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Mathematics for Enzyme Reaction Kinetics and Reactor Performance. F. Xavier MalcataЧитать онлайн книгу.

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where j_u denotes a unit vector colinear with u . Algebraic rearrangement resorting to Eq. (3.33) yields

(3.82) equation

from Eq. (3.81), whereas the associative property of multiplication of scalars unfolds

(3.83) equation

upon multiplication and division by cos{∠ v , w }, Eq. (3.83) becomes

(3.84) equation

with the aid also of the commutative property of multiplication of scalars. Recalling Eq. (3.53), one may reformulate Eq. (3.84) to

(3.85) equation

one promptly concludes that

(3.86) equation

because the vector in the right‐hand side of Eq. (3.85) has length equal to ‖ w ‖ multiplied by correction factor images rather than simply ‖ w ‖ as in Eq. (3.86) – and its direction is that of vector u (via j_u), rather than that of vector w (or of unit vector j_w, for that matter) also as in Eq. (3.86). Therefore, one may in general state that

(3.87) equation

this means that the scalar product of vectors is not associative with regard to the product of scalar by vector.

Although the definition as per Eq. (3.53), or a graphical support (as done above) may be utilized to infer all properties of the scalar product of vectors, either approach may prove cumbersome in routine analysis – so a handier mode of calculation would be welcome. Toward this goal, one may resort to the coordinate‐based forms of vectors u and v labeled as Eqs. (3.1) and (3.2), i.e.

(3.88) equation

In view of Eq. (3.70), one can convert Eq. (3.88) to

(3.89) equation

and a further application of the said distributive property unfolds

(3.90) equation

Equations (3.33) and (3.38) permit transformation of Eq. (3.90) to

(3.91) equation

– or, due to Eq. (3.58),

(3.92) equation

Recalling Eq. (3.55), one realizes that

(3.93) equation

because vectors j_x, j_y, and j_z have unit length by definition; on the other hand,

(3.94) equation

because each pair of indicated vectors are orthogonal to each other – so the cosine of their angle is nil, as per Eq. (3.56). Combination with Eqs. (3.93) and (3.94) permits simplification of Eq. (3.92) to just

(3.95) equation

or, in condensed form,

(3.96) equation

where i stands for x (i = 1), y (i = 2), or z (i = 3). Equation (3.95) is of particular relevance,since it allows calculation of the dot product based solely on the coordinates of its vector factors – without the need to explicitly know the angle between them or their magnitude; while providing a basic relationship of scalar product to the definition provided by Eq. (3.52) (as will soon be seen). Once in possession of Eq. (3.95), one realizes that

(3.97) equation

after

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