Science with an international dimension for Scientific and technological development in Amazonian.

Since Adam Smith discussed the role of scientific research in economic growth in the second half of the 18^th century, many changes in academic content, as well as changes in the way nations have passed to see science have occurred and continue to happen. In the second half of the 20th century, notably in the years 1990, disciplines of the so-called natural sciences linked with data processing technologies gave rise to new possibilities for scientific research could give unfolding to the creation of wealth. Emerging countries have structured Science and Technology systems and consequent consolidation of human capital training programs  with sufficient improvement to meet social demands and paradigmatic of the New society called modern, and currently postmodern, the first, identified with the Industrial Revolution and with the ideals of enlightenment, devised the promotion of progress through the incorporation of rationality principles, and the last, is conceived as cultural condition characterized by constant change in the pursuit of progress, that is, a process in which constant change became the Status Quo.

Universities have created the environment to think and breathe modernity, either in the social sense or when there is a need for the application of technologies. Scientific research, in this type of environment, assumes a critical role, because it is the path through which nations are suited to the pressing competitive atmosphere of postmodernity. In this environment, characteristic competitive markets and capital accumulation are indispensable, and the means of production operate the search for profits forcing the industrial system to offer innovations that are the result of targeted scientific research.

Many C & T systems are sampled worldwide, but only a few economies have managed to have a more marketable notion of scientific search. There are very robust systems with the concentration of high-capacity scientists and working in translational research groups - the USA with about 1.3 million researchers and China with about 1.7 million researchers, are Important examples (CNPq source).  However, there are efforts in developing countries that deserve prominence, as appears to be the case of Brazil and South Korea, where the C & T systems are still in consolidation. In Brazil, the system has not yet reached full maturity. Though their results demonstrated evolution, they still do not fully repay the investment already made.

The SCImago Research Group (2017) produced the classification of countries with scientific production between 1996 and 2017, where the USA appear first (H-index 2077), South Korea in twelfth Place (H-index 576) and Brazil in fifteenth place (H-index 489). These figures indicate that Brazilian production is among the first twenty most important impact indexes. However, between Brazil and the USA, there is a strong discrepancy, confirming that the H-index band shreds of evidence discoveries of cause and effect relationships that allow wider applicability, that is, answers more general questions.

SCImago Research Group still showed that 98% of Brazilian institutions producing scientific knowledge are below the averages of global citations, so the Brazilian leadership is still shy or nonexistent.

In an environment of economic competitiveness among nations, Brazilian indices define a concept of fragility. Our ability to generate economic development using the C & T Tools is incipient. This seems partly explained because of the budgetary instability for C & T; but when we look at the numbers of doctors formally inserted in institutions by area, we see some obliquities. In a universe of 140,000 doctors in the Brazilian institutions, the Humanities add up 34,136 doctors (24.3%), being the largest group of doctors in the national C & T system, while the engineering corresponds to 18,700 doctors (13.3%) (National Council for Scientific and Technological Development - CNPq source). In 2016, according to information from the Lattes Platform (CNPq), 900 doctoral titles were granted for engineering, and critical modalities such as transport engineer formed only 12 doctors, energy engineering formed 18 doctors, to name a few, while humanities formed 2,080 doctors in the same period. With this panorama, one can understand why Brazilian scientific researches have a low scientific and economic impact. Perhaps this is the motivator of the budgetary oscillations for this sector. A C & T system that resents engineers fatally will have timid economic reflexes, considering that the transposition of the bench scale to the industrial scale demands more doctors engineers than experts in humanities, without no longer consider the importance of this latter, but considering the construction of economically useful knowledge, that is, the economic strength of innovations. What we want to understand is that the National Knowledge Base, with clear deficits in Sectors of Human capital, doesn’t ensure fundamentally all Solutions companies need to ensure their competitiveness.

Universities versus Gross Domestic Product (GDP)

Between 2000 and 2010, according to Menezes Filho et al (2016), enrolments in Brazilian higher education courses increased by 102%, while the number of graduates included an increase of 135% in the same period. The authors attribute growth as a consequence of the expansion of higher education institutions (HEI), especially the private ones. The same authors affirm that universities can streamline regional economies for several reasons: (i) resource injection and generation of jobs in the local economy, (ii) increase in the qualification and productivity of workers and (iii) increase demand for Highly skilled workers (professors and researchers). Logically, investments in education mean savings in Human capital.

There are studies in the literature that indicate that there are returns of investment in education. In Brazil, the initial studies are from Langoni (1974), where generous rates of return of investments in terms of human capital and wages are shown. Mincer (1974) aggregates the natural logarithm of labor income to years of schooling, indicating a positive correlation between schooling and income in different countries, including Brazil.

On the other hand, studies have indicated that higher education levels are correlated with crime reduction (Lochner and Moretti, 2001) , control of fertility rates and improvement in quality of Health (Grossman, 2006), increase of political maturity (Glaeser, Ponzetto and Shleiffer, 2006) and a decrease in social discrepancies (Gradstein and Justman, 2002), proving that education produces social results that go far beyond the individual, producing gains for the welfare Collective bargaining.

Barbosa Filho & Pessoa (2008) undertake an effort in the line of estimation of the internal rate of return of education in Brazil by stages of teaching. They also find high rates of return for all stages, suggesting that even though an increase in enrolment and completion rates can be verified, the relative scarcity of human capital remains existing. The authors point out that though does not have the highest rate of return (due to the high costs), higher education is the stage with the highest prizes for the graduates.

From the person, the gain delivered by universities is lasting, providing better wages, improving skills to enable technological growth, a fact that will represent value aggregation to consumer goods with a reverberation to the economic sector. As savings in human capital grows, investment in education is expected to be overcome by economic return.

The short and medium-term effects arising from the presence of universities in the municipalities are extremely significant since young graduates undertake new businesses that, in turn, create an environment of more investments, generating an economic atmosphere that tends to consolidate. Even those young people who prefer a formal job produce a positive economic effect. Barbosa et al. (2015) estimate these effects by admitting that there are always gains for municipal economies.

Today's Brazil houses a significant number of universities and, according to the mapping made by the World Higher Education Database (whed/ www.whed.net) only the USA has a greater amount of Universities. The direct impact of the number of universities takes place on the abundance of money circulating where they are deployed. The concentration of universities with better performances in the south and southeast Brazilian regions (Brazilian Institute of Geography and Statistics - IBGE, 2009), for example, produces greater weight in the native gross domestic product (GDP) of the regions mentioned above. This means that universities are not enough, but they need to be large universities discerning regional vocations. In the case of Brazilian regions with more discreet contributions to national GDP, universities installed there, as a rule, produce important social modifications, however, the absence of a Layer of entrepreneurship in its curricular grids could generate less social dependence of the state, besides allowing greater scientific-social protagonism.

On the other hand, despite the importance of higher education in terms of offering and increasing qualification in social capital, there seems to be, generally, a distance between the current demands of the sector and updating the structural grids of the courses taught. In most of the educational and research institutions, the content discussed in the classrooms is not in line with the researchers conducted in the University laboratories themselves and neither is lined with the desires of the productive sector. In this sense, a consented espionage agreement between universities and industries it would be ideal. Universities spy that the technological bottlenecks are demanding academic assistance and industries would spy if the content taught to satisfy the constant transformations in the productive sector, inducing updates. Technological Parks could help, since they produce immediate approximation between the two universes, facilitating private investment in C & T. Such a situation is the reality in the English educational system, to cite an example.

In the case of graduate programs, we could discuss how to produce training more focused on the expectations of the productive sector. Besides, there is a need for more appropriate involvement in the paradigmatic issues of world interest, that is, scientific issues related to the security of the planet. Even programs with strong specificity should have a look at the large and complex questions that need translational responses. Such bias would increment the return on investments in higher densities.

In November 2016, André Cabette Fábio published an article in the Nexus newspaper (www.nexojornal.com.br) where it discusses the impact of universities on economic growth. Among the data displayed, one draws attention to what it represents: calculations generated in the United Kingdom (www.eprints.lse.ac.uk/67680/) realize that..."If new universities were deployed for each of the ten regions, this would increase the national income by 0.7%. Which means gains of £11bn (R$46 billion). A value is much higher than government spending, which would be £1.61 billion (R $6.7 billion). "

Scientific diplomacy

Innovations in information technologies at the beginning of the 21st century brought facilities in the use of massive amounts of data. Thus, a new trend concerning scientific and economic management seems to be imposed. The formation of national and international networks facilitated cooperation, and in the scientific context, networks can give rise to intrinsic competitions, with the generation of eventual conflicts of interest, even if they have been created for cooperation. The tendency, in these cases, is to seek mediation which can be attended by a science diplomat.

The process of science diplomacy has been established in several fields, but the notion that covers the term and the concept shows to be a field of studies for Interactions peaceful related to Knowledge production, using science as a tool for the benefit of mankind, and can be promulgated by scientists or scientific Enterprises (Davis and Patman, 2015; Tonami, 2016). However, it was President Eisenhower who covered the way for mankind to establish international spaces during the second half of the 20th century when it promoted the agreement today known with the Antarctic Treaty. There he established the concept of international spaces, which has been important to also delimit Scientific Diplomacy (Berkman, 2011).

Rice (2014) advocates that: Effective use of scientific advice in diplomacy requires international policymakers to have a minimum level of scientific literacy and requires scientists to communicate their work in an accessible and intelligible, context-sensitive way. Broader political.

It is therefore clear that this mediation must occur in a fluid communication environment, where diplomats and scientists demonstrate the cross -Knowledge of the respective work area. Such an arrangement will allow the use of the so-called soft power, which may contribute to building relationships international bilateral or multilateral with long-term benefits to soften any conflicts in relationship networks, as Dolan (2012).

The question of technological innovation goes beyond the scientific environment because it can hesitate in sovereignty limits. However, scientific diplomacy will make it easier for each country to meet its goals, share talents, and create new ideas and resources. Thus, according to Flink et al. (2010), three groups of objectives can be pursued: access, promotion, and influence. Consequently, there are a variety of actors who require diplomatic expertise to organize strategies to promote cooperation.

Arroz (2014) concludes that: More and more scientific diplomacy in collaboration with science and technology is decided to collaborate to attract the best students, researchers, and companies from all over the world. This intention could make the country more competitive by improving its reputation and making it more attractive for investment.

Conformation of networks exceeds isolations and may influence in the use of scientific diplomacy to assist in the talent attraction, financial resources, and political cooperation, helping to disseminate partners on the international scenario. “Associated with science there are norms such as rationality, deliberation, universalism[...] "(Arroz, 2014).

Looking back at the scientific environment in the Amazon region, we must think about the formation of scientists with an international dimension and that know establish bonds through diplomacy.

Considering that 60% of the area of Amazonian is in Brazilian territory, thinking about sustainable development requires the establishment of a scientific-diplomatic network, to be able to ideate continental planning. Any developmental action, individually planned by Amazonian countries, and without joint discussion of the objectives, could result in losses, especially concerning health environmental. For this reason, South American integration is essential to ensure that we have a sustainable future, and this notion goes through innovative and participative planning.

South American cooperation agreements can accelerate achievements in science and technology with their respective economic repercussions. One of the European countries that have taken the lead in the green economy is Germany (Christian Lutz et al., 2017), and for this reason, a teuto-amazonian approach should be of interest, particularly important for the economic model of the Manaus free zone. Such a partnership could to converge into a new perspective on the aggregation of value to biodiversity, clean energy, in addition to providing an atmosphere of innovation to local education and research institutions, improving, including the governance of natural heritage, in addition to enabling access to promising markets for innovation and development.

In this sense, the Brazilian Government should initiate actions to seek intermediations that allow, for example, the construction of transnational universities in the Brazilian Amazon. Obviously, the South American environment to cooperate in science and technology is still embryonic, but, it would be strongly recommended that they be made for the integration of human and scientific capital into the formulation of international policies for education, in order to form a continental educational system, similar to what is in the European Community, especially for the development of strategic partnerships aimed at reducing eventual environmental disasters by virtue of the individual priorities of the countries. In the case of the Brazilian Amazon, Fonseca(2017) suggested the creation of three new universities, one in the region of the tri-border Brazil, Peru and Bolivia, another in the region of Tefé in the middle Solimões river, and one last in the lower Amazon in the region of Parintins. If these universities were conceived with a transnational character, they would be necessary for important discussions on development and innovation, particularly in crucial matters such as transport, energy, communications, mining and green economy. However, there are other ways of fostering partnerships, such as the creation of international graduate courses with validity for the countries involved, as well as research and education involving one or more institutions of the Brazil and one or more foreign institutions within a country or region.

Scientific cooperation agreements brokered by diplomacy should be the next step in the search for new frontiers and ways to develop the Amazonian, favouring political and economic benefits, involving academics and diplomats to generate a continental science, as foreseen by Neureiter (2012), with a view to shaping the current generation and the next to the innovative translational scientific work, which provides for the formation of groups of transnational research.

Currently, international scientific cooperation is in the responsibility of universities, but requires even greater governmental attention, since scientific diplomacy will guide the strategies of transfers of technologies which, in some cases, require limits, considering that efficient technologies are not only political tools, but can be inflection points for wealth creation. It's important to remember that for South America, continental cooperation between emerging nations can open opportunities to face challenges and increment connectivity for competition in the global economy (Sweet, 2015). In This sense, scientific diplomacy is prominent and virtually transformative. Support for the development of consortia for international communication is crucial, especially for developing countries, so, scientific diplomacy can help to acquire common perceptions of problems and opportunities, that is, a way to relate global thinking to regional action, through the leverage of its scientific portfolios, infrastructure sharing, training of a globally engaged workforce and especially opportunities to scan the horizons to anticipate emergency development issues.

References

ARROZ, S. S. (2014). Diplomacia Cientifica: Justificações, Abordagens e Ferramentas de Uma Especialização Profissional Emergente. Dissertação de Mestrado, 57. Lisboa, Portugal: Universidade de Lisboa.

BARBOSA, M. P. (2015). Composição do capital humano, crescimento econômico e produtividade total dos fatores nos municípios brasileiros. Anais do XX Encontro Regional de Economia, Fortaleza.

BERKMAN, P. A. (2011). President Eisenhower, the Antarctic Treaty, and the Origin of International Spaces. Em M. A. Paul Arthur Berkman, Science diplomacy: science, Antarctica, and the governance of international spaces (pp. 17-28). Washington DC: Smithsonian Institution Scholarly Press.

DAVIS, L. A. (2015). Science Diplomacy: New Day or False Dawn? Singapore: World Scientific.

DOLAN, B. M. (2012). Science and Technology Agreements as Tools for Science Diplomacy: A U.S. Case Study. Science & Diplomacy, 1. Fonte: www.sciencediplomacy.org

FLINK, T. S. (2010). Science Diplomacy at the Intersection of S&T Policies and Foreign Affairs - Toward a Typology of National Approaches. Science and Public Policy, 7(9), 665–677.

FONSECA, C. R. V. (16 de Novembro de 2017). O RELATÓRIO 2015 DA UNESCO SOBRE CIÊNCIA E TECNOLOGIA E O PAPEL DETERMINANTE DA PESQUISA CIENTÍFICA PARA PANAMAZÔNIA. Acesso em 2019, disponível em http://www.artigos.com

GRADSTEIN, M., & JUSTMAN, M. (2002). Education, Social Cohesion and Economic Growth. The American Economic Review, 92, 1192-1204.

GROSSMAN, M. (2006). Education and Nonmarket Outcomes. Em E. HANUSHEK, & F. (. WELCH, Handbook of the Economics of Education (pp. 577–633). Amsterdam: Elsevier Science.

LANGE, F., & TOPEL, R. (2006). The Social Value of Education and Human Capital. Em E. HANUSHEK, & F. (. WELCH, Handbook of the Economics of Education, (Vol. 1, pp. 459–509). Amsterdam: Elsevier Science.

LANGONI, C. G. (1974). As Causas do Crescimento Econômico do Brasil. Rio de Janeiro: Apec.

LOCHNER, L., & MORETTI, E. (2001). The Effect of Education on Crime: evidence from prison inmates, arrests, and self-reports. National Bureau of Economic Research.

LUTZ, C., ZIESCHANK, R., & DROSDOWSKI, T. (2017). Measuring Germany’s Transition to a Green Economy. Low Carbon Economy, pp. 1-19.

MENEZES FILHO, N., OLIVEIRA, A. P., ROCHA, R. H., & KOMATSU, B. K. (Agosto de 2016). O Impacto do Ensino Superior Sobre o Trabalho e a Renda dos Municípios Brasileiros. Policy Paper, 20, pp. 1-40. Fonte: http://www.insper.edu.br/cpp/

MINCER, J. (1974). Schooling, Experience, and Earnings. National Bureau of Economic Research, Inc.

NEUREITER, N. (2012). Experts See Progress, Challenges in Advancing Science Diplomacy. American Association for the Advancement of Science. Fonte: www.aaas.org

SJR, SCImago (n.d.). (s.d.). SCImago Journal & Country Rank [Portal]. Fonte: SCImago: www.scimagojr.com

SWEET, A. (2015). “Science Diplomacy and the Small Advanced Economies Initiative. Auckland: NZILLA Christchurch Branch.

TONAMI, A. (2016). Asian Foreign Policy in a Changing Arctic. London: Palgrave Macmillan.