Donald Erik Sarason was an American mathematician who made fundamental advances in the areas of Hardy space theory and VMO. He was one of the most popular doctoral advisors in the Mathematics Department at UC Berkeley. He supervised 39 Ph.D. theses at UC Berkeley.
Sarason was awarded a Sloan Fellowship for 1969–1971. Sarason was the author of 78 mathematics publications spanning the fifty years from 1963 to 2013. Sarason was the sole author on 56 of these publications; the other 22 publications were written with a total of 25 different co-authors. The huge influence of Sarason’s publications on other mathematicians is reflected in unusually high citation rates. Google Scholar shows that Sarason’s publications have been cited over four-thousand times in the mathematical literature. Sarason wrote an amazing total of 456 reviews for Mathematical Reviews/MathSciNet. These reviews were published from 1970 to 2009. Teaching awards from UC Berkeley Mathematics Undergraduate Student Association, 2003 and 2006. At various times, served on the editorial boards of Proceedings of the American Mathematical Society, Integral Equations and Operator Theory, and Journal of Functional Analysis.
Selected works
1967. Generalized Interpolation in.
Sarason reproved a theorem of G. Pick on when an interpolation problem can be solved by a holomorphic function that maps the disk to itself; this is often called Nevanlinna-Pick interpolation. Sarason’s approach not only gave a natural unification of the Pick interpolation problem with the Carathoédory interpolation problem, but it led to the Commutant Lifting theorem of Sz.-Nagy and Foiaş which inaugurated an operator theoretic approach to many problems in function theory.
Sarason’s work played a major role in the modern development of function theory on the unit circle in the complex plane. In Sarason he showed that is a closed subalgebra of. Sarason’s paper called attention to outstanding open questions concerning algebras of functions on the unit circle. Then in an important 1975 paper that has since been cited by hundreds of other papers, Sarason introduced the space VMO of functions of vanishing mean oscillation. A complex-valued function defined on the unit circle in the complex plane has vanishing mean oscillation if the average amount of the absolute value of its difference from its average over an interval has limit as the length of the interval shrinks to. Thus VMO is a subspace of the set of functions with bounded mean oscillation, called BMO. Sarason proved that the set of bounded functions in VMO equals the set of functions in whose complex conjugates are in. Extensions of these ideas led to a spectacular description of the closed subalgebras between and in Chang and Marshall.
On June 19–23, 1978, Sarason gave a series of ten lectures at a conference hosted by Virginia Polytechnic Institute and State University on analytic function theory on the unit circle. In these lectures he discussed a number of recent results in the field, bringing together classical ideas and more recent ideas from functional analysis and from the extension of the theory of Hardy spaces to higher dimensions. The lecture notes, entitled Function Theory on the Unit Circle were made available by the math department at VPI. Though only available as a mimeographed document, they circulated widely and were very influential. Of all his publications, these lecture notes are the fifth most frequently cited according to the bibliographic database MathSciNet.
This influential book developed the theory of the de Branges–Rovnyak spaces, which were first introduced in de Branges and Rovnyak. Sarason pioneered the abstract treatment of contractive containment and established a fruitful connection between the spaces and the ranges of certain Toeplitz operators. Using reproducing kernel Hilbert space techniques, he gave elegant proofs of the Julia–Carathéodory and the Denjoy–Wolff theorems. Two recent accounts of the theory are Emmanuel Fricain and Javad Mashreghi and Dan Timotin.
This textbook for a first course in complex analysis at the advanced undergraduate level provides an unusually clear introduction to the theory of analytic functions.
