The relative affinities of ligand atoms for acceptor molecules and ions

Ahrland, Sten; Chatt, J.; Davies, N. R.

doi:10.1039/qr9581200265

Cited by 923 publications

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“…Based on a theoretical calculation, the N end SCN -is assumed to have a lower frequency compared with that of its free ion. 47,48 It is evident that the electrode potential has a significant influence on the frequency of the adsorbed SCN -, which can be 226 ANALYTICAL SCIENCES FEBRUARY 2000, VOL. 16…”

Section: Scnmentioning

confidence: 99%

Analyzing the Adsorption Behavior of Thiocyanide on Pure Pt and Ni Electrode Surfaces by Confocal Microprobe Raman Spectroscopy

et al. 2000

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Surface vibrational spectroscopies, such as infrared (IR), 1,2 Raman 3,4 and sum frequency generation (SFG), 5 are powerful surface analytical tools for in-situ investigating electrochemical interfaces by providing information at the molecular level. Among these techniques, Raman spectroscopy exhibits several advantages over IR spectroscopy and the SFG technique in analyzing solid/liquid interfaces: 3 (i) easy use of near-UV, visible, or near-IR light sources for the excitation of the Raman process, (ii) transparency of the electrolyte for the light beam, (iii) application of standard electrochemical cells without the need of using thin liquid cells, and hence, (iv) easy combination with electrochemical transient measurements in faradaic and non-faradaic regions, (v) easy obtaining vibrational bands related to the adsorbate-surface interaction in the low-frequency region (<500 cm -1 ). However, the lack of detection sensitivity has been a severe obstacle which had impeded the wide application of Raman spectroscopy in surface science and interfacial electrochemistry. In the absence of any resonance Raman or surface-enhancement processes, the typical differential Raman cross section (dσ/dΩ)NRS is less than 10 -29 cm 2 sr -1 compared with 10 -20 cm 2 sr -1 that of IR. 3 Especially in the analysis of adsorbates on the surface, the molecular quantity present is normally on the order of monolayer, or even submonolayer.Accordingly, the corresponding surface Raman intensities expected for a monolayer adsorbates are less than 1 count per second (cps) when standard Raman spectrometer systems are used. The discovery of surface-enhanced Raman scattering (SERS) in the 1970s, 6-8 that the Raman intensities for pyridine adsorbed at electrochemically roughened Ag electrodes were six orders of magnitude larger than those expected from the known differential Raman cross section for pyridine in solution, changed the situation of surface Raman spectroscopy. These findings stimulated worldwide experimental and theoretical research on SERS. Among the various proposed SERS mechanisms, "electromagnetic mechanism" (EM) 9 and "chemical effect" or "charge transfer" (CT) enhancement 10 have been widely accepted as the two main contributions to the giant surface enhancement. In the past two decades, with its high surface sensitivity and ease detecting vibrations in the lowfrequency region, SERS has been extensively applied in surface science, 3,4,9,10 analytical science 11 and life science. 12 Although it has especially provided a wealth of information in understanding solid/liquid and solid/gas interfacial structures, its application was almost restricted to noble metals, i.e., Ag, Au and Cu. 3,4,9,10 Therefore, it is worth finding other SERS substrates which are extensively used in variety of technologically important processes, such as Pt, Ni and Fe metals. Many researchers have been exploring very hard to attain this goal, but successful cases are few. Among them, Fleischmann's group 13 and Weaver's group 14,15 took advantage of the lo...

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Section: Scnmentioning

confidence: 99%

Analyzing the Adsorption Behavior of Thiocyanide on Pure Pt and Ni Electrode Surfaces by Confocal Microprobe Raman Spectroscopy

et al. 2000

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“…The fact that these two ligands can replace the zinc water without donating a proton to T199 Oyl might be due to their softness (polarizability), compared to oxygen. Soft anions have a higher affinity for relatively soft cations like zinc and, conversely, hard anions have a higher affinity for hard cations like alkali and alkaline earth metal ions [16]. The higher polarizability of the bromide and azide ions might alleviate the confrontation between its electron orbitals and the lone pair of T199 0~1.…”

Section: The Complex With Bromide At Ph 78mentioning

confidence: 99%

The structure of human carbonic anhydrase II in complex with bromide and azide

1993

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The three-dimensional structure of human carbonic anhydrase II complexed with azide and with bromide was investigated crystallographically. Both of these non-protonated inhibitors replace the zinc and the 'deep' water, two catalytically important water molecules in the active site of the molecule. Both the azide and the bromide ions bind in a distorted tetrahedral manner 0.4 and 1.1 A from the zinc water position, respectively, but are in close contact (2.0 and 2.6 A, respectively) with the zinc ion.

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“…Uncomplexed 2,2 is included for comparison . The formation constants in aqueous solution for the first complex between the weak (b)-acceptor (Ahrland, Chatt & Davies, 1958) Cd 2+ and NH 3 and I-respectively are of about the same order of magnitude. With the marked (b)-acceptor Hg 2+ the difference is about four log units in favour of I-(Stability Constants of Metal-Ion Complexes, 1964), indicating a very strong Hg2+-I -interaction.…”

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confidence: 69%

The structures of the mixed complexes cadmium(II)–1,4,10,13-tetraoxa-7,16-diazacyclooctadecane diiodide and mercury(II)–1,4,10,13-tetraoxa-7,16-diazacyclooctadecane diiodide

Malmsten¹

1979

Acta Crystallogr Sect B

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The relative affinities of ligand atoms for acceptor molecules and ions

Cited by 923 publications

References 0 publications

Analyzing the Adsorption Behavior of Thiocyanide on Pure Pt and Ni Electrode Surfaces by Confocal Microprobe Raman Spectroscopy

Analyzing the Adsorption Behavior of Thiocyanide on Pure Pt and Ni Electrode Surfaces by Confocal Microprobe Raman Spectroscopy

The structure of human carbonic anhydrase II in complex with bromide and azide

The structures of the mixed complexes cadmium(II)–1,4,10,13-tetraoxa-7,16-diazacyclooctadecane diiodide and mercury(II)–1,4,10,13-tetraoxa-7,16-diazacyclooctadecane diiodide

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