CHAPTER ONE
The Rise and Decline of Hegemonic Systems of Scientific Creativity
J. ROGERS HOLLINGSWORTH AND DAVID M. GEAR
ADDRESSING CREATIVITY at the level of a society has a long tradition, whether it be the ancient Greek city-state, sixteenth-century Florence, France during the Enlightenment, the United Kingdom during the Industrial Revolution, or other societies. In order to gain a fresh perspective on creativity in the contemporary world, this chapter extends the tradition by focusing on the rise and decline of creativity at the level of the nation-state during the past 250 years. Despite our focus on the societal level, we recognize that most acts of creativity occur at the level of the individual. But by aggregating acts of creativity, it becomes possible to analyze creativity at the level of a society, at the level of an organization (e.g., Bell Labs in the United States, the Laboratory of Molecular Biology in the United Kingdom, the Max-Planck Institutes in Germany; Rockefeller University in the United States), and at the level of a university department (e.g., physics at the University of Göttingen in the 1920s; the Cavendish Laboratory in Cambridge during much of the twentieth century).
Since the mid-eighteenth century, the most highly creative systems of science have been embedded only in those societies that were hegemons (from the ancient Greek word hegemon, meaning âleaderâ). A hegemonic power is one that exercises political, economic, and military supremacy over all other powers during a particular historic period. It was a societyâs economic, political, and military hegemonic power that gave birth to the creative scientific hegemon.
A scientific hegemon dominates multiple scientific fields and establishes the standards of excellence in most scientific fields. Its language is the major one used in scientific communication, and its scientific elite is the one most prominent in the world of science. It attracts more foreign young people for training than any other country. Its scientific culture tends to reflect societyâs culture. Scientific hegemons are embedded in societies that are economic, political, and military hegemonsâbut not all political, economic, and military hegemonic powers develop a hegemonic scientific system. However, modern hegemonic scientific systems exist only in societies that are political, economic, and military hegemons.
The process by which scientific hegemons emerged as well as declined varied from society to societyâalthough the underlying explanation was the same in each society. When their systems began to decline, the elites in scientific hegemons often failed to understand this fact; indeed, they tended to believe that their systems were continuing to perform extraordinarily well. Only as a result of a retrospective analysis was a hegemonic system of science observed to have been in relative decline.
Figure 1 is a representation of the rise and decline of four hegemonic systems of science since the middle of the eighteenth century: French, German, British, and American.
Figure 1. The Rise and Decline of Hegemonic Systems of Science
FRENCH HEGEMONY
From around 1735 until the mid-nineteenth century, France led the world in scientific creativityâparticularly in the fields of mathematics, physics, physiology, clinical medicine, zoology, and paleontology. A few of the most prominent French scientists of this period are listed in Table 1.
As France was a great power during the latter part of the eighteenth century, it is not surprising that it became a scientific hegemon. The worldâs leading scientific journals were published in France, the major scientific language was French, many of the worldâs most accomplished scientists were French, and large numbers of young people from all over Europe went to France for training. However, the turmoil brought about by the French Revolution and the military adventures of Napoleon Bonaparte had long-term negative effects on Franceâs military, economic, and scientific influence. Of course, the decline of Franceâs distinction in science did not occur all at once. Indeed, throughout the nineteenth century and even through the early years of the twentieth century, many of the worldâs most eminent scientists were French.
Franceâs role as a scientific hegemon did not decline simply because of its relative decline in military, economic, and political power. There were inherent contradictions in French society that had profound implications for its science. Part of the problem was the centralization of French government. Before and somewhat after the French Revolution, the centralization of France was significant in accelerating the rapid growth of Franceâs role in world affairs, including its system of science. But during the nineteenth and on into the twentieth century, centralization had an adverse effect on Franceâs ability to adapt to many of the radical innovations occurring elsewhere in the world, especially in the rest of Europe.
This was, of course, not true of all aspects of French society. Indeed, in the first half of the nineteenth century, outstanding scientific research occurred in the CollĂšge de France in Paris and in several of the grandes Ă©coles. Moreover, even as basic science in France declined during the nineteenth century, the society excelled in the development of large-scale technological systems. Jean-Baptiste Colbert, late in the seventeenth century, led France in making it a world leader in this area, a tradition that continued into the twentieth century with the development of French trains and aircraft. Colbert was a pioneer in developing applied science through government activity. As a result, the French state developed an excellent system of schools to train technocrats: the Ăcole des Mines, the Ăcole des Ponts et ChaussĂ©es, the Ăcole de GĂ©nie Militaire, and the world-renowned Ăcole Polytechnique. At the Ăcole Polytechnique the dominant epistemology emphasized deductive reasoning, complemented by rigorous mathematics.
However, partly because of its heavy investment in technological training in the development of large-scale projects, the French state underinvested in the training of young scientists. For the past several centuries, French society has long admired highly achieving individuals, but has been miserly in investing in the development of individual creativity. Throughout the nineteenth and twentieth centuries, the celebration of great scientists and other intellectuals was an important part of French culture. But among the four societies discussed in this essay, none was more parsimonious and lacking in foresight than France in providing individual scientists with the financial and organizational resources they needed for outstanding research.1 From the middle of the nineteenth century, while German universities were providing the finest equipment for laboratories, some of Franceâs greatest biomedical scientistsâFrançois Magendie, Claude Bernard, Charles-Ădouard Brown-SĂ©quard, Louis Pasteur, as well as Pierre Curie and Marie Curieâoften had to work under abominable conditions. It is a tribute to the French system of education, with its emphasis on individual brilliance and creativity, that these scientists performed so well despite their inadequately developed and underfunded research organizations. Over the years, scientists in France, in comparison with those in Germany, Britain, or the United States, more often than not had to operate in crowded laboratories, rely on obsolete equipment, and endure periodically the deleterious effects of inflation.
Even when the French government provided ample funding for laboratories, the method of governance was highly centralized. While there was some variation in the type of state-run organizations dedicated to researchâthe universities, the CollĂšge de France, hospitals, and the MusĂ©e de lâHistoire Naturelle (not a museum but a training and research center)âthese different organizations enjoyed little autonomy or flexibility, which naturally hampered their capacity to make major discoveries.
Numerous accounts have described how the French university system has long been embedded in a highly centralized ministry of education that determined salaries and promotions. Letters of evaluation were often written largely by friends and mentors. Historically, an enormous amount of favoritism and organizational nepotism had been present.2 Some of Franceâs most distinguished scientists expressed harsh criticism of the system: its lack of funds, the mediocrity of its science, its perpetuation of antiquated disciplines and its reluctance to develop new ones, and the incompetence of its administrative personnel. Pasteur, Bernard, and Adolphe Wurtz all wrote scathing reports on French science.
According to Terry Shinn, the files of applications of young people wishing to be trained as scientists became voluminous as the French government demanded information about the applicantsâ families. But the applications were then often filed away without any response to the applicant. In the meantime, buildings deteriorated: roofs leaked, floors flooded, and walls crumbled. There are many reports of insufficient light and lack of running water in laboratories; for lack of adequate storage facilities, equipment sometimes simply vanished. These conditions were obviously disincentives for young people thinking of becoming scientists, while many of those who had embarked on a career in science lost their ambition to conduct research.3
In areas of creative activity with few expectations of funding by the state, such as in the arts, France excelled. One has only to think of French literature, painting, and sculpture in the nineteenth century. But in science, after the first third of the nineteenth century, the centralized state stifled individual creativity, except in the service of large-scale collective projects. Coupled with the decline of French political and economic hegemony on the world stage, Franceâs capacity to remain a scientific hegemon was diminished.4
GERMAN HEGEMONY
From France the worldâs center of scientific creativity shifted to Germany, which became the worldâs scientific hegemon from about 1840 to the 1920sâa consequence of economic prosperity and a powerful political elite with a strong military organization. From the middle of the nineteenth century until the early twentieth century, twenty prominent German research universities emerged, and Germany had a far larger number of serious research universities than any other country. The new type of German university produced many of the worldâs most creative mathematicians, physicists, chemists, biochemists, and biologists. Germany had the worldâs best-equipped laboratories and scientific institutesâsuch as the Kaiser Wilhelm (later Max-Planck) Institutesâand growing science-based industries in pharmaceuticals, dyes, and vaccines. In the first eleven years of the Nobel Prizes, from 1901 onward, thirteen German scientists received awards in physics, chemistry, and physiology or medicineâmany more than any other nationality.
From 1880 until 1920, German science dominated numerous fields and established new standards of excellence. The leading scientific journals of the day were based in Germany, making German the major language for scientific communication. Germany attracted more foreign young people to study in its universities than any other country. Tens of thousands of young Americans traveled to Germany in the late nineteenth and early twentieth centuries for advanced trainingâa factor that led to the transformation of research in the United States.
However, like France, fundamental contradictions were built into both the culture of Germany and its science system, particularly its high level of authoritarianismâa factor that would later place constraints on the creativity of German science. Respect for authority in society facilitated the rapid emergence of German universities, but would ultimately be a factor in their relative decline. Because most university departments had only one professor, senior professors tended to incur heavy responsibilities for teaching across all fields in their particular discipline, limiting their ability to specialize, and heavy administrative burdens, limiting their time for research. In due course, creative research in most scientific disciplines began to level off. The increasing inability of German universities to create new disciplines necessitated the creation of the Kaiser Wilhelm Institutes in 1911, resulting in a surge of creative research, at least for a while.
The first institutes were in Dahlem, a suburb of Berlin. They were established in physics, in various fields of chemistry, and in the biological sciencesâall concentrated within a few hundred meters of each otherâwhich contributed to Dahlem becoming one of the most creative centers of science anywhere (see Table 2).
Among the scientists appointed to these institutes were Albert Einstein, Richard Goldschmidt, Fritz Haber, Otto Hahn, Lise Meitner, Otto Warburg, and others of great distinction. One most important attraction and facilitator of interaction among scientists at the Dahlem institutes were the âHaber colloquiaâ held every Monday afternoon. Among those frequently in attendance were the scientists mentioned above; more occasional attendees included Niels Bohr, Peter Debye, Selig Hecht, Max von Laue, Max Planck, Walther Nernst, Erwin Schrödinger, and Arnold Sommerfeld. Soon there were Kaiser Wilhelm Institutes in various parts of Germany, though none as creative as those in Dahlem.
The institutes would not have been possible without the hegemonic power of the German empire. Then Germanyâs political elites and military powers overreached themselves, resulting in Germanyâs defeat in the First World War, the loss of considerable territory, and a disrupted economy. By the early 1920s, all of these factors, combined with poor economic policies, resulted in some of the most disastrous inflation ever experienced in a modern economy, leading to the relative decline of German scientific hegemony even before the Nazis came to power in 1933.5 Of course, Germanyâs loss of status as a major power contributed to the emergence of the Nazi Party in the 1920s.
Yet even in the midst of the decline of a national scientific hegemon, scientific creativity may still occur in particular centers, as was clearly the case at the University of Göttingen in the 1920s. (See Table 3.) In that decade Göttingen became one of the most creative universities in the natural sciences of the entire twentieth century, encouraged by a high degree of communication among excellent scientists in diverse fields. Working there at the time were the internationally distinguished mathematicians Richard Courant, Edward Landau, and David Hilbert, as well as chemists Walther Nernst, Adolf Windaus, and Richard Zsigmondy, all three of whom received Nobel Prizes for work done mostly at Göttingen. Others at Göttingen were considered to be...