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Alan G. MacDiarmid Nobel Prize in Chemistry 2000"for the discovery and development of conductive polymers"

He was born a Kiwi (a New Zealander) in Masterton, New Zealand on April 14, 1927, and he is still a Kiwi by New Zealand law, although He became a naturalized United States citizen many years ago in order to have the right to vote in US elections and, hence, voice his political opinions in a meaningful way. His father, an engineer, was unemployed for four years during the Great Depression which hit New Zealand rather severely in the early 1930s. Since jobs were believed to be more plentiful in the vicinity of Wellington, the capital city of New Zealand, located at the bottom of the North Island, he and his family moved to Lower Hutt a few miles from Wellington. There his two older brothers and his elder sister were able to find jobs while he and his younger sister were still at primary school. His parents set the stage for nurturing a warm, loving united, mutually supportive family who always pulled together and also helped others outside the family in need when necessary. Although they did not have too much food, his mother was always inviting other, less fortunate people to meals. On such occasions, his older brothers and sister would frequently remind him and his younger sister at meals not to ask for more food by saying to us out loud at the table, "FHB," which meant, "Family Hold Back," i.e., don't eat too much! They had no phone or refrigerator. In one of the houses they lived in Lower Hutt, their hot water came from water pipes embedded in the brick at the back of the open fireplace in the living room. This resulted in their weekly bath night - where the younger children used the bath water from the older children, to which we were allowed to add more hot water if any still remained! For most of his time at primary school, he went to school barefooted, like most of the other kids. The soles of our feet literally became leather! Even though he has been away from New Zealand for about 50 years, his brothers and sisters and he (his parents passed on several years ago) are still very closely connected to each other. Throughout the decades they have telephoned each other about every ten days and they keep up to date with what they are each doing. Shortly after learning of his being a recipient of the Nobel Prize he was speaking to one of his brothers in New Zealand by phone and he said how lucky he was to have been raised in a poor family which was also a close loving family. The fact that we were poor made them self reliant and conscious of the value of money. The fact that they were closely knit taught them the important aspects of interpersonal relationships. Everyone expects "the important things" in life that such as birthday and Christmas presents, but it is the "little unimportant" actions which actually are the real important things. These put the flesh on the skeleton of any relationship. Several hundred of these each week - the unimportant, the unexpected, the unnecessary, "the little things", are the things that really count. He says that they were lucky to have been brought up in this environment, but there is a statement on the wall of my study at home in suburban Philadelphia which reads, "I am a very lucky person and the harder I work the luckier I seem to be"! It is his home life while growing up through high school, which he consider to have been the single most important factor in any success which he may have had in life. As his parents always said, "...an 'A's grade in a class is not a sign of success." Success is knowing that you have done your best and have exploited your God-given or gene-given abilities to the next maximum extent. More than this, no one can do.

For a period in grade school, I attended a two-room school in Keri Keri (town population, 600) where most of my school chums were Maori boys and girls from whom I learned so much. During much of my time at grade school I had an early morning, pre-school job delivering milk on my bicycle for Mr. Bradley, who had a few cows in a nearby paddock. My mother was superb - she would get up with me while it was still dark to make me hot tea to send me on my way. When I started high school it was necessary to give up my Milk route. Instead, I delivered the "Evening Post" newspaper on my bicycle after school.

Alan (age 12) with bicycle. When my father retired (on a very small pension) and moved away from Wellington, it was necessary for me to leave Hutt Valley High School after only three years at the age of 16 and take a low-paying, part-time job as "lab boy"/janitor in the chemistry department at Victoria University College, as it was then known. The total student population was 1200; the Chemistry Department had a faculty of 2! I boarded with friends of my parents and, as a part-time student, took only two courses - one in chemistry and one in mathematics. During this time I became a resident at Weir House, the University dormitory for men. This I found to be one of the most enjoyable and maturing times of my life where I made many good friends from the other ninety residents, with some of whom I still keep in close contact. I remained a part-time student throughout my B.Sc. and M.Sc. studies at Victoria University College. After completing my B.Sc. degree I graduated to the position of demonstrator. Since the age of 17 I have supported myself financially, assisted later only by scholarships and fellowships for which I am most grateful.

My interest in chemistry was kindled when I was about ten years old at which time I found one of my father's old chemistry text books dating back to the late 1800's when he was studying engineering. I spent hours pouring over the pages in complete confusion but with burning curiosity! Some clarification of a type occurred when I rode my bicycle to the public library in Lower Hutt and entered the children's section. There, on the right hand side on the bottom shelf, in the new books section, was a book with a bright blue cover. It was called, "The Boy Chemist." I took it out and continually renewed it by borrowing it for over a year and carried out most of the experiments in it. One of my duties as lab boy, when I was not washing dirty labware or sweeping floors, was to prepare demonstration chemicals for Mr. A.D. "Bobbie" Monro, the lecturer in first-year chemistry. On one occasion he asked me to prepare some S4N4 - beautiful bright orange crystals. When it became time for me to start my M.Sc. thesis, I asked Mr. Monro if I could look at some of its chemistry. He agreed. This resulted in my first publication in 1949. Its derivatives were highly colored. Color continued to be one of the driving forces in my future career in chemistry. I love color. Little did I know that thirty years later this was going to be a key factor which would shape my professional life.

In 1950, I had the good fortune to receive a Fullbright fellowship from the U.S. State Department to do a Ph.D. at the University of Wisconsin in the USA where I studied under Professor Norris F. Hall, majoring in Inorganic Chemistry, studying the rate of exchange in 14C-tagged complex metal cyanides. It was at the University of Wisconsin that I became president of the International Club - the largest student organization on campus and had the crucial chance meeting of my life when I met my future wife, Marian Mathieu, at an International Club dance. During this time I was elected by the Department of Chemistry to the position of Knapp Research Fellow and had the privilege of living rent free in the beautiful old ex-governor's mansion on the shores of Lake Mendota. When I was still at the University of Wisconsin I was successful in obtaining a New Zealand Shell graduate scholarship to study silicon hydrides at Cambridge University, England under the directorship of Professor H.J. Emeléus. It was there that Marian and I were married in the chapel at my college, Sidney Sussex College. After a brief appointment as a junior faculty member at Queens College of the University of St. Andrews, Scotland, I accepted a junior position on the faculty of the Department of Chemistry at the University of Pennsylvania where I have been for the past 45 years and became father of three daughters and a son and grandparent of nine lovely boys and girls. I grew to love teaching and the stimulation of young fresh inquiring minds. I am still fully engaged in teaching as well as research and indeed have requested to teach a section of first-year chemistry at Penn later this year. I had the good fortune to meet my future friend and colleague, Professor Alan J. Heeger, Professor of Physics at the University of Pennsylvania. On one occasion he came to my office and informed me that Mort Labes, Professor of Chemistry at Temple University, had published a paper on a highly conducting material. I asked Heeger its formula and he replied, "sss-nnn-ex". Being an inorganic chemist, I wrote down on a piece of paper, "(Sn)x" and said, "Of course you expect it to be conducting, it's a metal!" To which Heeger replied on paper, "No, not (Sn)x, but (SN)x! This was the beginning of our each learning each other's scientific language. I told him that I had made the precursor to (SN)x, i. e. S4N4 during my M.Sc. thesis work in New Zealand. He asked me if I could make some (SN)x - as golden crystals. We were ultimately successful, and co-published many papers together, on this conducting polymer. When I was a Visiting Professor at Kyoto University in Japan, lecturing on molecular silicon compounds, I visited Tokyo Institute of Technology in 1975 and described our work on (SN)x, Hideki Shirakawa and I met over a cup of green tea after a lecture I gave and as I was showing a sample of our golden (SN)x, he showed me a sample of his silvery (CH)x. I asked him how he had made this silvery film of polyacetylene and he replied that this occurred because of a misunderstanding between the japanese language and that of a foreign student who had just joined his group. Shirakawa had been polymerizing ordinary acetylene welding gas using a Ziegler-Natta catalyst and had been obtaining a rather uninteresting black-brown powder. He told the new student to repeat this work using a concentration of the catalyst which was milli-molar. A few days later the student came back and said that the stirring bar would not go around in the flask. Shirakawa went to the laboratory and, sure enough, instead of the black brown powder, there were lumps of silvery-pinkish jelly floating around. Shirakawa asked what the student had done and the student replied that he had done exactly as Shirakawa had told him; he had made the catalyst with a concentration of "x-molar"- in other words, he had made the catalyst 1000 times more concentrated than Shirakawa had told him! Shirakawa was most intrigued by this observation, since as all good chemists know, a catalyst should only increase the rate of a chemical reaction and should not alter the nature of the product. This then started Shirakawa investigating this silvery form of polyacetylene. I asked Shirakawa if he could join me for a year at the University of Pennsylvania since I was already interested in conducting materials such as the golden (SN)x films. He stated that he could and when he arrived we tried to make the silvery polyacetylene, (CH)x, more pure and, hence, increase its conductivity. However, we found that the purer we made the (CH)x, by elemental analysis, the lower was its conductivity! Since we had found previously that by adding bromine to the golden (SN)x material, we could increase its conductivity tenfold, we thought that perhaps the impurity in the polyacetylene was acting as a dopant and was actually increasing the conductivity of the polyacetylene, rather than decreasing it. We therefore decided to add some bromine to the silvery (CH)x films and immediately, within a few minutes at room temperature, the conductivity increased many millions of times. We then collaborated with my colleague, Professor Alan Heeger, who was well-versed in the physics of conducting materials. The rest is history! When Alan left Penn almost 10 years ago, my ongoing collaboration with my good friend Professor Art Epstein (Physics Dept, Ohio State Univ.) continued at an even more rapid pace.