Margaret Robinson

she/her

  • Julia and Sarah Ann Adams Professor of Mathematics
Margaret Robinson

Margaret Robinson is a number theorist whose work combines analysis, algebra, and topology to understand number theoretic objects, in particular zeta functions. Questions about zeta functions and related L-functions lie at the very center of current mathematical research. Two of the Clay Mathematics Institute's seven Millennium Prizes -- often called the "Million Dollar Problems" after the prize money -- are offered for solutions to questions about zeta and L-functions: the Riemann Hypothesis and the Birch and Swinnerton-Dyer Conjecture. "The research I do is addictive," says Robinson, "because objects from other areas of mathematics arise like strange outcrops revealing unexpected constituents in the rock of number theory. Tracking down and explaining why these startling connections exist is tantalizing, sometimes frustrating, but never boring."

Robinson's research and reviews have appeared in the Bulletin of the American Mathematical Society, the Mathematics of Computation, and the Journal of Number Theory, among other publications. She is co-author, along with others in the Mathematics and Statistics Department at Mount Holyoke, of Laboratories in Mathematical Experimentation: A Bridge to Higher Mathematics, a laboratory text and accompanying instructor's manual based on a sophomore-level course developed and taught at Mount Holyoke.

Robinson has been principal investigator and co-principal investigator on a number of National Science Foundation (NSF), National Security Agency (NSA), and Mathematical Association of America (MAA) grants. Some of these grants funded Mount Holyoke's Summer Mathematics Institute, one of the oldest NSF funded Research Experiences for Undergraduates (REU) sites in the country. As part of the REU, Robinson has directed a number of undergraduate research groups. Projects have investigated: the Igusa local zeta function for elliptic curves using Tate's algorithm; the Igusa local zeta function for polynomials using their Newton polyhedra; the Fourier Transform, the Mellin Transform, and their relation to local zeta functions; the Bernstein b-function and local zeta functions.

In 2006, Robinson and her colleague Giuliana Davidoff were invited to deliver the Institute for Advanced Study's undergraduate lecture series as part of its Women and Mathematics Program Zeta Functions all the way.

Robinson served as chair of the Mathematics and Statistics department from 2002-2005. She has taught most courses in the undergraduate mathematics curriculum at Mount Holyoke, including: algebraic geometry; elliptic curves; number theory; laboratory in mathematical experimentation; explorations in fractals and chaos; explorations in number theory; making sense of biological signals (co-taught with Sue Barry, biology, and Mark Peterson, math/physics); real analysis; complex analysis; abstract algebra; design and analysis of experiments; differential equations; accelerated calculus; calculus I, II, and III.

Areas of Expertise

Number theory, zeta functions, p-adic analysis

Education

  • Ph.D., M.A., Johns Hopkins University
  • B.A., Bowdoin College

Happening at Mount Holyoke

Recent Campus News

Margaret Robinson, Julia and Sarah Ann Adams Professor of Mathematics at , was recognized for support and empowerment of women in the mathematics field.

hosted the annual Hudson River Undergraduate Mathematics Conference, which brings together faculty and students from the greater Hudson Valley region for a day of talks on and about the mathematical sciences.

Valerie Barr ’77, the first Jean E. Sammet Professor of Computer Science, shares with her benefactor an interdisciplinary vision of computing.

Recent Grants

Margaret Robinson PI with Co-PIs Giuliana Davidoff, Dylan Shepardson and Jessica Sidman (Mathematics) received a grant from the National Science Foundation (NSF) for “Collaborative Proposal: Hudson River Undergraduate Mathematics Conference 2020-2022” – with Keene and Siena Colleges. The project is for three years.

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