To avoid system errors, if Chrome is your preferred browser, please update to the latest version of Chrome (81 or higher) or use an alternative browser.
Click here to login if you're an NAE Member
Recover Your Account Information
BY JOAN F. BRENNECKE
ROGER ANTHONY SCHMITZ, Keating-Crawford Professor Emeritus at the University of Notre Dame, died October 11, 2013, at the age of 78, after having been diagnosed with ALS earlier that year. Roger was born in Carlyle, a small ...
ROGER ANTHONY SCHMITZ, Keating-Crawford Professor Emeritus at the University of Notre Dame, died October 11, 2013, at the age of 78, after having been diagnosed with ALS earlier that year. Roger was born in Carlyle, a small town in Illinois, on October 22, 1934. After high school he went to work as a stock clerk in a local store and then started his own ice service. His entrepreneurial activities were soon interrupted when he was drafted into the US Army in November 1953 during the Korean War (although he spent most of his service in Germany).
When he was discharged in October 1955, Roger enrolled in the University of Illinois at Urbana-Champaign (UIUC) on the GI Bill, earning his BS in chemical engineering in 1959. Influenced by his undergraduate research with John Quinn, he went on to pursue his PhD in chemical engineering at the University of Minnesota, where he worked with Neal Amundson. Ever in a hurry, he defended his PhD after just three years, in 1962, and joined the UIUC chemical engineering faculty that same year.
Roger’s major research contributions were in the experimental observation of complex behavior in chemical reactions and catalysis. His work with Amundson involved theoretical predictions of mathematically very rich steady-state and dynamic behavior in chemical reactors. Roger and his 29 PhD and 37 MS students were the first to verify theoretical predictions of such complex behavior experimentally. He was the first to show multiple steady states in a stirred tank reactor and to demonstrate chaos in chemical reactions. His demonstration that multiplicities and instabilities in chemically reacting systems were real issues, not just theoretical ones, is the core of Roger’s research contributions.
Major awards for his research include a Guggenheim Fellowship (1968–1969), which he spent at CalTech and the University of Southern California; the Allan P. Colburn Award for Excellence in Publication by a Young Member of the Institute (1970) and the R.H. Wilhelm Award in Chemical Reaction Engineering (1981), both from the American Institute of Chemical Engineers; and, of course, election to the National Academy of Engineering (1984).
But his contributions to engineering go well beyond his research. In 1979 he moved to the University of Notre Dame as chair of the Department of Chemical Engineering and ushered in a fundamental transformation of the department. After only two years he became dean of the College of Engineering, where that same transformative energy impacted the rest of the college. And in 1987 he became vice president and associate provost of the university.
Roger was an early adopter of computing in chemical engineering, both for research and for undergraduate instruction, at a time when you had to do everything yourself, including writing code in machine language. He received the American Society for Engineering Education George Westinghouse Award in 1977 for the establishment of a computerized dynamics and digital control laboratory at the University of Illinois, the first of its kind nationally for undergraduates in chemical engineering.
At Notre Dame, he started a large-scale deployment of campuswide computing resources in 1985, providing state-ofthe-art Unix workstations for engineering and science faculty and students, graduate and undergraduate alike. This created some of the best computing infrastructure in the nation, as well as a culture change in the way many classes were taught.
In 1995 Roger returned to the department to teach a new course, for which he wrote an electronic textbook titled Ecological Models and Dynamics: An Interactive Textbook (Garland Science, 2008). He had always seen the mathematical connection between dynamic behavior in a diverse range of natural phenomena, from chemical reactions to heart fibrillations and predator-prey behavior. This course, still taught at Notre Dame, is an elegant exposition of that understanding.
Roger was an avid athlete. If he hadn’t been a chemical engineer, he surely would have been a baseball player. He was also a formidable opponent on the handball court and he loved running. But his pride and joy was his family. He married Ruth Kuhl in 1957 when he was an undergraduate at Illinois, and they had three wonderful daughters and seven grandchildren. Nothing was better than when he could combine his family with his passion for running, as in 2005, when three generations of his family placed first in their divisions at the annual Sunburst race in South Bend.
It is impossible to describe Roger’s career and contributions to our profession without the one word that describes him best—integrity. Scientific integrity: Roger designed and performed the most elegant experiments with care and curiosity. Professional integrity: Roger treated everyone with the utmost in honesty and fairness. He was the one that everyone went to for advice and counsel. Above all else, Roger could be trusted to tell you the truth. Personal integrity: Roger was the model of decency. This showed through his family and in all his interpersonal relationships. He battled ALS with courage, dignity, and humor. A visit with Ruth and Roger in his final weeks was nothing less than inspiring.
Roger A. Schmitz is the experimental verification of the theoretical prediction that good guys can finish first.