Poly(lactic acid). Группа авторовЧитать онлайн книгу.

L₂ can further react to form lactolyl–lactolyllactic acid, L₃

(2.5) normal upper L 1 plus normal upper L 2 right harpoon over left harpoon normal upper L 3 plus normal upper H 2 normal upper O

The structures of the species are shown in Figures 2.2 and 2.3. The step‐wise condensation oligomerization presents a significant challenge for performing separations and for modeling vapor–liquid equilibrium of aqueous solutions. The oligomerization can be represented by a succession of simultaneous equilibrium reactions with the same equilibrium constant.

(2.6) normal upper L 1 plus normal upper L 3 right harpoon over left harpoon normal upper L 4 plus normal upper H 2 normal upper O

(2.7) normal upper L 1 plus normal upper L Subscript j minus 1 Baseline equals normal upper L Subscript j Baseline plus normal upper H 2 normal upper O

where L₄ is the tetramer, and L_{j − 1} and L_j are generic notation for oligomers of the lengths j − 1 and j, respectively. While alternative combinations of reactions can be written, such as two L₂ molecules forming L₄, chemical equilibrium can be obtained with the most convenient combination of independent reactions. Other expressions of the equilibria can be obtained by combinations of the independent network. For generalization, addition of a monomer to a chain provides a series of reactions where each equilibrium constant is expected to be approximately the same numerical value.

The equilibrium constant can be expressed in terms of concentration or mole fraction equivalently because the reaction has no net change in moles. Assuming that the equilibrium constant K ₂ for forming L₂, is the same for each condensation reaction K _j for forming L_j, as suggested by Flory [22]:

(2.8)

where x _i represents a mole fraction (e.g., x Subscript normal upper L Sub Subscript j represents the mole fraction of species L_j), n _i represents a number of moles, and the square brackets indicate a concentration.

The equilibrium has been studied by Watson [23], Montgomery [24], and Ueda and Terajima [25] and Bezzi [26], but the basis of the concentrations is not always clear. The distribution was studied by Witzke [1] who suggested an equilibrium constant value of approximately 0.25. Vu et al. [27] performed calibrated HPLC analysis and titrations and found that a value of 0.2023 was suitable, which is used for the calculated equilibria below. The mole fractions, moles, or concentrations appearing in Equation 2.8 are those existing at equilibrium and not those used to prepare a solution.

Schematic illustration of chemical structure of lactic acid and lactoyllactic acid.

FIGURE 2.2 Chemical structure of lactic acid and lactoyllactic acid.

Schematic illustration of chemical reaction between lactic acid and lactoyllactic acid.

FIGURE 2.3 Chemical reaction between lactic acid and lactoyllactic acid.

The unreacted form of lactic acid (L₁) is called the monomer. The concentration resulting from the conversion of all lactic acid to monomer is called the apparent concentration or sometimes the superficial or formal concentration. In the work of Vu et al. [27], the percent equivalent monomer lactic acid, %EMLA_j, denotes the percentage of apparent lactic acid represented by a particular oligomer. For example, the %EMLA₂ equals 10% when 10% of the apparent lactic acid molecules are dimers. The weight fraction is commonly referred to as the apparent (also known as superficial or formal) weight fraction. Using a superscript i to indicate the initial moles, for a solution composed of n Subscript normal upper W Superscript i moles of water (mass m Subscript normal upper W Superscript i Baseline equals 18.02 n Subscript normal upper W Superscript i Baseline right-parenthesis and n Subscript normal upper L Superscript i lactic acid (all L_1, mass m Subscript normal upper L Superscript i Baseline equals 90.08 n Subscript normal upper L Superscript i ), the apparent mole fraction of lactic acid is and the apparent weight fraction is .

2.5 EQUILIBRIUM DISTRIBUTION OF OLIGOMERS

The equilibrium and size distributions can be readily calculated using infinite series when the equilibrium constant is assumed to be independent of the oligomer length. Oligomer distribution is obtained by rearranging the material balances in terms of the equilibrium constant and subsequently empirically determining the equilibrium constant that represents the total titratable acid. The distribution is then verified against the smaller oligomers that are measurable. The equilibrium constant (Equation 2.8) can be rearranged as:

(2.9) n Subscript normal upper L Sub Subscript j Baseline equals n Subscript normal upper L Sub Subscript left-parenthesis j minus 1 right-parenthesis Baseline StartFraction n Subscript normal upper L 1 Baseline upper K Over n Subscript normal upper W Baseline EndFraction equals n Subscript normal upper L Sub Subscript left-parenthesis j minus 1 right-parenthesis Baseline p j greater-than-or-equal-to 2

where p is a lumped variable including the lactic acid monomer, free water, and equilibrium constant.

Скачать книгу