Technology for a Modern India
The governance of nanotechnology is marked by a strong role for the national government, and in particular for several influential individuals with prominent positions in both science and the government. The government first set up a funding scheme in 2001 and since 2007 a much larger amount of funding has been freed by the Planning Commission. In the same year, a new organization called the Nano Mission was established that was given the responsibility to govern nanotechnology. The Mission functioned under the Department of Science and Technology and distributed funding through two committees – a scientific and a technological advisory committee – that both were predominantly staffed by scientists and funded projects based on the academic merit of the proposals received.
How was nanotechnology governance mutually constructed with nation-building in this context? In the most basic sense the role of nanotechnology in nation-building helps to explain why India invests in nanotechnology: the role of nanotechnology in nation-building informed the objectives for nanotechnology governance. As mentioned, the first Indian investments in nanotechnology started in 2001, only a year after the announcement of the American National Nanotechnology initiative, when the Science and Engineering Research Council initiated a small funding programme (the Nano Science and Technology Initiative) in order to ‘feel the pulse’ and explore the possibilities for India to engage in this new field of research and development. At the time, however, larger funds could only be freed in India when they were included in Five Year Plans by the Planning Commission (a structure that has recently been replaced by the newly created Niti Ayog that created three-year action plans, seven year strategies, and 15-year vision documents). These Five Year Plans were the main vehicle for economic policy-making in India, a structure that builds upon post-independence ideas of economic planning. The Five Year Plans were drafted in a centralized and largely technocratic manner by the Planning Commission, chaired by the Prime Minister. As the process of drafting the Eleventh Five Year Plan (2007–2012) was underway, so one leading civil servant recalled, “it was (…) increasingly felt during this period that the national efforts were subcritical compared to the scale of nanotech R&D enterprise in most developed nations and even some developing nations” ([
40]:14–15). The Eleventh Five Year Plan subsequently included an expanded funding programme for nanotechnology with an outlay of 10 billion rupees, to be administered by the Department of Science and Technology. In the years that followed various other government departments followed suit with similar funding programmes.
The arguments supporting India’s investments in nanotechnology all point to the contribution nanotechnology can make to transforming India into a modern and developed nation. Nanotechnology, so the Five Year Plan notes, “represents a ‘make or break’ opportunity, capable of catapulting India into a high growth orbit and on a fast track to becoming a developed nation” ([
41]:252). These arguments draw upon a long-standing relation between science, technology and the nation in India that is commonly associated with Jawaharlal Nehru, India’s first Prime Minister. Hailing large dams as the ‘temples of modern India’, Nehru perceived of science and technology as essential tools for the newly independent nation to attain development and modernization [
42]. As Gyan Prakash notes in his wonderful book
Another Reason [
43], “emergence and existence of India is inseparable from the authority of science and its functioning as the name for freedom and enlightenment, power and progress” ([
43]:3). This narrative can perhaps be best captured by the oft-cited statement by Nehru that “it is science alone that can solve the problems of hunger and poverty, insanitation and illiteracy, of superstition and deadening custom and tradition, of vast resources running to waste, of a rich country inhabited by starving people” (quoted [
44]:564–565).
The unambiguously positive assessment of nanotechnology’s role for the Indian nation should not be taken for granted, however. As the historian of Indian science David Arnold has observed, “it would be erroneous to think of India as having a single scientific tradition” ([
45]:2). The relation between science, technology and the Indian nation is for instance marked by the postcolonial pendulum where modern science and technology were at times embraced as forces that could liberate India from the British Raj while at other moments are rejected as tools for colonial domination. In these latter cases, science and technology have been perceived as instruments of colonial oppression that may bring into being new dependencies towards their former colonizers. “Modern technology”, as another historian of science in India notes, “was always marked with the trace of the foreign. Yet true independence required self-reliance and indigeneity, especially in relation to technology” [
46]. The very same dams that Nehru considered as the modern temples of India are dismissed by these critics as incarnations of Western ideals that are ill-suited to the Indian context, wreaking havoc to local communities whose villages were displaced and whose own technologies for the provision and distribution of water and electricity were relegated to the museum [
47].
In the case of nanotechnology, however, the pendulum swings entirely the other way. On this side of the spectrum, modern science and technology are regarded as “the jewels in the crown of modernity” (Harding in [
48]:2). Nanotechnology was squarely put in this tradition and actors across the board put forward nanotechnology as a powerful technology that can contribute to turning India into a developed nation [
49]. Scientists from Indian research institutes were found claiming that “the possible impacts of nanotechnology will even go beyond those of the first Industrial Revolution” ([
50]:648), and former President Abdul Kalam (1931–2015) claimed in his biography that a conference he organized to bring together various nano-scientists was one of the most significant events in his presidency [
51], civil society organizations like The Energy and Resource Institute thought along these lines when highlighting the key challenges for India to be able to use nanotechnology to address key development-related challenges [
52], and industry actors – though not often speaking out on nanotechnology – talked about the technology’s contribution to India’s development whenever they did. Actors across the board embraced nanotechnology as an essential tool for India to become a developed nation. The reverse criticism that charts modern technology as a tool of Western oppression was almost entirely absent.
The way this idea of the Indian nation informed the objectives for nanotechnology governance can be better understood by having a closer look at the two most powerful actors in shaping the governance of Indian nanotechnology, C.N.R. Rao and Abdul Kalam. Both Rao and Kalam held key positions in both the scientific establishment and the government and exerted substantial influence on Indian nanotechnology. C.N.R. Rao, who is often referred to as the ‘nano-godfather’ of India, is a solid state chemist who had been working on nanotechnology since the early 1990s. Rao held various leading positions at Indian scientific institutes and he is widely accredited to be one of the most successful Indian scientists alive. His claims carried further authority in his function as chair of the scientific advisory council to the Prime Minister, a position he held from 1985 to 1989 under Rajiv Gandhi and later since 2005 under Manmohan Singh. Abdul Kalam, previously scientific advisor to the Prime Minister himself, was a physicist and aerospace engineer whose claims about the relation between India and nanotechnology carried similar authority, especially after being elected in the office of president of India in 2002, a post to which he served until 2007. Two authors from industry wrote in 2005 that “since his appointment as the President of the country, Dr. Kalam has been campaigning for programs to expedite the development and commercialization of nanotechnology in India” ([
53]289).
Both C.N.R. Rao and Abdul Kalam were influential in formulating the Five Year Plans and both repeatedly put nanotechnology forward as an essential field for India to engage in so as to become a modern and developed nation. In doing so, they strongly drew upon the Nehruvian view of India as a country for which modern science and technology are crucial to attain development. Kalam articulated this view most explicitly in the Technology Vision 2020, a large scale forecasting exercise led by Kalam that aimed at articulating what was required for India to ‘transform’ into a developed nation by 2020. Resonating with Nehru’s famous quote, the final roadmap document reads that ‘technology is the only vital input’ ([
54]:6). “Mastering of technologies,” so he wrote, “is the task to which the country and its people have to give importance. This can be considered to be the very essence of development” ([
54]:9). Nanotechnology was readily understood within this framework by Abdul Kalam. Whereas nanotechnology had not yet risen to prominence by the time the Vision 2020 was first published and hence is not mentioned in the document itself, Kalam explicitly referred to the vision when promoting nanotechnology, for instance noting that “nanotechnology research, development and commercialization will be important to transform India into a developed nation by 2020” (cited in [
55]).
Technology Development for Independence
The objectives for funding nanotechnology were thus partly pivoted upon a Nehruvian view of the nation as a developing nation that needs to engage with emerging technologies in order to attain development. The pro-active manner in which this occurred was further informed by notions of India as a nation that can only reap the benefits of technologies and attain development when developing those technologies themselves.
Although the idea that developing countries should develop emerging technologies increasingly finds support (e.g. [
56‐
58]), this also directly contrasts several well-established economic theories that outline the benefits for developing countries to wait until developed countries have conducted most high-risk fundamental research and subsequently adopt those technologies that may be of use locally (e.g. [
59]). Yet in the case of Indian nanotechnology, this pathway was not conceived to be open because not developing the technology itself was perceived to jeopardize their chances to reap the benefits of the technology. This anxiety was time and time again captured by describing nanotechnology with the metaphor of a train or a bus. Nanotechnology emerges as an unstoppable and fast moving train that is passing now and “if we miss it in the coming years, we will definitely lag behind” ([
60]:16–18). Whereas nanotechnology was almost unanimously embraced as a technology that could bring development to India, the possibility that India would indeed benefit from nanotechnology was premised on the condition that India makes an effort to board the train that will not pass again.
This uncertainty about the possibility to benefit from emerging technologies can be seen in other countries in different forms. In a very basic sense, the benefits provide the carrot while the uncertainty concerning the ability to reap those benefits provides the stick, both urging governments and industries to start investing in the promising technology. In Europe for instance nanotechnology benefits were considered attractive in a context where large parts of its industrial production have been outsourced to low-wage countries and innovativeness is considered its main source of competitiveness. The Lisbon Strategy most explicitly articulated this in the objective to become the most innovative economy in the world. Whereas the technology hence offers clear benefits, these are presented as conditional upon Europe’s ability to be more innovative than others. This implied that its investments in nanotechnology have to be considered in relation to efforts by other countries; Europe has to ‘stay ahead in the nano-race’ [
61], as the programme officer for nanosciences and technologies at the European Commission wrote.
The metaphor of a passing bus or train, however, also expresses the concern that India may fully miss out on the benefits. Contrary to a race, that Europe can merely fail to win, the Indian train can be missed in its entirety. This concern should be understood against the background of more recent entanglements of technology and the Indian nation. For instance take the technological projects that Abdul Kalam was involved in throughout his career, most notably the development of ballistic missiles, India’s first indigenously developed satellite, and the nuclear technology that eventually led to the series of controversial underground tests in May 1998. India was prompted into developing these technologies as it was caught in the Cold War logic that excluded India from the international exchange of dual use technologies. These achievements were widely celebrated in India, serving as public demonstrations of the ability of the Indian nation to overcome such foreign opposition to their use of the latest technologies. The day India performed its first nuclear tests, May 11, has since become the official National Technology Day and Kalam’s leadership in these projects were central in his election as President of India. As a flag-bearer in these projects, Abdul Kalam had first-hand experience in witnessing the unavailability of scientific and technological developments to India.
In the case of nanotechnology this relation between unavailable technology and the self-sufficient nation was repeatedly drawn upon. Also nowadays, so Kalam warned in 2012, the latest technologies “are not available from developed countries to India at least for a decade. Hence, research is vital, particularly in basic sciences, to take up India’s global competitiveness to the desired level” ([
51]:78). C.N.R. Rao similarly warned that India “should not be at the receiving end when the world is driven by nanotechnology. (…) The country must play a leading role in science” [
62]. India, in the context of nanotechnology, is thus constituted as a country that has to take care of itself in the face of foreign opposition, that needs to engage in the development of modern science and technology itself in order to have access to it. That nanotechnology was also interpreted in this light strengthened the urgency with which Indian actors set up funding schemes for the technology.
Science-Centered Governance
It was mentioned in section 3.1 that the Five Year Plans were the main mechanism for allocating government resources (before being replaced by the new structure). The Five Year Plans were drafted in a centralized and technocratic process and the main input for the allocation of funds for science and technology consisted of a report of a special steering committee on science and technology for the Eleventh Five Year plan. This report was prepared by the Office of the Principal Scientific Advisor to the Government of India, which was at the time headed by C.N.R. Rao. The Eleventh Five Year Plan stipulated the creation of an institute that would take charge of the governance of nanotechnology and distributed the funds that the Plan freed. The institute was called the Mission of Nano Science and Technology and is better known as the Nano Mission. The institute was launched on 3 May 2007 and was administered by the Department of Science and Technology. The Nano Mission was “an umbrella programme for capacity building” [
63] and had five formal objectives: basic research promotion, infrastructure development, human resources development, international collaboration, and applications and technology development. The responsibility for executing this funding programme was put in the hand of the Nano Mission Council, which was in turn supported by two subsidiary advisory groups: one focused on science and one on applications and technology. These two advisory groups were responsible for distributing the funds that were allocated to nanotechnology in the Five Year Plan.
A characteristic feature of the way the Nano Mission governed nanotechnology was its science-centered nature [
9]. First of all, with the exception of technology development, all objectives of the Nano Mission aimed first and foremost to build the capacity of Indian scientists to do fundamental research in the field of nanotechnology [
52,
62]. The great majority of funds were hence provided for fundamental research at universities and public research institutes. Secondly, in distributing the funding through a tendered system where actors could submit proposals in an open competition, the
scientific quality of the proposals was the main criterion. Other possibly relevant factors, such as the relation between the area of studies (like water, energy, or health) and national priorities (like food security, clean water, or employment) were not taken into consideration. And thirdly, it were predominantly scientists that were enabled to steer nanotechnology so that the technology could help turn India into a modern and developed nation. The Nano Mission Council was headed by C.N.R. Rao himself and consisted almost entirely of scientists and so did the scientific and technology advisory groups that eventually decided which projects did and did not receive funding.
It hardly requires elaboration that this is not the only way to govern emerging technologies. A great deal of theoretical work has been put into capturing the various ways in which the governance of science and technology has moved away from a science-centered basis and has become ever more intertwined with societal and industrial actors and objectives (e.g. [
64,
65]). This can also be seen in the case of nanotechnology, where governments around the world are involving industries, civil society organizations, and publics in the governance of nanotechnology. The Indian governance of science and technology is itself to some extent marked by a shift towards less science-centric forms of governance, as if for instance exemplified by the work of R.A. Mashelkar [
66,
67].
Efforts to move beyond science-centered governance of nanotechnology were not entirely absent in India. For instance the Department of Science and Technology took several steps to promote science-industry linkages: they organized conferences together with the Confederation of Indian Industry [
68] where scientists and industry could meet and they established a centre especially aimed at providing information services that supported industry and science collaborations. But at the end of the day, these efforts do not disguise the fact that the governance of nanotechnology is overwhelmingly science-centered.
Shortly after the launch of the Nano Mission their website already noted that “research on fundamental aspects of Nano Science and training of large number of manpower will receive prime attention” [
63] and this was reflected in the funding pattern. Whereas between 2001 and 2012 the scientific advisory groups of the Nano Science and Technology Initiative and later the Nano Mission funded 240 so-called ‘scientist-centric projects’ focused on fundamental research, in the same period the technology advisory group funded only seven projects focused on technology applications [
40]. Even if the scientific advisory group also funded a number of application-oriented projects, the share of these projects did not increase over time [
69], and the emphasis squarely remained on fundamental research. Many actors in India disagreed that this science-centric form of governance was the best way to go forward: the limited efforts to turn fundamental science into applications and to connect science to industry was the most hotly debated issue in Indian discussions about nanotechnology governance [
27].
This science-centered governance of nanotechnology is a tributary to linear notions of innovation but it also draws upon long-standing ideas of how science could best contribute to turning India into a developed nation. We have already seen that in the Nehruvian tradition, it is ‘science alone’ that can contribute to development and in governing science and technology this has been interpreted in the most literal sense. In the first two decades following Indian independence, scientists sought to implement the Nehruvian project by carving out an autonomous space for science [
70]. The argument was that the scientific progress required for India to turn into a developed country, was best achieved by leaving science alone. As historian of science Dhruv Raina described: “strategic areas of scientific research were protected from bureaucratic and political intervention; this created the illusion of the autonomy of science from the social institutions that legitimated it” ([
71]:360).
This was further perpetuated by notions of rationality and truth that were foundational for the Indian nation-state, as is perhaps best captured by the notion of ‘scientific temper’. This notion was introduced by Jawaharlal Nehru in 1946 and the aim to develop ‘scientific temper’ was even included in the Constitution of India as one of the fundamental duties of Indian citizens. The term referred to the ideal that citizens should adopt a scientific attitude to everyday life, which could help to overcome superstitions and religious beliefs that were perceived to hold back India’s development. While it has been pointed out that this denigrates Indian citizens by suggesting they themselves are responsible for their suffering because of their supposed lack of scientific temper (e.g. [
72]), the term simultaneously aimed to promote equality in a society that was marked by rigid inequalities and divisions along the lines of caste, religion, gender, and class. As several interviewees told me: one and one is two, regardless of whether one is a Hindu or Muslim. The notion of scientific temper thus puts forward India as a nation whose divisions could be bridged and whose backwardness could be overcome by science, on the premise that facts and values, science and politics could be strictly separated. The move to distinguish science from politics in the governance of nanotechnology thus emerged in the context of an Indian nation with potentially deep-rooted divisions that could be bridged by science.
In the case of nanotechnology governance the strict separation of science from politics was also visible in attempts to actively shape the Nano Mission as an expert body. While both the Nano Mission council and the two advisory groups consisted of both scientists from public research institutes and civil servants from the Department of Science and Technology, both the scientists and civil servants were explicitly referred to as scientists. This followed the practice of the Department of Science and Technology to exclusively staff this government department with scientists, not only by exclusively hiring people with a background in science, but also by referring to employees as scientists. For instance the rank of a civil servant is denoted with ‘scientist A’ (the starting level) up to ‘scientist H’ (a very high level civil servant). In their daily work these government employees functioned as civil servants but by continuously identifying them as scientists, a clear boundary was suggested between science and politics, thereby reaffirming that in India science is the exclusive domain of experts. As one civil servant explained to me: “All people in the Department of Science and Technology (…) are scientists. This ministry is not run by bureaucrats. This ministry is run by technocrats” (Interview, New Delhi, 7 November 2012).
The exclusive reliance on scientific criteria to judge the quality of proposals further built upon these ideas of the Indian nation whose unity and ability to attain development was premised on the autonomy of science. The nanotechnology funds were distributed on a competitive basis where scientists had to submit a proposal and orally defend this in front of the Nano Mission advisory groups. Both the scientific and technology advisory groups based their decision on the scientific quality of the proposal and the scientific track record of the researchers, without taking into account problems of national importance. While it may be suggested that the early stage of development of the field of nanotechnology may play a role here, this did not prevent other countries from governing nanotechnology in ways that tried to steer technology developments towards specific problems of national importance right from the start, as was for instance the case in countries like South Africa and the Netherlands [
49,
73]. Whereas in India the application-oriented projects that were funded increasingly revolved around applications in the domains of energy and health, there are no indications that this was a feature of governance itself. In contrast, as one senior scientist who was a member of both advisory groups mentioned in an interview: “in a group which is evaluating a research project, political considerations are never there. They are essentially driven by the academic merit of a project” (Interview, New Delhi, 10 December 2010). The science-centered way of governing nanotechnology hence cannot be understood without attending to the role of science (‘science alone’) and technology in Indian nation-building. Only by attempting to strictly exclude political considerations from decision-making could entrenched divisions be bridged and could science contribute to turning India into a developed nation.
Global Leadership
A final feature that characterizes the Indian governance of nanotechnology is that it is aimed at global leadership. This was first of all visible in that the success of Indian governance efforts were measured by comparing Indian achievements to those of other countries. C.N.R. Rao for instance repeatedly compared India to Europe, the United States, and China, noting that: “India is lagging behind the U.S. and Japan, where annually a couple of billion dollars are invested in nanotechnology research and development. Even China has a head start and is putting in a few hundreds of millions of dollars into its nanotechnology efforts” (cited in [
74]). And when evaluating the effects of governance measures, government officials and academics routinely referred to statistics that explicitly set off Indian achievements against those of other countries, at times in terms of funding, but predominantly in terms of scientific publications and patents (e.g. [
40,
75]). Such figures and comparisons construct nanotechnology as the subject of international competition, spurring India to invest in order to get a ‘piece of the pie’.
The production and use of internationally comparative numbers of nanotechnology output is itself part of technology governance as it enables decision-makers to adjust the way they steer the technology. This is certainly not an uncommon part of nanotechnology governance. In various European and North American countries this is for instance standard practice in the ‘nano-race’ [
76,
77]. And yet, in the Indian context, it should not be taken for granted. In the Indian context, where nanotechnology was pursued in order to transform from a developing into a developed country, one could easily imagine other ways to measure the extent to which nanotechnology contributed to this objective. For instance they could measure the effects of nanotechnologies on poverty reduction, on the provision of clean water and electricity, the expansion of capabilities of the poor, or other common development indicators. Instead, by putting the relative performance of India in terms of scientific publications and patents central, these statistics not only reiterate the science-centric nature of Indian nanotechnology governance, it also makes India’s achievements in the field of nanotechnology relative to the achievements of other countries, which subsequently serve as a yardstick to measure Indian success in nanotechnology.
What is more, despite explicitly describing India as a developing country, several scientists, commentators, and politicians, including C.N.R. Rao and Abdul Kalam, repeatedly cited the opportunity for India to be a leader in the field. On the one hand this was partly due to the novelty of the technology. In contrast to well-established technologies like semiconductors that would require substantial investments for India to even match other countries’ past achievements, nanotechnology was perceived to provide a more level playing field because also other countries were only beginning to discover technologies at the nano-scale. C.N.R. Rao argued that: “India has become one of the leaders in nanoscience and technology because this is an upcoming area where we are more or less on an equal footing with the rest of the world. (…) In nanoscience, we can become one of the leaders, if we try hard” ([
60]:16).
On the other hand the objective to be a leader in the field was also partly informed by the recently thriving ideas of India as a world leader. This feature of Indian nanotechnology governance is hence entangled with ideas of nation-building that strongly depart from Nehruvian views of the Indian nation. Since the 1991 economic reforms India has witnessed high rates of economic growth that have fed wide speculations of India becoming a global power (e.g. see [
78‐
80]). This has also spilled over to the domain of science and technology, with commentators characterizing India’s rise as the emergence of a ‘knowledge superpower’ (see [
81‐
86]). Even though India does not come close to match the United States, Europe and Japan on rankings of virtually all science and technology indicators, India did witness high growth rates in both research spending and scientific output. In 2002 researchers affiliated to Indian institutions published a total of nearly 19,000 publications whereas already in 2008 this had increased to over 36,000 [
87], and in 2014 this increased to over 53,000 [
88].
The ambition to become a world leader in nanotechnology emerged in the midst of this newly found optimism about India’s position in the world. Abdul Kalam for instances noted that “today we have an opportunity to take the leadership in the knowledge revolution” (cited in [
89]). And the steering committee on science and technology for the Eleventh Five Year Plan posited that “India must try to become a global innovation leader” ([
90]:7), citing nanotechnology as a prime example. Whereas the notion, outlined above, that nanotechnology can help to turn India into a developed nation is mainly concerned with the impacts or consequences of nanotechnology within India, the ambition to become a world leader through nanotechnology situates the Indian nation in a global arena where development is measured in relation to the technological advances of other nations. If India wanted to be a united country that could overcome superstition and religion and turn into a developed nation, a world leader even, then nanotechnology had to be pro-actively pursued to ensure access to the technology, its governance had to be left to scientific experts alone, and their success should be measured by comparing Indian achievements to those of other countries.