Science in newly industrialized countries

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Scientific research is concentrated in the developed world[1], with only a marginal contribution from the rest of the world. Most Nobel Laureates are either from United States or Europe. Many newly industrialized countries have been trying to establish scientific institutions, but with limited success. There is an insufficient dedicated, inspired and motivated labor pool for science and insufficient investment in science education. [2][3][4]

Contents

[edit] The limited success of Newly Industrialized Countries

The reason that there have been so few scientists, who have made their mark globally, from most NIC's (Newly Industrialized Countries) is partly historical and partly social [5] A true scientist is nurtured from the school up wards to scientific establishments. Only, if there are inspired and dedicated school science teachers in abundance, there will be sufficient number of inspired students who would like to take science as a career option and who may one day become a successful scientist.[6]

At present in newly industrialized nations, a school teacher most often belongs to one of the lower economic strata, that is, s/he does not get sufficient respect in the society which is essential to produce motivated and inspired teachers. Therefore there is little chance that a child would learn the art of asking questions and seeking their answers. Even if .001% of the large populations of any of these countries learns that art, there is seldom any scope for encouragement in the colleges or universities. Universities in most newly-industrialized countries do not fare as well as some universities in East Asia (e.g. Japan and Singapore), Canada, Oceania, USA or Western Europe, mainly because there are fewer opportunities for the meritorious; largely due to many prevalent social practices, nepotism is one of them.

A career in science is not as lucrative as one in management and administration. In addition, the investment in science education is sparse because the local industry does not find it profitable. This invariably leads to fewer academic positions and these few positions are invariably grabbed by people who have influence.

[edit] The common thread

A common thread can indeed be discerned in the state of science in many NIC's. Thus although, most of the science establishments in the major NICs can be said to be doing fairly well, none of them have been as successful as the developed countries. The genesis of this comparatively poor performance can in fact be traced to the history and culture of these countries. For example, the traditions in India, one of the leading newly industrialized countries are rooted in its caste system of its majority community namely the Hindus. The apparently poor performance of countries like Iran can be traced to the perception of science in Islam. An especially interesting fact is that although People's Republic of China as a nation has never produced a single native Nobel Prize recipient but there are a number of ethnic Chinese living in Western countries that have won Nobel Prizes (especially in physics),for example Steven Chu, Samuel C. C. Ting, Chen Ning Yang, Tsung-Dao Lee, Yuan T. Lee, Daniel C. Tsui, and Gao Xingjian.This further reinforces the idea that cultural factors,political stability and wealth are significant factors.During the Cultural Revolution in China (1966-1976),many academics and educated people were attacked,oppressed,humiliated and sent to the rural areas to do hard labour. The impact was severe and halted scientific progress in China.

Perhaps a possible hypothesis for this observation could be the political will of the industrialized countries, which may not be very comfortable with the challenge from NICs to their present dominant status in the world of science.

After the Second World War, a small technical elite arose in developing countries such as India, Pakistan, Brazil, and Iraq who had been educated as scientists in the industrialized world. They spear headed the development of science in these countries presuming that by pushing for Manhattan project-type enterprises in nuclear power, electronics, pharmaceuticals, or space exploration they could leapfrog the dismally low level of development of science establishments in their countries. India, for example, started a nuclear energy program that mobilized thousands of technicians and cost hundreds of millions of dollars but had limited success. Thus, although China, North Korea, India and Pakistan have been successful in deploying nuclear weapons and some of them e.g. China and India have launched fairly successful space program mes, for example, Chandrayaan I(Sanskrit चंद्रयान-1), which literally means "Moon Craft," is an unmanned lunar mission by the Indian Space Research Organization and it hopes to land a motorised rover on the moon in 2010 or 2011, as a part of its second Chandrayaan mission. Similarly Chang'e I, China's moon probing project is proceeding in full swing in a well-organized way. China's first moon probing is planned to be launched in three years. The mission includes a lunar orbiter as well as an impactor. The spacecraft will be launched by a modified version of the Polar Satellite Launch Vehicle. However, the fact remains that most of the scientists responsible for these deeds had received their terminal education from some institution/university in US or Europe. In addition there have been hardly any Nobel laureates in science who has conducted the path breaking research in a native science establishment.

[edit] Science in Brazil

Main article: Science and technology in Brazil

Brazilian science effectively began in the 19th century, until then, Brazil was a poor colony, without universities, printing presses, libraries, museums, etc. This was perhaps a deliberate policy of the Portuguese colonial power, because they feared that the appearance of educated Brazilian classes would boost nationalism and aspirations toward political independence.[7]

The first attempts of having a Brazilian science establishment were made around 1783, with the expedition of Portuguese naturalist Alexandre Rodrigues, who was sent by Portugal's prime minister, the Marquis of Pombal, to explore and identify Brazilian fauna, flora and geology. His collections, however, were lost to the French, when Napoleon invaded, and were transported to Paris by Étienne Geoffroy Saint-Hilaire. In 1772, the first learned society, the Sociedade Scientifica, was founded in Rio de Janeiro, but lasted only until 1794. Also, in 1797, the first botanic institute was founded in Salvador, Bahia. In the second and third decades of the twentieth century, the main universities in Brazil were organised from a set of existing medical, engineering and law schools. The University of Brazil dates from 1927, the University of São Paulo - today the largest in the Country - dates from 1934.

Today, Brazil has a well developed organization of science and technology. Basic research in science is largely carried out in public universities and research centers and institutes, and some in private institutions, particularly in non-profit non-governmental organizations. More than 90% of funding for basic research comes from governmental sources.

Applied research, technology and engineering is also largely carried out in the university and research centers system, contrary-wise to more developed countries such as the United States, South Korea, Germany, Japan, etc. A significant trend is emerging lately. Companies such as Motorola, Samsung, Nokia and IBM have established large R&D&I centers in Brazil. One of the incentive factors for this, besides the relatively lower cost and high sophistication and skills of Brazilian technical manpower, has been the so-called Informatics Law, which exempts from certain taxes up to 5% of the gross revenue of high technology manufacturing companies in the fields of telecommunications, computers, digital electronics, etc. The Law has attracted annually more than 1,5 billion dollars of investment in Brazilian R&D&I. Multinational companies have also discovered that some products and technologies designed and developed by Brazilians have a nice competitivity and are appreciated by other countries, such as automobiles, aircraft, software, fiber optics, electric appliances, and so on.

The challenges Brazilian science faces today are: to expand the system with quality, supporting the installed competence; transfer knowledge from the research sector to industry; embark on government action in strategic areas; enhance the assessment of existing programmes and commence innovative projects in areas of relevance for the Country. Furthermore, scientific dissemination plays a fundamental role in transforming the perception of the public at large of the importance of science in modern life. The government has undertaken to meet these challenges using institutional base and the operation of existing qualified scientists.[8]

[edit] Science in China

Main articles: Science and technology in the People's Republic of China and Science in China

A question that has been intriguing many historians studying China is the fact that China did not develop a scientific revolution and Chinese technology fell behind that of Europe. Many hypotheses have been proposed ranging from the cultural to the political and economic. Nathan Sivin [9] has argued that China indeed had a scientific revolution in the 17th century and that we are still far from understanding the scientific revolutions of the West and China in all their political, economic and social ramifications. Some like John K. Fairbank are of the opinion that the Chinese political system was hostile to scientific progress.

Needham argued, and most scholars agreed, that cultural factors prevented these Chinese achievements from developing into what could be called "science". It was the religious and philosophical framework of the Chinese intellectuals which made them unable to believe in the ideas of laws of nature. More recent historians have questioned political and cultural explanations and have focused more on economic causes. Mark Elvin's high level equilibrium trap is one well-known example of this line of thought, as well as Kenneth Pomeranz' argument that resources from the New World made the crucial difference between European and Chinese development.

Thus, it was not that there was no order in nature for the Chinese, but rather that it was not an order ordained by a rational personal being, and hence there was no conviction that rational personal beings would be able to spell out in their lesser earthly languages the divine code of laws which he had decreed aforetime. The Taoists, indeed, would have scorned such an idea as being too naive for the subtlety and complexity of the universe as they intuited it. Similar grounds have been found for questioning much of the philosophy behind traditional Chinese medicine, which, derived mainly from Taoist philosophy, reflects the classical Chinese belief that individual human experiences express causative principles effective in the environment at all scales. Because its theory predates use of the scientific method, it has received various criticisms based on scientific thinking. Even though there are physically verifiable anatomical or histological bases for the existence of acupuncture points or meridians, for instance skin conductance measurements show increases at the predicted points.

Today, Science and technology establishment in the People's Republic of China is growing rapidly. Even as many Chinese scientists debate what institutional arrangements will be best for Chinese science, reforms of the Chinese Academy of Sciences continue. The average age of researchers at the Chinese Academy of Sciences has dropped by nearly ten years between 1991 and 2003. However, many of them are educated in the United States and other foreign countries.

Chinese university undergraduate and graduate enrollments more than doubled from 1995 to 2005. The universities now have more cited PRC papers than CAS in the Science Citation Index. Some Chinese scientists say CAS is still ahead on overall quality of scientific work but that lead will only last five to ten years.

Several immigrant Chinese in USA have also been awarded the Nobel Prize,[10].Examples include Steven Chu, Samuel C. C. Ting, Chen Ning Yang, Tsung-Dao Lee, Yuan T. Lee, Daniel C. Tsui, and Gao Xingjian. Other overseas ethnic Chinese that have achieved success in sciences include Fields Medal recipient Shing-Tung Yau and Terence Tao, and Turing Award recipient Andrew Yao. Tsien Hsue-shen was a prominent scientist at NASA's Jet Propulsion Laboratory, while Chien-Shiung Wu contributed to the Manhattan Project (some argue she never received the Nobel Prize unlike her colleagues Tsung-Dao Lee and Chen Ning Yang due to sexism by the selection committee). Others include Charles K. Kao, a pioneer in fiber optics technology, and Doctor David Ho, one of the first scientists to propose that AIDS was caused by a virus, thus subsequently developing combination antiretroviral therapy to combat it. Dr. Ho was named TIME magazine's 1996 Man of the Year. However, the fact remains that many Chinese rue the absence of a native Chinese scientist among Nobel laureates, the genesis of which lies in the tradition laden culture.

[edit] Science in India

Main article: Science and technology in India

In India, contemplative science did indeed find a place in ancient Indian culture. The so called rishi’s and muni’s can indeed be called theoretical scientists. They contemplated on several natural phenomena and reached certain conclusions after careful thought. But, that was really long long ago, once the caste system became firmly established in the ancient Indian society there was little room left for rishis and munis. There place was taken by the Brahmins, whose primary function was to learn the thoughts of the rishi’s and muni’s and interpret their meaning to the ruling class. They excelled in remembering and reciting, not in original thought.

The earliest applications of chemistry in India took place in the context of medicine, metallurgy, construction technology (such as manufacture of cement and paints) and in textile production and dyeing. But in the process of understanding chemical processes, led to some theories about physical processes and the forces of nature that are today studied as specific topics within the fields of chemistry and physics. [11]

Even though, there was really no place for scientists in the Indian caste system; there are castes for the learned brahmins, the warriors kshatriyas, the traders vaishyas and the menial workers shudras, may be even the bureaucrats (the kayasths) and hardly any formal place in the social hierarchy for a people who discover new knowledge [12] or invent new devices based on the recently discovered knowledge, the scientific temper has always been in India, in the form of logic, reasoning and method of acquiring knowledge. Its therefore no wonder that some Indians quickly learned to value science, especially those belonging to the privileged Brahmin caste during the British colonial rule that lasted over two centuries. Some of them, like Satyendra Nath Bose, Megh Nad Saha, Jagdish Chandra Bose, C. V. Raman and Birbal Sahni also achieved phenomenal success. The science communication had begun with publication of a scientific journal, Asiatick Researches [13] in 1788. Thereafter, the science communication in India has evolved in many facets. Following this, there has been a continuing development in the formation of scientific institutions and publication of scientific literature. Subsequently, scientific publications also started appearing in Indian languages by the end of eighteenth century. The publication of ancient scientific literature and textbooks at mass scale started in the beginning of nineteenth century. The scientific and technical terms, however, had been a great difficulty for a long time for popular science writing. [14].

The colonial rule was indeed a blessing in disguise for the development of science and technology in India, as it is witnessed today. It thus facilitated the development of a Science and Technology establishment after India gained independence, especially under the visionary guidance of its first prime minister Jawaharlal Nehru. This legacy led to very successful career in science for many Non resident Indians, notable amongst them are Hargobind Khorana and S. Chandrasekhar who have won the Nobel Prize. However, the influence of Britishers that was once a blessing in disguise is proving as a road block for rapid growth, as most established scientists still rely on the approval from scientists from U.S or Europe before putting forth an opinion and it is hard for a young scientist to succeed unless s/he has the blessing from such an established scientist.

[edit] Science in Iran

Main article: Science in Iran

Iran (formerly known as Persia) has an extensive history, Persia was a Cradle of Science in earlier times. Persian scientists contributed significantly to the current understanding of nature, medicine, mathematics, and philosophy. Persians founded algebra, invented the wind-power machine, and discovered alcohol.

Although little is known about science in Iran during ancient times, in the Sassanid period (226 to 652 AD), great attention was given to mathematics and astronomy. The Academy of Gondeshapur was a prominent example in this regard. Sa'ad Andolsosi, in his book Classes of People, highly praised the knowledge of Persians in the subjects of mathematics and astronomy. In some books written in the Pahlavi languages, one comes across many references to scientific subjects such as the divinity, natural science, mathematics, and other relevant subjects.

In the year of 1000, Birooni wrote an astronomical encyclopaedia which discussed the possibility that the earth might rotate around the sun. This was long before Tycho Brahe drew the first maps of the sky, using stylized animals to depict the constellations.

The legacy of Alhazen who was highly instrumental in the founding of Modern Optics was continued by Ali Javan who invented the Gas laser. In the 13th century, Nasir al-Din Tusi developed a basic theory of evolution- more than 600 years before Charles Darwin. There are some key differences between Tusi's approach and Darwin's "The Origin of Species". While Darwin used deductive reasoning, gathering samples of plants and animals to work his way from facts to a theory, Tusi used a more theoretical approach. Tusi explained that "hereditary variability" was the leading force of evolution. He wrote that all living organisms were able to change and that the animate organisms developed owing to their hereditary variability: "The organisms that can gain the new features faster are more variable. As a result, they gain advantages over other creatures." This sounds remarkably like a simplistic form of Darwin's writings about mutations. Tusi was correct when he suggested: "The bodies are changing as a result of the internal and external interactions" - that is, as a result of environmental influences.

Today, scientists in Iran are trying to revive the golden time of Persian science. Many individual Iranian scientists along with Iranian Academy of Medical Sciences and The Academy of Sciences of Iran are involved in this revival. According to Institute for Scientific Information Iran has increased its publication output nearly tenfold from 1996 until 2004, and has been ranked first in terms of output growth rate (followed by China). Currently among the 146 top-performing countries in all fields, Iran is ranked 49 for citations, 42 for papers, and 135 for citations per paper.

Iran has made considerable advances through focusing on education and training. Despite sanctions in almost all aspects of research during the past few decades, Persian scientists have been producing cutting-edge science. The publication rate in international journals has quadrupled during the past decade. Although it is still low compared with the developed countries, this puts Iran in the first rank of Islamic countries. Despite the country's brain drain and its poor political relationship with the USA and some Western countries, Iran's scientific community remains productive, even while economic sanctions make it difficult for universities to purchase equipment or send people to the United States to attend scientific meetings.

Iran's university population has swelled from 100,000 in 1979 to 2 million in 2006. Some 70% of science and engineering students are women.

Theoretical and computational sciences are quite developed in Iran. Despite the limitations in funds, facilities, and international collaborations, Iranian scientists have been very productive in several experimental fields as pharmacology, pharmaceutical chemistry, and organic and polymer chemistry. Iranian scientists are also helping construct the Compact Muon Solenoid, a detector for CERN's Large Hadron Collider, due to come online in 2007. Iranian Biophysicists (especially molecular biophysics) have found international reputations since 1990's. Tissue engineering and research on biomaterials have just started to emerge in Biophysics departments. Recently in last months of 2006, Iranian biotechnologists announced that they, as a third manufacturer in the world, have sent CinneVex (recombinant type of Interferon b1a) to the market. Also, Royana, which is the first live cloned sheep in Iran, has survived over two months.

Iranian scientists contribute a great deal to the international scientific community. In 1960, Ali Javan invented first gas laser. In 1973, the fuzzy set theory was developed by Lotfi Zadeh. Iranian cardiologist, Tofy Mussivand, invented the first Artificial heart and afterwards developed it further. HbA1c was discovered by Samuel Rahbar and introduced to medical community. The Vafa-Witten theorem was proposed by Cumrun Vafa, Iranian string theorist and his co-worker Edward Witten. The KPZ equation has been named after Mehran Kardar, notable Iranian physicist.

[edit] Science in Korea

Main article: Science and technology in Korea

Development of Science and technology in Korea has closely paralleled that of overall economy, which has been almost completely dominated by chaebols and export-oriented industries. It started with hurriedly assembled hodgepodge of institutes and organizations focusing on reverse engineering, licensing and copying, imitations, and at times right-out pirating.

At the beginning of the 20th century, the words and concepts of science and technology were virtually non-existent in Korean society. Some science courses were taught in a couple of universities but only as purely academic subjects. It can be safely said, however, up until the early 1960s Korea was a nation with neither modern technologies nor scientific research and development infrastructure.

Korea's science and technology, did not exist, in any meaningful form, prior to the 1960s, it is said to be only four decades old, the time period that marks the beginning of Modern South Korea under the strongman rule of Park Chung Hee. As Korea embarked on its first major push for industrialization at that time, development of accompanying technologies became critical and the need for scientific infrastructure to support such efforts became imperative.[15]

[edit] The future

Several countries like India and China are already aware of the problem and have initiated many steps towards enhancing the enthusiasm of their youth towards science. India for example has a vibrant science talent search in place and many students have excelled in several international science competitions, like the one conducted by Intel.

[edit] References

  1. ^ Calestous Juma, Limits to South-South collaboration, <http://www.nature.com/wcs/c18.html>. Retrieved on 2007-12-21 
  2. ^ N. Gopal Raj (July 8, 2004), Universities and scientific research, The Hindu, <http://www.hindu.com/2004/07/08/stories/2004070801271000.htm>. Retrieved on 2007-12-21 
  3. ^ José Goldemberg ( 20 February 1998), What Is the Role of Science in Developing Countries?, vol. 279, Science, pp. 1140-1141, DOI 10.1126/science.279.5354.1140, <http://www.sciencemag.org/cgi/content/full/279/5354/1140>. Retrieved on 2007-12-21 
  4. ^ K. C. Garg & B. M. Gupta (May 10, 2003), “Decline in science education in India – A case study at + 2 and undergraduate level”, Current Science 84 (9), <http://www.ias.ac.in/currsci/may102003/1198.pdf>. Retrieved on 2007-12-21 
  5. ^ Philip G. Altbach (1992), “Higher education, democracy, and development: Implications for Newly Industrialized Countries”, Interchange (Netherlands: Springer) 23 (1-2): 143-163, ISSN 0826-4805 (Print) 1573-1790 (Online), DOI 10.1007/BF01435230, <http://www.springerlink.com/content/ug1831u70712195j/>. Retrieved on 2007-12-21 
  6. ^ “Institutional growth in the moulds of "national science"”, The uncertain quest: science, technology, and development, United Nations University Press, 1994, <http://www.unu.edu/unupress/unupbooks/uu09ue/uu09ue0j.htm>. Retrieved on 2007-12-21 
  7. ^ http://www.answers.com/topic/brazilian-science-and-technology[unreliable source?] (unreliable source: Wikipedia mirror)
  8. ^ José Galizia Tundisi, Science in Brazil, Government of Brazil, <http://www.mre.gov.br/cdbrasil/itamaraty/web/ingles/economia/ctec/panhist/apresent.htm>. Retrieved on 2007-12-21 
  9. ^ Think Ahead, university of New South wales \accessdate=2007-12-21, <http://hps.arts.unsw.edu.au/hps_content/new/sivin_new_sts.htm> 
  10. ^ Famous Chinese-Americans in Science and Technology, yellowbridge.com, <http://www.yellowbridge.com/people/science.html>. Retrieved on 2007-12-21 
  11. ^ History of Indian Science and Technology: History of Physics and Chemistry
  12. ^ What ails Indian science*
  13. ^ 1784 - Calcutta - Asiatic Society of Bengal - History of Scholarly Societies
  14. ^ Manoj Patairiya, Science Journalism in India, pantaneto.co.uk, <http://www.pantaneto.co.uk/issue25/patairiya.htm>. Retrieved on 2007-12-21 
  15. ^ Moo-Young Han, ANNOTATED CHRONOLOGY OF KOREA’S SCIENCE AND TECHNOLOGY; FROM RICE PADDIES TO FLAT PANEL DISPLAYS, self-published at Duke University, <http://www.duke.edu/~myhan/kaf0401.html>. Retrieved on 2007-12-21 [unreliable source?]

[edit] External links