(this story was written in 1998)
On entering university, the Zeitgeist of the middle of the 20th century was the excitement of science - space exploration, transistors, lasers and DNA were being discovered, and I began my obsession with chemistry. During my teaching and research I have realised the importance of taking a broader interdisciplinary approach, as I believe that future discoveries in science will be made at the boundaries of different research areas.
During a visit to England last year, the time happened to coincide with the 60th anniversary of the Hove Grammar School for boys in Sussex, where I began my higher level education and first real exposure to the subject of chemistry. I was glad to be with over 300 Old Boys whose age ranged from close to 100 to about 40, and whose professions ended up being quite diverse. Quite a few boys had actually become academics and I learned of some, who like myself, emigrated to Canada. There were also a suprising number of boys who had made their million pounds. It was quite an eye-opener for me to learn how the change-over from the grammar to the comprehensive school system, not long after I had gone up to university, had altered the system. It saddened me to see how all the signs of an elite educational system had been purged from the school, including all the names of the boys who in my year, 1961, had been awarded State Scholarships to first rank universities, and who had been honoured with their names written in gold letters on a mahogany edifice. The happiest recollection of all was the discovery that my chemistry teacher, Mr. Charles Whone-Brown, was still in excellent health.
Prof. Ozin with his chemistry teacher
I obtained my undergraduate and postgraduate degrees at London and Oxford and was awarded an ICI postdoctoral fellowship to work on lasers in inorganic chemistry at Southampton University. I happened to be a student in an inorganic materials chemistry laboratory, but I was always intrigued by the physical-theoretical under-pinnings of inorganic chemistry, challenged by the demands of having to master a multi-analytical approach for measuring the properties of materials, enchanted with the synthetic aspects of creating new inorganic compounds, and excited at the prospect of determining their structures for the first time. During a stimulating four year research apprenticeship in the UK, I was exposed to a range of synthetic methods in main group aluminum, silicon, phosphorous and fluorine chemistry, and I learned how to handle gaseous, liquid and solid state materials under extreme conditions from cryogenic to high temperatures, and from low to high pressures. Meanwhile, I was captivated by the revolution in the new physical methods for characterising inorganic materials, I studied how to usefully apply various spectroscopy, diffraction, microscopy, theoretical and computational techniques for solving diverse problems in inorganic chemistry. This period of time for me was inspiring, it served to cement my research interests in inorganic chemistry.
I have always viewed teaching and research in chemistry from an integrated inorganic-physical perspective, and my personal research philosophy has been to embrace whatever physical and chemical methods were available and suitable at the time, to solve the particular problem at hand. My mentors and role models were outstanding teachers and researchers. These scholars inspired me to search continuously for high quality, significant, and timely scientific questions, they taught me the importance of seeing the relevance of one’s discoveries, they exposed me to the vitality of working at the forefront of a research field. My future was set to be an academic inorganic chemist. In 1969 I received an offer of an assistant professorship in inorganic chemistry at the University of Toronto. This provided me with the opportunity to inspire students in my lecturing, to develop the imagination, creativity, knowledge and skills of students in my research. I took on this task with gusto and joy, it was a major responsibility and a great honour to be able to contribute to the education, training, and eventually the careers of many highly skilled chemists in Canada.
Over the past thirty years of my teaching chemistry at the University of Toronto, with a particular emphasis on inorganic and materials chemistry, the paradigm of the field has undergone dramatic changes and the knowledge base has exploded. Inorganic textbooks of the day have changed from covering classical subjects like atomic and molecular structure, bonding theories, periodicity, spectroscopic methods, co-ordination compounds, ligands and stereochemistry, magnetism, reaction kinetics, thermodynamics and stability, and theoretical aspects, to stressing instead the importance of synthesis, particularly of organometallic, polymeric and solid state materials and their relevance to a wide variety of application areas. Modern day inorganic chemistry now traverses the boundaries of biology, medicine and physics as seen by the rapid growth of bioinorganic and inorganic materials chemistry. This significant shift in emphasis of the subject matter is reflected in modern inorganic textbooks, and is no doubt the correct response to the developments that have taken place over the past thirty years.
I have always been cognisant, throughout my almost three decades of teaching chemistry to undergraduate and graduate students at the University of Toronto, of the continuously changing face of the field of chemistry. Consequently, I have assigned a high priority to remaining current in my organisation and presentation of the inorganic chemistry curriculum, all the way from the introductory first year to the advanced graduate chemistry lecture and laboratory courses that I have taught. I have tried to be at the leading-edge of my field of inorganic research, and to accurately reflect the knowledge and excitement of the times in my lectures at every level, to inspire students about the amazement of chemistry, and to prepare them in the best possible way for the challenges that they will ultimately experience in the 21st. century. It is my job as a teacher and researcher to transmit, as accurately as possible, the necessary background and current knowledge of the field, from the fundamental scientific principles to the technological relevance of the subject, in such a way that excites, inspires and motivates students, to get them to see that the revolution is in chemistry, and that they should seriously consider chemistry as a career. I continue to learn from my teaching and teach to learn. This is my integrated teaching-research perspective of chemistry and it appears to have served both students and myself well over my years at the University of Toronto.
Throughout my tenure in the Chemistry Department, I have taught a great variety of chemistry subjects and courses at all levels. The breadth and depth of my undergraduate and graduate teaching contributions on both the St. George and Erindale campuses over the years, can be appreciated from inspection of the attached listing of my teaching assignments. I have re-vamped and taught introductory chemistry to physical scientists for five years, conceived and established entirely new second and third year inorganic chemistry courses and laboratories, created new advanced courses in cryochemistry, vibrational spectroscopy, paramagnetic resonance, symmetry, structural methods, and introduced, for the first time, modern materials chemistry and physical methods in materials chemistry, into the chemistry curriculum. The student evaluations of my teaching have generally been most positive.
I am especially delighted with the success of the inorganic materials chemistry program in the Chemistry Department since I introduced the subject more than a decade ago. The impressive growth and maintenance of undergraduate and graduate student numbers and interest in inorganic materials chemistry has stimulated the department to greatly expand its commitment in materials teaching, from the original fourth year course, to inject new materials topics into the first, second and third year inorganic chemistry courses, to include a new third year polymer-materials course as well as various graduate level courses in polymer and inorganic materials chemistry. This success has led to a significant increase in the complement of materials oriented research faculty in the chemistry department.
The cornerstone of my teaching and research in the rapidly expanding and vitally important area of materials chemistry is the design and synthesis of materials with new and improved properties. An important message to transmit to students, is how this knowledge will enable the development and manufacture of enhanced performance products and processes based upon the unique structures and properties of these materials. It is central to Canada’s technological and socio-economic future that students be cognisant of, and trained, in the modern strategies of synthesising, characterising and studying the relationships between the structures, properties, and functions of a diverse range of materials classes. Training in state-of-the-art solid state analytical and computational methods is an important co-requisite for teaching students how to make meaningful advances in materials chemistry and for remaining competitive in the field. I constantly impress upon students the synergy between materials chemistry and other fields, as a means to stimulate meaningful collaboration and to solve challenging multidisciplinary problems, while injecting insight and inspiration into materials research. I like to convey the idea that chemistry is the central science and that materials chemistry is a rapidly emerging subdiscipline of chemistry. It is a highly interdisciplinary field with great intellectual challenges and enormous practical consequences. Students learn that the knowledge and new classes of materials that are growing out of this fledgling branch of chemistry are now impacting research and development in physics, engineering, molecular biology, biomaterials, biotechnology, geology, metallurgy, environmental, computational and materials science. I always try to convey the excitement that materials research is the area of chemistry which creates the new materials, upon which the products and processes of tomorrow’s high technology society will depend.
In my materials courses the students learn that in order to respond to the global needs of advanced materials in the 21st. Century, chemists have had to change their way of thinking about the synthesis, structure, property relationships of solid state materials. Students soon discover that the synthesis paradigm is swinging away from a traditional “heat-and-beat, shake-and-bake” haphazard type of solid state chemistry, moving instead towards a contemporary “chemie douce, turning-down-the-heat” kind of soft chemistry, where the central tenet is the “intentional design” of materials. I am placing less emphasis on the classical inorganic solid state approach to electronic, optical, photonic, magnetic, dielectric, catalytic, separation, sensory, and mechanical materials, as these methods will not likely be able to address the performance requirements of advanced materials for the future. Instead I am beginning to introduce the student to the idea of materials synthesis based upon molecular design and organised self-assembly. Thus, as synthetic chemists are learning how to build well beyond the molecule, materials chemists are developing skills in molecular and crystal engineering. I like students to experience this modern trend towards “synthesis-with-construction” and “molecular tectonics”, a new approach to for example, supramolecular, polymeric, porous and composite materials. Students are confronted with, and excited by, the current thrust towards the design of intelligent materials and complex systems, that depend on the precise interplay between structure, organization and dynamics, in determining functional responses to environmental signals. I show how the interactive homeostatic milieu of biology teaches materials chemists much about these systems, and how this has led to exciting breakthroughs in the biomimicry of “soft” organic tissues like muscle and skin, and the “hard, stiff and tough” biomineralized structures found in bones and teeth. The students discover that materials chemists have much to learn from the evolution of biologies materials and that “biologies materials work”, when it comes for instance, to creating form with function and microstructure with purpose, in a synthetic laboratory setting. The reality is, that fascinating new materials can now be synthesised from the bottom-up and under mild reaction conditions compared to the top-down approach and extreme conditions of yesterday. The lessons of today are that molecule-by-molecule and layer-by-layer self-assembly techniques can now be applied to build “designer materials” with structure and dimensionality control over angstrom to centimeter length scales, and compositional command over most corners of the periodic table of the elements. Students learn of the power of the synthetic chemist whose job it is to dream-up new materials to solve a particular problem.
My teaching method is to illustrate with modern examples, how the synthesis, structure, property, function relationships of new generations of materials that are emerging from chemistry can be elegantly tailored to meet the growing needs of a knowledge-based society. This is my way of introducing the student to the real world of materials chemistry, through numerous case histories. These include, the oil and gas companies and the diverse range of catalytic materials that they use to produce fine chemicals, and efficient and environmentally friendly fuels; the biomedical community and the biomaterials that they use for the augmentation, replacement and repair of hard and soft tissues in humans; the medical profession and the materials utilised in the targeting and delivery of pharmaceuticals in the treatment of diseases; the processing industries and the sensory materials that they employ to recognise and detect small and large molecules crucial in the manufacture, preservation and quality control of their products; the space and transportation sectors and the metallic, polymeric and ceramic materials that they use to construct high strength and superior performance parts and machines; the semiconductor manufacturers and the metallo-organic chemical vapour deposition precursors and liquid crystalline materials that they use for assembling the infinity of electronic components on computer chips and the high resolution imaging devices in display systems; the telecommunication groups and the advanced glasses that constitute their fibre optic cables and networks which transmit digital data across offices, cities and continents every picosecond of every day; the computer industries and the every increasing density of magnetically and optically encoded information materials on their storage and processing devices; the recording companies and the semiconductor laser and nonlinear optical materials that they use in their disc readers and diskettes; the power corporations and the lightweight-high-energy-density battery materials designed to drive heart pacemakers reliably for more than ten years, and which are the workhorses for the clean electric cars of the future; and the numerous high technology industries that depend upon the new high temperature superconducting materials for non-invasive magnetic resonance imaging in medicine, power transmisssion cables free of resistive losses in cities, and perpetual motors to drive the boats, cars and trains of the next millenium. These examples are but a small taste of the multitude of creative gifts that materials chemistry has given to society, and I find that it is a particularly effective way of providing students with a direct appreciation of where modern materials are finding a niche in the world. Based on the positive responses of students to my materials chemistry courses over the years, this teaching approach appears to work well.
Extraordinary new materials demand equally powerful methods for their structural characterization, measurement of their properties, elucidation of their functions, and determination of their end-uses. Because of the rapid changes that have occurred in the physical aspects of the field, I have also designed complementary course material to encapsulate the spectacular advances in instrumental and computational methods that have accompanied the breathtaking developments in materials chemistry. This has formed the basis of a new materials course aimed at physical methods for solving problems in materials chemistry. This instrumental methods course has been designed to meet the needs of the student of materials chemistry who wishes to experience, first hand, the application of a wide range of diffraction, spectroscopy, microscopy, thermal, transport, and optical techniques, used routinely by the practising materials chemist, to investigate a diverse range of problems in the field. New analytical as well as small and large scale computational and graphical tools have permitted the materials chemist to attack more challenging questions. The student is introduced to these newer methods to get a flavour of how the results are proving relevant to many practical applications of materials and are pointing the way to new materials with desirable properties, functions and utilities.
The student emerges from these unified materials courses with the optimistic impression that the future of materials chemistry looks very bright and that it may represent a possible career in chemistry which they may not have considered before taking these courses. This is the greatest contribution that a teacher can make to his students.