Topologyhasbeenreferredtoas"rubbersheetgeometry".Thenameisapt,for the subject is concerned with properties of an object that would be preserved, no matter how much it is stretched, squashed, or distorted, so long as it is not in any way torn apart or glued together. One's ?rst reaction might be that such animprecisesoundingsubjectcouldhardlybepartofseriousmathematics,and wouldbeunlikelytohaveapplicationsbeyondtheamusementofsimpleparlour games. This reaction could hardly be further from the truth. Topology is one of the most important and broadranging disciplines of modern mathematics. It is a subject of great precision and of breadth of development. It has vastly many applications, some of great importance, ranging from particle physics to cosmology, and from hydrodynamics to algebra and number theory. It is also a subject of great beauty and depth. To appreciate something of this, it is not necessary to delve into the more obscure aspects of mathematical formalism. For topology is, at least initially, a very visual subject.
Some of its concepts apply to spaces of large numbers of dimensions, and therefore do not easily submit to reasoning that depends upon direct pictorial representation. But even in such cases, important insights can be obtained from the visual  rusal of a simple geometrical con?guration. Although much modern topology depends upon ?nely tuned abstract algebraic machinery of great mathematical sophistication, the underlying ideas are often very simple and can be appre ated by the examination of properties of elementarylooking drawings.
ISBN  9781848009127   Pages  161  ISBN13  9781848009127 (What's this?)   Weight (grammes)  286  Publisher  Springer London Ltd   Published in  England  Imprint  Springer London Ltd   Published in  GB  Format  Paperback   Previous ISBN  9781852333775  Publication date  27 Feb 2009   Height (mm)  235  DEWEY  514   Width (mm)  178  DEWEY edition  DC22   Spine width (mm)  8 

 
1   Homeomorphic Sets   1  2   Topological Properties   15  3   Equivalent Subsets   25  4   Surfaces and Spaces   51  5   Polyhedra   69  6   Winding Number   93  A   Continuity   105  B   Knots   113  C   History   121  D   Solutions   127    Bibliography   149    Index   151 
The appearance of this beautiful, modestsized (166pp) book in this time and place is, for me personally, an instance of splendid serendipity. My reason for regarding this publication as a case of perfect timing is that my own work in number theory has begun to take a frighteningly topological turn over the last few years (in the French sense, so to speak), and some old lacunae have to be taken care of. Now! And A Topological Aperitif looks to be a great place to start. The book would serve well for selfstudy and would play an important role in an introductory course as a supplementary level text to one of the established players, as I will discuss at greater length presently. It would actually also be perfect for a seminar in which various topics could then be pursued in greater depth using various supplementary sources. I should like to preface my review proper with a few personal reminiscences for which I beg the reader's indulgence. More years ago than I care to admit, I enrolled in undergraduate topology, at first full of enthusiasm and good intentions. But soon I proceeded to cut most of the classes because I was goofy and irresponsible and, if not in love, then heavily in like. I had become profoundly romantically infatuated with a pretty flautist whose musicdepartment schedule allowed me to spend the hour ostensibly reserved for topology sitting on a bench near a fountain, gazing into her eyes rather than at a blackboard covered with what were to me very weird pictures. The romantic liaison did not last and I didn't learn topology (although I passed the class). In graduate school my elective courses outside of number theory ran toward Fourier analysis, trigonometric series, and commutative Banach algebras, even though no one would accuse me of being an analyst. As regards topology, it was by now strangely and sneakily fascinating to me, having glimpsed all those delectable commutative diagrams and long exact cohomology sequences in general department colloquia and on sundry blackboards in open offices. I even had the great pleasure of attending a seminar with Karoubi, whom I was ruefully unprepared to appreciate properly (though he was impossible not to like and admire). But all in all: no real learning of topology took place for me. I have grown more and more sorry about this gap in my knowledge over the years (although some of the problem was solved in an ad hoc fashion: teaching the subject helps, even if it's done badly). But now there is another real and pressing need to correct the problem: techniques from modern algebraic geometry have become big players in my work. I like to learn new and unfamiliar material within a framework of analogies, if possible, and so it has been my way for a while now to try to understand some of the new and highfalutin' stuff concerning, say, derived categories, by means of juxtaposing these developments against the corresponding staples of algebraic topology. (Mapping cones come to mind right away, for example.) But the shortcomings in my education in topology, described selfindulgently above, have made this approach increasingly difficult, causing me to seek a more formal course of selfstudy. It would be nice to go a linear route, with as one objective the development of a sortof latterday topologist's intuition. I think the present book by Huggett and Jordan, distinguished by clear and wonderful exposition and laden with informal motivation, visual aids, cool (and beautifully rendered) pictures, etc. fits the bill to a tee as a point of departure. Indeed, I particularly want to recommend the book as an initial point for just about any course of studies in topology, whether it be a selfstudy affair such as what I'm now about to undertake, or something more in the orthodox mainstream of a college or university education in mathematics. Despite my being topologically challenged, my department has twice allowed me to teach the same undergraduate topology course which I cut so successfully almost three decades ago and I have always gone the Munkres route. My next time at bat I will introduce A Topological Aperitif as, at the very least, a supplementary text. After such a wealth of unsolicited personal information let me now get down to some specifics regarding the book. The authors' characterization of their book as an aperitif is right on the money. The main course (starting with Munkres' book, for example) is to be had elsewhere, as Huggett and Jordan state at the onset: "[W]e hope to whet the reader's appetite for this way of thinking," which, a sentence earlier, they describe as "conceptual and geometric rather than formulaic." And so it is that the book succeeds wonderfully at providing an intuition to the almost parochial familiarity that topologists seem to have with their specific mathematical objects  a Fingerspitzenkunde that I've grown to be more and more jealous of ... ...Note that the book's arrangement and the absence of analysis situs proper (or point set topology) disqualify the book as a solo text for a mainstream American undergraduate topology course. Hence my suggestion that A Topological Aperitif serve primarily as a supplement in such a setting. Or, as I already indicated above, it would be a marvelous experiment to use it in a student seminar, aimed at exposing the participants to topologyforinsiders, with the proviso that topics should be pursued in greater depth via other sources. Huggett and Jordan stress that the heart of the book is the study of homeomorphisms, surfaces and polyhedra, which material they promise is pitched at the level of a second year undergraduate. With Huggett in Plymouth, UK, and Jordan in Hull, UK, this leads one to ask whether the English still refer to their graduate studies as undergraduates; I don't know. But actually it matters not: their presentation is very, very clear and accessible, and the book would be used to great advantage on either side of the pond (or anywhere else I guess). I'm even willing to go so far as to suggest that the book is likely to contribute materially to the seduction of a number of fledgling mathematics students to topology, seeing that it hints so successfully at what can be had down the line. In fact, Huggett and Jordan unabashedly introduce the reader, by now getting to be wellversed in the topologist's jargon and particular way of thinking, to truly sexy things: in their Appendix B they have a go at the Jones polynomial. I should like to point out also that in the chapter "Polyhedra" there is a marvelous treatment of the Euler characteristic (in its first incarnation) and its attendant applications. After dealing with the Platonic solids Huggett and Jordan go to polyhedra on a torus, then on a Klein bottle, and then on the real projective plane. They go on to consider handlebodies and a classification theorem. And the proof of Euler's theorem they choose is that of van Staudt, using trees and the dual polyhedron. The proof also contains an en passant invocation of the Jordan curve theorem. This is all a clear example of the authors' excellent taste! The exercises provided in the book are excellent and critical. The preface contains the warning that "Although elementary, the mathematics in this book is sharp and subtle, and will not be properly grasped without serious attempts at the exercises, the challenge of which may be undone by a premature glimpse of an illustrated solution." And then Huggett and Jordan add a pithy bit of pedagogy: "If you want to be a pianist you don't just read music and listen to it, you play it." So there! The book ends with a brief but very nice discussion of the history of the subject, focussed on the menu served as the foregoing aperitif. This is a terrific book and I recommend it very highly. MAA Online "A Topological Aperitif provides a marvellous introduction to the subject, with many different tastes of ideas.Stephen Huggett and David Jordan have excellent credentials for explaining the beauty of this curiously austere but potentially enormously general form of geometry". Professor Sir Roger Penrose OM FRS, Mathematical Institute, Oxford, UK Be the first to write a customer review


