Items 171 to 180 of 296 total
Display:
Product Name | CAS # | Catalog # | QUANTITY | Price | Citations | RATING |
---|---|---|---|---|---|---|
Strontium titanate | 12060-59-2 | sc-251072 sc-251072A | 100 g 1 kg | $41.00 $408.00 | ||
Strontium titanate is a fascinating oxide known for its exceptional dielectric properties and ferroelectric behavior. Its perovskite structure facilitates unique electron mobility and polarization effects, which are critical in various electronic applications. The compound exhibits strong ionic bonding, leading to significant lattice distortions under external fields. Additionally, its high refractive index and low thermal conductivity make it an intriguing subject for studies in photonics and solid-state physics. | ||||||
Cyclopentadienyl iron(II) dicarbonyl dimer | 12154-95-9 | sc-239620 | 25 g | $92.00 | ||
Cyclopentadienyl iron(II) dicarbonyl dimer is a notable organometallic compound characterized by its unique bridging interactions between iron centers. This dimer exhibits distinct reactivity patterns, particularly in carbonyl ligand substitution reactions, which can influence its coordination chemistry. The compound's ability to engage in π-backbonding enhances its stability and alters its electronic properties, making it a subject of interest in catalysis and materials science. Its distinctive geometry contributes to its behavior in various chemical environments. | ||||||
Iron(III) acetylacetonate | 14024-18-1 | sc-252913 sc-252913A | 25 g 100 g | $31.00 $56.00 | ||
Iron(III) acetylacetonate is a versatile coordination complex known for its chelating ability, forming stable five-membered rings with acetylacetonate ligands. This compound exhibits unique electronic properties due to strong π-π interactions and metal-ligand charge transfer, influencing its reactivity in oxidation and reduction processes. Its distinct solubility in organic solvents and ability to participate in ligand exchange reactions make it a key player in various synthetic pathways and materials applications. | ||||||
Lithium tetrachloroaluminate | 14024-11-4 | sc-252969 sc-252969A sc-252969E | 5 g 25 g 250 g | $109.00 $235.00 $2350.00 | ||
Lithium tetrachloroaluminate is a notable Lewis acid characterized by its strong electrophilic nature, facilitating unique interactions with electron-rich substrates. Its tetrahedral geometry allows for effective coordination with various ligands, enhancing reaction kinetics in polymerization and catalysis. The compound's high ionic character contributes to its solubility in polar solvents, promoting rapid ion exchange and enabling diverse pathways in synthetic chemistry. Its reactivity is further influenced by the presence of chloride ions, which can stabilize transition states. | ||||||
Octadecylsilane | 18623-11-5 | sc-228872 | 25 g | $123.00 | ||
Octadecylsilane is a silane compound notable for its long hydrophobic alkyl chain, which significantly influences its surface properties. This compound exhibits strong van der Waals interactions, promoting self-assembly on surfaces to form monolayers. Its reactivity is characterized by the formation of siloxane bonds, facilitating robust adhesion to various substrates. The unique molecular architecture enhances its ability to modify surface energy, impacting wettability and chemical resistance. | ||||||
Antimony(III) oxide | 1309-64-4 | sc-239254 | 100 g | $31.00 | ||
Antimony(III) oxide exhibits intriguing properties as a semiconductor and a catalyst in various chemical reactions. Its layered structure allows for significant charge transport, enhancing its conductivity. The compound's ability to form stable complexes with Lewis bases facilitates unique molecular interactions, influencing reaction pathways. Additionally, its amphoteric nature enables it to react with both acids and bases, showcasing versatility in diverse chemical environments. | ||||||
Silver salicylate | 528-93-8 | sc-272466 | 5 g | $90.00 | ||
Silver salicylate is characterized by its unique coordination chemistry, where silver ions interact with the salicylate anion, leading to the formation of distinct molecular complexes. This compound exhibits notable photochemical properties, enabling it to participate in light-induced reactions. Its crystalline structure contributes to specific optical characteristics, influencing light absorption and emission. Furthermore, the compound's reactivity with various ligands highlights its potential in complexation and catalysis, showcasing its dynamic behavior in diverse chemical contexts. | ||||||
Lead(II) chromate | 7758-97-6 | sc-250240 | 100 g | $57.00 | ||
Lead(II) chromate is distinguished by its vibrant yellow hue and unique crystalline structure, which influences its solubility and reactivity. The compound exhibits strong ionic interactions, leading to distinct pathways in redox reactions. Its stability in various environments allows for selective precipitation reactions, while its ability to form complexes with other ions enhances its role in various chemical processes. Additionally, its high density and hardness contribute to its physical robustness. | ||||||
Ga(III) Protoporphyrin IX Chloride | 210409-12-4 | sc-396856 | 50 mg | $418.00 | ||
Ga(III) Protoporphyrin IX Chloride is characterized by its intricate coordination chemistry, where gallium interacts with the porphyrin ring, influencing electronic properties and light absorption. This compound exhibits unique ligand field stabilization, affecting its reactivity in complexation and electron transfer processes. Its distinct geometry facilitates specific molecular interactions, enhancing its role in catalysis and photophysical applications. The compound's solubility and stability in various solvents further contribute to its diverse chemical behavior. | ||||||
Cobalt(II) oxide | 1307-96-6 | sc-475663 | 1 g | $12.00 | ||
Cobalt(II) oxide exhibits notable redox properties, allowing it to participate in various electron transfer reactions. Its crystalline structure facilitates strong metal-oxygen bonding, influencing its catalytic activity in oxidation processes. The compound's ability to form stable complexes with ligands enhances its reactivity, while its magnetic properties are attributed to unpaired electrons, making it significant in materials science. Additionally, its thermal stability allows for diverse applications in high-temperature environments. |