Jaime Benítez, the author of Principles and Modern Applications of Mass Transfer Operations, has taught this subject in the chemical engineering department of the University of Puerto Rico in Myagüez for some three
decades. Before he began work on the first edition, Benítez was determined to write a textbook, not just a text that would
be used with students simply because it was the only book to deal with a specialized subject, according to biographical information
included in the book. A textbook should be written by an educator who can impart his understanding to others. The author should
not only be an expert in the subject, but should also be able to communicate to students the logic of the discipline, its
causes and effects, and how it can be applied practically to solve problems.
Benítez's challenges are to present the problem of mass transfer in its full complexity to the novice, to parse the relationships
between its components, and to express the subject in the language of mathematics to solve problems. Providing such a chain
of logic requires far more than an expert knowledge of the subject, but Benítez is equal to the task. His ability to communicate
with the uninitiated is awesome.
For each of the numerous examples he uses to demonstrate mass-transfer applications, he sets forth the problem, provides the
necessary data, explains the underlying physical laws, presents relevant experimental references, and indicates the mathematical
path to the solution. The text includes too many examples of this approach to generalize, but each instance is impressive
in its relevance and practicality.
Principles and Modern Applications of Mass Transfer Operations by Jaime Benítez, Wiley, Hoboken, NJ, 2009, 620 pp., ISBN:
Benítez states that the methods of mass-transfer operations include such techniques as distillation, gas absorption, adsorption,
humidification, liquid extraction, and membrane separations. Benítez incorporates Mathcad, software that expresses problems
in mathematical notation and verifies engineering calculations, for example problems and homework. An appendix lists many
such programs, which can help solve Maxwell–Stefan equations, perform packed-column calculations, assist sieve-tray design,
solve binary distillation problems, and perform multistage crosscurrent extractions.
Mass-transfer operations is not an everyday subject. Even today, it remains largely the province of the chemical engineer.
But in this reviewer's opinion, the subject should be a required course in every physical-science curriculum today because
it is basic to almost all separation processes. Mass transfer is related to the tendency toward equilibrium that derives from
concentration gradients. It involves the transfer of material, or mass, from one homogeneous phase to another. Any arrangement
that includes several components in unequal concentrations exhibits mass transfer toward equilibrium (i.e., from the concentrate
to the dilute).
The text's breadth of focus is astonishing. It deals with interphase mass transfer and the relevant theories, the material
balances, the equilibria, and equilibrium-stage operations. It treats diffusion, diffusion coefficients, and diffusion in
solids and liquids. Other subjects covered include the distillation of multicomponents, batch distillations, packed and trayed
towers, Fenske's equation, and optimum-reflux ratios. Among many other activities discussed in similar detail are humidification
operations, mass transfer in membranes, and sorption processes.
Regarding membrane separation techniques, Benítez discusses such current processes as dialysis, reverse osmosis, microfiltration,
and ultrafiltration, as well as gas permeation. This reviewer, as must be apparent, considers this book to be a most worthwhile
addition to the technical literature.
Today's students are lucky to have textbooks such as Benítez's for their instruction. Mass-transfer operations were little
organized as a discipline in the 1930s and '40s. Scientists formerly used distillation and liquid-extraction techniques, prepared
ultrapure water, and purified drugs with membrane processes without sufficient instruction in mass-transfer operations. Only
recently has industry realized the importance of the hydrogen bond, understood the reflux ratio in distillations, and appreciated
the centrality of surface physics.
Rather than learning by trial and error, today's students have the means to learn the factors and interactions involved in
mass-transfer processes, thus gaining confidence and skill. Understanding is the indispensible basis of practice, and Benítez
supplies that understanding up front.
Benítez also manages to bring a personal and poetic touch to what could have been a dry discussion of chemical engineering.
For example, Benítez's example of mass transfer is "the invigorating aroma of a cup of freshly brewed coffee and the sensuous
scent of a delicate perfume both reaching our nostrils from the source by diffusion through the air." The reader cannot help
but notice and admire the author's perception.
Through the book's dedication ("To Jaime for being a most special son; your angelic smile is all that is necessary for my
happiness."), Benítez reveals his pleasure in dealing with people. His audience, the readers of his text, will be his beneficiaries.
Theodore H. Meltzer is a principal of Capitola Consulting, 8103 Hampden Ln., Bethesda, MD 20814-1244, tel. 301.986.8640, fax 301.986.9085, email@example.com
. He also is a member of Pharmaceutical Technology's Editorial Advisory Board.