Professor of Mathematics Ira Gessel has been awarded a prestigious Simons Fellowship in Mathematics. He is part of the initial class of awardees for this fellowship, which will support research activities during his sabbatical leave in the spring of 2013. Other recipients included Math alumni János Kollár (PhD ’84), now at Princeton, and Irena Peeva (PhD ’95), now at Cornell.
Gessel awarded Simons Fellowship
November 16, 2012 By
Math graduate student training grant renewed
September 7, 2012 By
Mathematics Ph.D. students and faculty at Brandeis should be happy to learn that the department’s training grant from the US Dept. of Education’s Graduate Assistance in Areas of National Need (GAANN) program is being renewed for another three years. Training grants are a vital piece of the puzzle for supporting graduate education in the sciences, allowing Ph.D. students to focus on research.
Olivier Bernardi to Join Math Faculty
May 10, 2012 By
Dr. Olivier Bernardi will be joining the mathematics department in Fall, 2012 as a tenure-track assistant professor. Bernardi’s research interests lie in combinatorics and probability. He has worked on problems arising from mathematical physics (statistical mechanics and quantum gravity), computer science (algorithms and graph theory), and algebra (representation theory of the symmetric group). His Ph.D. thesis was on bijective approaches to the numeration of planar maps.
Bernardi received his Ph. D. in computer science in 2006 at the University of Bordeaux, under the direction of Mireille Bousquet-Mélou, and has worked as a postdoctoral researcher at the Center of Mathematical Research, Barcelona, Spain, and as a CNRS researcher in the Mathematics Department at Université Paris-Sud, in Orsay, France. He is currently an instructor in applied mathematics at MIT.
Six scientists secure fellowships
May 9, 2012 By
One current undergraduate, and five alumni, from the Brandeis Sciences were honored with offers of National Science Foundation Graduate Research Fellowships in 2012. The fellowships, which are awarded based on a national competition, provide three full years of support for Ph.D. research and are highly valued by students and institutions. These students are:
Samuel McCandlish ’12 (Physics) , a current student who did research with Michael Hagan and Aparna Baskaran, resulting in a paper “Spontaneous segregation of self-propelled particles with different motilities” in Soft Matter (as a junior). He then switched to work with Albion Lawrence for his senior thesis research. Sam will speak about “Bending and Breaking Time Contours: a World Line Approach to Quantum Field Theory” at the Berko Symposium on May 14. Sam has been offered a couple of other fellowships as well, so he’ll have a nice choice to make. Sam will be heading to Stanford in the fall to continue his studies in theoretical physics.- Briana Abrahms ’08 (Physics). After graduating from Brandeis, Briana followed her interests in ecological and conversation issues, and in Africa as a research assistant with the Botswana Predator Conservation Trust, Briana previously described some of her experiences here in “Three Leopards and a Shower“. Briana plans to pursue as Ph.D. in Ecology at UC Davis.
- Sarah Robinson ’07 (Chemistry). Sarah did undergraduate research with Irving Epstein on “Pattern formation in a coupled layer reaction-diffusion system”. After graduating, Sarah spent time with the Peace Corps in Tanzania, returning to study Neurosciene at UCSF.
- Si Hui Pan ’10 (Physics) participated in a summer REU program at Harvard, and continued doing her honors thesis in collaboration with the labs at Harvard. Her award is to study condensed matter physics at MIT.
- Elizabeth Setren ’10 was a Mathematics and Economics double major who worked together with Donald Shepard (Heller School) on the cost of hunger in the US. She has worked as an Assistant Economist at the Federal Reserve Bank of New York and her award is to study Economics at Harvard.
- Michael Ari Cohen ’01 (Psychology) worked as a technology specialist for several years before returning to academia as PhD student in the Energy and Resources Group at UC Berkeley.
Congratulations to all the winners!
American Academy of Arts & Sciences elects Turrigiano, Luo and Berger.
April 24, 2012 By
The American Academy of Arts & Sciences recently announced its 2012 class of Fellows, including 3 current and former Brandeis scientists.
Professor of Biology Gina Turrigiano and graduate alumnus Liqun Luo (PhD ’92, Biology) were elected in the Neurosciences, Cognitive Sciences, and Behavioral Biology section. Undergraduate alumna Bonnie Berger ’83 was elected in the Mathematics section.
Turrigiano’s lab works on the plasticity of synaptic and intrinsic properties of cortical neurons and circuits. Turrigiano has been previously honored with a MacArthur Fellowship and with the Human Frontier Science Program Nakasone Award for “frontier-moving research in biology“. Luo, who did his graduate research with Kalpana White at Brandies, is now Professor of Biology at Stanford University and an HHMI Investigator. His lab studies how neural circuits are organized and assembled during development. Berger discovered her interest and talent for math as an undergraduate at Brandeis, graduating with a degree in computer science. She obtained her PhD at MiT, where she is now Professor of Applied Mathematics and head of the Computation and Biology group at the MIT Computer Science and Artificial Intelligence Laboratory (CSAIL). Berger has continued to support Brandeis through her active membership in the Brandeis University Science Advisory Council.
The American Academy of Arts & Sciences elects leaders in the academic disciplines, the arts, business, and public affairs. Among the others elected this year are Mel Brooks, Clint Eastwood, Frederica von Stade, Melinda Gates and Hilary Clinton.
See also Brandeis NOW.
UPDATE (5/1/2012): Liqun Luo was elected to the National Academy of Sciences this year.
Eisenbud Lectures: “The Mathematics of Dynamic Random Networks”
November 21, 2011 By
This year’s Eisenbud Lectures in Mathematics and Physics will be given by Dr. Jennifer Chayes, Distinguished Scientist and Managing Director of Microsoft Research New England. Dr. Chayes is well known for her work on the phase transitions in combinatorial and computer science problems; she is a world expert on the study of random, dynamically growing graphs, which can be used to model real-world social and technological networks.
Dr. Chayes received her PhD in mathematical physics from Princeton. After postdoctoral fellowships at Harvard and Cornell, she was on the faculty at UC Los Angeles before co-founding the theory group at Microsoft Research in Redmond, Washington. In 2008 she co-founded Microsoft Research New England. She is a fellow of the American Association for the Advancement of Science, the Fields Institute, and the Association for Computing Machinery; she is also a National Associate of the National Academies.
The Eisenbud Lectures are the result of a generous donation by Leonard and Ruth-Jean Eisenbud, intended for a yearly set of lectures by an eminent physicist or mathematician working close to the interface of the two subjects. Dr. Chayes’ distinguished career working on fundamental issues in mathematics, physics, and computer science makes her an ideal speaker for this series.
The lectures will take place at 4 PM on Tuesday Nov. 29 and at 4:30 PM on Thursday Dec. 1. both in Abelson 131. A full description of the lectures can be found below. Driving directions, maps, links to the MBTA, and so forth can be found at: http://www.brandeis.edu/about/visiting/directions.html. If you need parking, please contact Catherine Broderick at cbroderi@brandeis.edu. A reception will be held after the first lecture on Tuesday November 29th from 5pm – 7pm in the Faculty Club Lounge at Brandeis. All are welcome.
Everybody should come out to hear this year’s lectures! They promise to be a lot of fun.
THE MATHEMATICS OF DYNAMIC RANDOM NETWORKS
During the past decade, dynamic random networks have become increasingly important in communication and information technology. Vast, self-engineered networks, like the Internet, the World Wide Web, and online social networks, have facilitated the flow of information, and served as media for social and economic interaction. I will discuss both the mathematical challenges and opportunities that exist in describing these networks: How do we model these networks – taking into account both observed features and incentives? What processes occur on these networks, again motivated by strategic interactions and incentives, and how can we influence or control these processes? What algorithms can we construct on these networks to make them more valuable to the participants? In this talk, I will review the general classes of mathematical problems which arise on these networks, and present a few results which take into account mathematical, computer science and economic considerations. I will also present a general theory of limits of sequences of networks, and discuss what this theory may tell us about dynamically growing networks.LECTURE 1: Models and Behavior of the Internet, the World Wide Web and Online Social Networks
Although the Internet, the World Wide Web and online social networks have many distinct features, all have a self-organized structure, rather than the engineered architecture of previous networks, such as phone or transportation systems. As a consequence of this self-organization, these networks have a host of properties which differ from those encountered in engineered structures: a broad “power-law” distribution of connections (so-called “scale-invariance”), short paths between two given points (so-called “small world phenomena” like “six degrees of separation”), strong clustering (leading to so-called “communities and subcultures”), robustness to random errors, but vulnerability to malicious attack, etc. During this lecture, I will first review some of the distinguishing observed features of these networks, and then discuss some of the models which have been devised to explain these features. I will also discuss processes and algorithms on these networks, focusing on a few particular examples.LECTURE 2: Convergent Sequences of Networks
In the second lecture of this series, I will abstract some of the lessons of the first lecture. Inspired by dynamically growing networks, I will ask how we can characterize general sequences of graphs in which the number of nodes grows without bound. In particular, I will define various natural notions of convergence for a sequence of graphs, and show that, in the case of dense graphs and even some sparse graphs, many of these notions are equivalent. I will also give a construction for a function representing the limit of a sequence of graphs. I’ll review examples of some simple growing network models, and illustrate the corresponding limit functions. I will also discuss the relationship between these convergent sequences and some notions from mathematical statistical physics.
