Acceptor ability

Hydrogen bonding to the nitrogen lone pair leads to an upheld shift, the extent of which depends on the proton-donor ability of the solvent, and the acceptor ability of the base shifts of some 20 p.p.m. are commonly found. 

These isomerization processes may be dependent on the nature of the solvent. For example, the rotational barrier of the tetrazathiapentalenes 15.15 (ca. 16 kcal moF ) is influenced by the donor or acceptor ability of the substituents X and Y through the S N short contacts.Solvents with acidic protons increase the magnitude of the barrier, whereas solvents that are good Lewis bases decrease the size of the barrier, owing to solvation of the transition state. 

If the cation has been unchanged, its ability to act as a hydrogen-bond donor has been unchanged, so why is an effect seen at all I propose that there is competition between the anion and the Reichardt s dye solute for the proton. Thus, the values of the ionic liquids are controlled by the ability of the liquid to act as a hydrogen bond donor (cation effect) moderated by its hydrogen bond acceptor ability (anion effect). This may be described in terms of two competing equilibria. The cation can hydrogen bond to the anion [Equation (3.5-2)] ... 

Recently, more detailed parameters for hydrogen bonding bases have been introduced and applied to many reactions demonstrating the existence of a linear free energy relationship between the hydrogen bonding donor and acceptor abilities and many kinetic or thermodynamic parameters91. 

The acceptor ability of the cation is increased by electron-attracting substituents. The task was to seperate the substituent influences on the reactivity of the monomer from that on the cation and to find a relationship between these influences and the brutto rate constant of the cationic polymerization 76). 

Halogen bond electron acceptor ability decreases in the order I > Br > Cl. Fluorine (acting as an electron acceptor) forms only very weak halogen bonds, if at all. 

Tetrabromomethane shows two types of n-bonding with aromatic donors that are contrasted in Fig. 8a and b, showing over-the-rim coordination to the aromatic C-C bond and over-the-center coordination to the benzene ring. The over-the-rim coordination is generally similar to that observed in the dibromine complexes but the C - Br distance in the former is longer, in agreement with weaker acceptor abilities of tetrabromomethane. Note that picryl bromide shows similar bromine coordination to the outer pyrene C-C bond with Br - C distances of 3.35 and 3.39 A [83]. A second type of coordination was reported earlier in ihc p-xylcnc complex [80] and recently in the associate with dimethylnaphtalene [53]. 

Since most Ni1 species with simple N-donor ligands are prone to disproportionation into Ni° and Ni11, relatively few Ni1 complexes with nonmacrocyclic N-donor ligands have been reported. Formation of Ni1 species is in most cases proposed on the basis of electrochemical data, although ligand-centered redox processes have to be considered. The ligands usually contain imine donor atoms or aromatic N-heterocycles, which because of their 7r-acceptor ability favor stabilization of lower oxidation states. 

The relationship between the herbicidal activity of 1,2,5-oxadiazole iV-oxides and some physicochemical properties potentially related to this bioactivity, such as polarity, molecular volume, proton acceptor ability, lipophilicity, and reduction potential, were studied. The semi-empirical MO method AMI was used to calculate theoretical descriptors such as dipolar moment, molecular volume, Mulliken s charge, and the octanol/water partition coefficients (log Po/w) <2005MOL1197>. 

Among the several configurations of the crucial [Nin(octadienediyl)L] complex, all of which are in equilibrium, the p3, 1 1) species 2a and the bis(p3) species 4a are predicted to be prevalent. The odonor/71-acceptor ability of the ancillary ligand is shown to predominantly determine the position of the kinetically mobile 2a 4a equilibrium. The conversion of the terminal allylic groups via allylic isomerization and/or allylic enantioface conversion are indicated to be the most facile of all the elementary processes that involve the [NiII(octadienediyl)L] complex. Consequently, the several octadienediyl-Ni11 configurations and their stereoisomers are likely to be in a dynamic pre-established equilibrium, that can be assumed to be always present. 

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