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Beryllium chloride is an inorganic compound with the formula BeCl 2. It is a colourless, hygroscopic solid that dissolves well in many polar solvents. Its properties are similar to those of aluminium chloride , due to beryllium 's diagonal relationship with aluminium .
beryllium formate: 1111–71–3 Be(C 2 H 3 O 2) 2: beryllium acetate: 543–81–7 Be(C 5 H 7 O 2) 2: beryllium acetylacetonate: 10210–64–7 BeCl 2: beryllium chloride: 7787–47–5 BeF 2: beryllium fluoride: 7787–49–7 BeH 2: beryllium hydride: 7787–52–2 BeI 2: beryllium iodide: 7787–53–3 Be(NO 3) 2: beryllium nitrate: 13597 ...
This is a list of common chemical compounds with chemical formulae and CAS numbers, indexed by formula. ... beryllium chloride: 7787-47-5 Be(ClO) 2:
Beryllium bromide – BeBr 2 [108] Beryllium carbonate – BeCO 3 [109] Beryllium chloride – BeCl 2 [110] Beryllium fluoride – BeF 2 [111] Beryllium hydride – BeH 2 [112] Beryllium hydroxide – Be(OH) 2 [113] Beryllium iodide – BeI 2 [114] Beryllium nitrate – Be(NO 3) 2 [115] Beryllium nitride – Be 3 N 2 [116] [117] Beryllium oxide ...
The following chart shows the solubility of various ionic compounds in water at 1 atm pressure and room temperature (approx. 25 °C, 298.15 K). "Soluble" means the ionic compound doesn't precipitate, while "slightly soluble" and "insoluble" mean that a solid will precipitate; "slightly soluble" compounds like calcium sulfate may require heat to precipitate.
Organoberyllium chemistry involves the synthesis and properties of organometallic compounds featuring the group 2 alkaline earth metal beryllium (Be). [2] The area remains less developed relative to the chemistry of other main-group elements, because Be compounds are toxic and few applications have been found. [3]
Pages in category "Beryllium compounds" The following 29 pages are in this category, out of 29 total. ... Beryllium chloride; Beryllium chromate; Beryllium fluoride ...
Finally, Kapustinskii noted that the Madelung constant, M, was approximately 0.88 times the number of ions in the empirical formula. [2] The derivation of the later form of the Kapustinskii equation followed similar logic, starting from the quantum chemical treatment in which the final term is 1 − d / r 0 where d is as defined above.