Dr. Valdebenito was born and raised in Chile, and earned a B.S. in Mathematical Engineering, and a diploma in Mathematical Engineering, from the University of Chile. Afterwards, he earned a M.Sc. and Ph.D. in Mathematics from the University of Minnesota. After postdoctoral work at McMaster University (Hamilton, Ontario, Canada) and the University of Tennessee (Knoxville, TN, U.S.A.), he joined 鶹ý as an assistant professor of mathematics.
In addition to his research experience, Dr. Valdebenito has taught mathematics at a college level for over 15 years, in a variety of educational settings (large and small classes, in person and online, in Spanish and English...), and strives to serve both the mathematical community (via peer-reviews, authoring reports for Mathematical Reviews) and the community at large.
Beyond mathematics, Dr. Valdebenito studied music for many years, plays the piano and has some basic singing skills. Dr. Valdebenito was a member of the tenor section of the Twin Cities Catholic Chorale, as well as of the schola at the Church of St. Agnes (St. Paul, MN), and the schola at Holy Ghost Church (Knoxville, TN). Beyond any formal studies, Dr. Valdebenito is interested in opera, the arts, history, planes, trains, and automobiles.
Dr. Valdebenito's research is focused on partial differential equations. Most of his research has revolved around spatial dynamics, in which elliptic equations (which are time-independent) are analyzed using techniques from dynamical systems (which are usually employed to study time-dependent equations). Recent research is concerned with studying the behavior of fluids with very low viscosity near the boundary, relative to the behavior of ideal fluids (with no viscosity), the so-called boundary layer problem.
Dr. Valdebenito's research is focused on partial differential equations. Most of his research has revolved around spatial dynamics, in which elliptic equations (which are time-independent) are analyzed using techniques from dynamical systems (which are usually employed to study time-dependent equations). Recent research is concerned with studying the behavior of fluids with very low viscosity near the boundary, relative to the behavior of ideal fluids (with no viscosity), the so-called boundary layer problem.
Sunny skies, warm temperatures, a beautiful campus. What more could you want? How about a community-like atmosphere, quality instructors who care about your success, a wealth of spiritual activities, expert career guidance… and that’s only the beginning. Imagine your future at AMU. It all starts by filling out our free application today.
ʱʳ