The intrinsic persistence length of carboxymethyl cellulose (CMC) is determined by size
exclusion chromatography in combination with multiangle laser light scattering (SEC−MALLS) as well
as from potentiometric titrations. Samples with degree of substitution (ds) ranging from 0.75 to 1.25
were investigated. The relation between molar mass M and radius of gyration R
g as obtained by SEC−MALLS is determined in 0.02, 0.1, and 0.2 mol L-1 NaNO3. Using the electrostatic wormlike chain theory
a bare (intrinsic) persistence length L
p0 of CMC is assessed at 16 nm, irrespective of the degree of
substitution. A somewhat lower value (12 nm) is obtained when Odijk's theory for the description of
polyelectrolyte dimensions is applied. The difference between L
p0 assessed from both models is discussed
briefly. Potentiometric titrations were carried out in NaCl solutions (ranging from 0.01 to 1 mol L-1).
From the titrations the radius of the CMC backbone was obtained by application of the model of a
uniformly charged cylinder. The radius amounts to 0.95 nm for CMC ds = 0.75, and increases to 1.15
nm for CMC with ds = 1.25. The pK for the intrinsic dissociation constant of the carboxyl groups (i.e.,
at zero degree of dissociation) amounted to 3.2. L
p0 was also deduced from potentiometric titrations. A
model developed by Katchalsky and Lifson, which relates the dissociation behavior of a polyelectrolyte
to the stiffness of its chain, was applied to CMC. From analyses of the potentiometric titrations an intrinsic
persistence length of 6 nm was deduced. The difference between L
p0 assessed from SEC−MALLS and
potentiometric titrations is discussed briefly.
The adsorption behavior of carboxymethyl cellulose (CMC) on inorganic surfaces (TiO2 and R-Fe2O3) in aqueous solution has been studied systematically. The general trends are that the adsorbed amount decreases with increasing pH, whereas increasing the electrolyte (NaCl) concentration causes the adsorption to increase. The actual values, however, are influenced by the kinetics of the adsorption process. Near the point of zero charge of the oxidic surfaces the adsorption depends linearly on pH. This linearity is interpreted in terms of a molecular condenser, which is composed of the surface layer and the polyelectrolyte in the first layer near the surface. Adsorption is independent of the number of carboxylic groups per glucose unit (degree of substitution, ds). Neither at low (0.01 mol L -1 ) nor at high (1 mol L -1 ) electrolyte concentration does the adsorption depend on the chain length, which indicates a (rather) flat conformation of the adsorbed polymer. The apparent hydrodynamic thickness of the adsorbed layer is found to be substantial. Strong hysteresis is observed with respect to the pH dependence of adsorption: as compared to the adsorption measured directly at specified fixed pH values, at high pH values a substantially higher adsorbed amount can be obtained by initially adsorbing at low pH and subsequently increasing the pH value. Desorption of CMC only takes place after initially low pH values are increased substantially. The arduous desorption originates from a strong interaction with the surface and is enhanced by the chain rigidity of the CMC backbone.
Abstract.IlB and 'H NMR spectroscopy studies have revealed that the apparent association constants for borate esters of 2-amino 1,3-diols are pH dependent, whereas such a pH dependence is not found in the case of methyl-substituted diols or 3-amino-I ,Zpropanediol. These studies have also shown that boric acid ester formation can be detected using "B NMR.
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