protein shells in the toxicity to algal photosynthesis induced by ionic silver (cas 12595-26-5) delivered from silver (cas 12595-26-5) nanoparticles08/10/2019

Because of their biocide properties, silver nanoparticles (AgNPs) are present in numerous consumer products. The biocidal properties of AgNPs are due to both the interactions between AgNP and cell membranes and the release of dissolved silver (Ag+). Recent studies emphasized the role of differen...detailed

12595-26-5Relevant academic research and scientific papers

The relaxation from linear to triangular Ag3 probed by femtosecond resonant two-photon ionization

Leisner, Thomas,Vajda, Stefan,Wolf, Sebastian,Woeste, Ludger,Berry, R. Stephen

, p. 1017 - 1021 (1999)

We present extended NeNePo (negative to neutral to positive) measurements on the ultrafast dynamics in the ground state of neutral, mass-selected Ag3 molecules. A vibrational wave packet in the neutral molecule is created with an ultrashort laser pulse by photodetachment of the excess electron from the corresponding mass-selected anion. The subsequent molecular rearrangement is probed by photoionization after a selected time delay. Complementary to our previous investigations of this process, we now use two-photon photoionization via a resonant state in the probe step. Here, a bound-bound excitation to a well-known state followed by one-photon ionization is used instead of the nonresonant bound/free transition into the ionic continuum. Using radiation with wavelengths near 370 nm for resonant ionization, we observe a fast bending motion of the initially linear Ag3, followed by an ultrafast intramolecular vibrational energy redistribution, interpretable as an intramolecular collision process. The signal shows an apparent loss of vibrational coherence after the collision, which can be explained by the finite temperature of the anionic clusters in our experiment. Additionally, we describe a previously unknown resonance in the linear neutral molecule around 500 nm.

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