Top 10 similar words or synonyms for bpy

bipy    0.822388

dcbpy    0.767866

dnbpy    0.756935

rucl    0.753833

pcy    0.753425

rhcl    0.746497

cobaltocene    0.728875

bipyridine    0.724515

phcn    0.722082

terpy    0.716051

Top 30 analogous words or synonyms for bpy

Article Example
DNA-binding metallo-intercalators In the case of ruthenium intercalators, the general synthesis consists of preparing intercalative ligands followed by their coupling to a ruthenium metal complex coordinated by specific ancillary ligands. Examples of prior ruthenium complexes used as precursors for metallo-intercalators include cis-[Ru(bpy)Cl] and cis-[Ru(phen)Cl]∙2HO, which can be synthesized into [Ru(bpy)(maip)], [Ru(bpy)(paip)], [Ru(bpy)(bfipH)](ClO), and Ru(phen)(bfipH)](ClO).
Organopalladium The first organopalladium(IV) compound was described in 1986. This complex is MePd(IV)Ibpy with bpy as a bidentate 2,2'-bipyridine ligand It was synthesized by reaction of methyl iodide with MePd(II)bpy.
Brookfield Property Partners In October, 2015, BPY acquired a Brookfield residential development in Brooklyn called “Greenpoint Landing.” BPY also sold a 44% interest in the $8 billion Manhattan West development in New York to the Qatar Investment Authority in October, 2015.
Tris(bipyridine)ruthenium(II) chloride [Ru(bpy)] has been examined as a photosensitiser for both the oxidation and reduction of water. Upon absorbing a photon, [Ru(bpy)] converts to the aforementioned triplet state, denoted [Ru(bpy)]*. This species transfers an electron, located on one bpy ligand, to a sacrificial oxidant such as peroxodisulfate (SO). The resulting [Ru(bpy)] is a powerful oxidant and oxidizes water into O and protons via a metal oxide catalyst. Alternatively, the reducing power of [Ru(bpy)]* can be harnessed to reduce methylviologen, a recyclable carrier of electrons, which in turn reduces protons at a platinum catalyst. For this process to be catalytic, a sacrificial reductant, such as EDTA or triethanolamine is provided to return the Ru(III) back to Ru(II).
Photochemical carbon dioxide reduction in the 1980s led the development of catalytic CO reduction using visible light. In prior work developing photocatalysts for water splitting, Lehn observed that Co(I) species were produced in solutions containing CoCl, 2,2'-bipyridine (bpy), a tertiary amine, and a Ru(bpy)Cl photosensitizer. The high affinity of CO to cobalt centers led both he and Ziessel to study cobalt centers as electrocatalysts for reduction. In 1982, they reported CO and H as products from the irradiation of a solution containing 700ml of CO, Ru(bpy) and Co(bpy).