61373-41-9

Basic information

• Product Name: (~137~Cs)caesium
• CAS NO: 61373-41-9
• Molecular Formula: ¹³⁷Cs
• Molecular Weight: 136.9065
• Mol File: 61373-41-9.mol
• Article Data: 6

Chemical Properties

• CAS DataBase Reference: (~137~Cs)caesium(CAS DataBase Reference)
• NIST Chemistry Reference: (~137~Cs)caesium(61373-41-9)
• EPA Substance Registry System: (~137~Cs)caesium(61373-41-9)

Safety Data

• Hazardous Substances Data: 61373-41-9(Hazardous Substances Data)

Upstream product

• 7440-46-2 caesium 
• 591-40-2 Anilinium-triflourmethansulfonat 
• 1310-73-2 sodium hydroxide 
• 15690-63-8 cesium chloride 
• 7732-18-5 water 
• 14234-48-1 helium ion 
• 7783-81-5 uranium hexafluoride 
• 13400-13-0 cesium fluoride 
• 7782-50-5 chlorine 
• 80937-33-3 oxygen 
• 10102-43-9 nitrogen(II) oxide 
• 7787-69-1 caesium bromide 

Downstream Products

• 21459-30-3 pentafluorophenylmercaptocaesium 
• 24315-86-4 cesium phenyltris(1-naphthyl)borate 

Relevant articles and documents

Cyanometalate cages with exchangeable terminal ligands

The coordination chemistry of the unusual metallo-ligand Cs?[CpCo(CN)3]4[Cp*Ru]3 (Cs?Co4Ru3) is described with attention to the behavior of the ligand itself, its binding to Lewis-acidic metal cations, and its ability to stabilize catalytically relevant Ru-PPh3 fragments. A series of tests demonstrate that the rim [CpCo(CN)3] - groups in Cs?Co4Ru3 are exchangeable. Upon treatment with [(MeC5H4)Co(CN)3] - (Co′) Cs?Co4Ru3 undergoes vertex exchange to give Cs?Co4-xCo′xRu3. Similarly the cage is degraded by CO. Most convincing, Cs?Co 4Ru3 reacts with PhNH3OTf to precipitate the polymer PhNH3CpCo(CN)3 and form the molecular box [Cs?Co4Ru4]+. Treatment of Cs?Co 4Ru3 with [M(NCMe)x]PF6 (M = Cu, Ag) gave the Lewis acidic cages {Cs?[CpCo(CN)3] 4[Cp*Ru]3M(NCMe)}PF6, which reacted with tertiary phosphane ligands to give adducts [Cs?Co4Ru 3M(PPh3)]PF6. Lewis acidic octahedral vertices were installed using Fe, Ni, and Ru reagents. The boxes [Cs?Co 4Ru3M(NCMe)3]2+ (M = Ni, Fe) formed readily from the reaction Cs?Co4Ru3 with [Ni(NCMe)6](BF4)2 and [Fe(NCMe) 6]-(PF6)2. Displacement of the MeCN ligands gives [Cs?Co4Ru3Ni(9-ane-S3)](BF4) 2. A series of boxes were prepared by the reaction of Cs?Co 4Ru3 and RuCl2(PPh3)3, RuHCl(PPh3)3, and [(C6H6)Ru(NCMe) 3](PF6)2. The derivative of the hydride, [Cs?Co4Ru3Ru(NCMe)(PPh3) 2](PF6)2, was characterized crystallographically. Wiley-VCH Verlag GmbH & Co. KGaA, 2007.

Production of Hydrated Metal Ions by Fast Ion or Atom Beam Sputtering. Collision-Induced Dissociation and Successive Hydration Energies of Gaseous Cu(1+) with 1-4 Water Molecules

Low-temperature sputtering of frozen aqueous solutions of metal salts, of hydrated crystalline transition-metal salts, of frosted metal surfaces, and of frosted metal salts with kiloelectronovolt energy rare gas atoms or ions produces copious amounts of cluster ions, among which M(1+)(H2O)n and/or M(1+)OH(H2O)n frequently dominate.Variable-energy collision-induced dissociation of these ions in a triple quadrupole mass spectrometer yields the successive gas-phase solvation energies.Several known hydration and bond energies have been reproduced, and the first and secondhydration energies of the Cu(1+) ion have been determined as 35 +/- 3 and 39 +/- 3 kcal/mol, respectively.It is concluded that gaseous Cu(1+) prefers dicoordination.

Charge transfer cross sections for Hg+, Xe+, and Cs+ in collision with various metals and carbon

Cross sections for charge transfer between Hg+, Xe+, and Cs+ and the atomic species Fe, Mo, Al, Ti, Ta, and C have been measured in the ion energy range from 1 to 5000 eV.In general, the cross sections for charge transfer