Iran has made considerable advances in science and technology through education and training, despite international sanctions in almost all aspects of research during the past 30 years. Iran's university population swelled from 100,000 in 1979 to 2 million in 2006. In recent years, the growth in Iran's scientific output is reported to be the fastest in the world. Iran has made great strides in different sectors, including aerospace, nuclear science, medical development, as well as stem cell and cloning research.
Throughout the history Persia was always a cradle of science, contributing to medicine, mathematics, astronomy and philosophy. Trying to revive the golden time of Persian science, Iran's scientists now are cautiously reaching out to the world. Many individual Iranian scientists, along with the Iranian Academy of Medical Sciences and Academy of Sciences of Iran, are involved in this revival.
Science in Persia evolved in two main phases separated by the arrival and widespread adoption of Islam in the region.
References to scientific subjects such as natural science and mathematics occur in books written in the Pahlavi languages.
The Qanat (a water management system used for irrigation) originated in pre-Achaemenid Persia. The oldest and largest known qanat is in the Iranian city of Gonabad, which, after 2,700 years, still provides drinking and agricultural water to nearly 40,000 people.
Persian philosophers and inventors may have created the first batteries (sometimes known as the Baghdad Battery) in the Parthian or Sassanid eras. Some have suggested that the batteries may have been used medicinally. Other scientists believe the batteries were used for electroplating--transferring a thin layer of metal to another metal surface--a technique still used today and the focus of a common classroom experiment.
Windwheels were developed by the Babylonians ca. 1700 BC to pump water for irrigation. In the 7th century, Persian engineers in Greater Iran developed a more advanced wind-power machine, the windmill, building upon the basic model developed by the Babylonians.
The 9th century mathematician Muhammad Ibn Musa-al-Kharazmi created the Logarithm table, developed algebra and expanded upon Persian and Indian arithmetic systems. His writings were translated into Latin by Gerard of Cremona under the title: De jebra et almucabola. Robert of Chester also translated it under the title Liber algebras et almucabala. The works of Kharazmi "exercised a profound influence on the development of mathematical thought in the medieval West".
Other Persian scientists included Abu Abbas Fazl Hatam, the Banu Musa brothers, Farahani, Omar Ibn Farakhan, Abu Zeid Ahmad Ibn Soheil Balkhi (9th century AD), Abul Vafa Bouzjani, Abu Jaafar Khan, Bijan Ibn Rostam Kouhi, Ahmad Ibn Abdul Jalil Qomi, Bu Nasr Araghi, Abu Reyhan Birooni, the noted Iranian poet Hakim Omar Khayyam Neishaburi, Qatan Marvazi, Massoudi Ghaznavi (13th century AD), Khajeh Nassireddin Tusi, and Ghiasseddin Jamshidi Kashani.
The practice and study of medicine in Iran has a long and prolific history. Situated at the crossroads of the East and West, Persia was often involved in developments in ancient Greek and Indian medicine; pre- and post-Islamic Iran have been involved in medicine as well.
For example, the first teaching hospital where medical students methodically practiced on patients under the supervision of physicians was the Academy of Gundishapur in the Persian Empire. Some experts go so far as to claim that: "to a very large extent, the credit for the whole hospital system must be given to Persia".
Several documents still exist from which the definitions and treatments of the headache in medieval Persia can be ascertained. These documents give detailed and precise clinical information on the different types of headaches. The medieval physicians listed various signs and symptoms, apparent causes, and hygienic and dietary rules for prevention of headaches. The medieval writings are both accurate and vivid, and they provide long lists of substances used in the treatment of headaches. Many of the approaches of physicians in medieval Persia are accepted today; however, still more of them could be of use to modern medicine.
In the 10th century work of Shahnameh, Ferdowsi describes a Caesarean section performed on Rudabeh, during which a special wine agent was prepared by a Zoroastrian priest and used to produce unconsciousness for the operation. Although largely mythical in content, the passage illustrates working knowledge of anesthesia in ancient Persia.
Later in the 10th century, Abu Bakr Muhammad Bin Zakaria Razi is considered the founder of practical physics and the inventor of the special or net weight of matter. His student, Abu Bakr Joveini, wrote the first comprehensive medical book in the Persian language.
After the Islamic conquest of Iran, medicine continued to flourish with the rise of notables such as Rhazes and Haly Abbas, albeit Baghdad was the new cosmopolitan inheritor of Sassanid Jundishapur's medical academy.
An idea of the number of medical works composed in Persian alone may be gathered from Adolf Fonahn's Zur Quellenkunde der Persischen Medizin, published in Leipzig in 1910. The author enumerates over 400 works in the Persian language on medicine, excluding authors such as Avicenna, who wrote in Arabic. Author-historians Meyerhof, Casey Wood, and Hirschberg also have recorded the names of at least 80 oculists who contributed treatises on subjects related to ophthalmology from the beginning of 800 AD to the full flowering of Muslim medical literature in 1300 AD.
Aside from the aforementioned, two other medical works attracted great attention in medieval Europe, namely Abu Mansur Muwaffaq's Materia Medica, written around 950 AD, and the illustrated Anatomy of Mansur ibn Muhammad, written in 1396 AD.
Modern academic medicine began in Iran when Joseph Cochran established a medical college in Urmia in 1878. Cochran is often credited for founding Iran's "first contemporary medical college". The website of Urmia University credits Cochran for "lowering the infant mortality rate in the region" and for founding one of Iran's first modern hospitals (Westminster Hospital) in Urmia.
In 1000 AD, Biruni wrote an astronomical encyclopaedia that discussed the possibility that the earth might rotate around the sun. This was before Tycho Brahe drew the first maps of the sky, using stylized animals to depict the constellations.
In the tenth century, the Persian astronomer Abd al-Rahman al-Sufi cast his eyes upwards to the awning of stars overhead and was the first to record a galaxy outside our own. Gazing at the Andromeda galaxy he called it a "little cloud" - an apt description of the slightly wispy appearance of our galactic neighbour.
Tusi believed that a body of matter is able to change but is not able to disappear entirely. He wrote "a body of matter cannot disappear completely. It only changes its form, condition, composition, color, and other properties, and turns into a different complex or elementary matter". Five hundred years later, Mikhail Lomonosov (1711-1765) and Antoine-Laurent Lavoisier (1743-1794) created the law of conservation of mass, setting down this same idea. However, it should be noted that Tusi argued for evolution within a firmly Islamic context--he did not, like Darwin, draw materialist conclusions from his theories. Moreover, unlike Darwin, he was arguing hypothetically: he did not attempt to provide empirical data for his theories. Nonetheless his arguments, which in some ways prefigure natural selection, are still considered remarkably 'advanced' for their time.
Jaber Ibn Hayyan, the famous Iranian chemist who died in 804 at Tous in Khorasan, was the father of a number of discoveries recorded in an encyclopaedia and of many treatises covering two thousand topics, and these became the bible of European chemists of the 18th century, particularly of Lavoisier. These works had a variety of uses including tinctures and their applications in tanning and textiles; distillations of plants and flowers; the origin of perfumes; therapeutic pharmacy, and gunpowder, a powerful military instrument possessed by Islam long before the West. Jabir ibn Hayyan, is widely regarded as the founder of chemistry, inventing many of the basic processes and equipment still used by chemists today such as distillation.
Abu Ali al-Hasan ibn al-Haytham is known in the West as Alhazen, born in 965 in Persia and dying in 1039 in Egypt. He is known as the father of optics for his writings on, and experiments with, lenses, mirrors, refraction, and reflection. He correctly stated that vision results from light that is reflected into the eye by an object, not emitted by the eye itself and reflected back, as Aristotle believed. He solved the problem of finding the locus of points on a spherical mirror from which light will be reflected to an observer. From his studies of refraction, he determined that the atmosphere has a definite height and that twilight is caused by refraction of solar radiation from beneath the horizon.
Kamal al-Din Al-Farisi (1267-1318) born in Tabriz, Iran, is known for giving the first mathematically satisfactory explanation of the rainbow, and an explication of the nature of colours that reformed the theory of Ibn al-Haytham. Al-Farisi also "proposed a model where the ray of light from the sun was refracted twice by a water droplet, one or more reflections occurring between the two refractions." He verified this through extensive experimentation using a transparent sphere filled with water and a camera obscura.
The Iranian Research Organization for Science and Technology and the National Research Institute for Science Policy come under the Ministry of Science, Research and Technology. They are in charge of establishing national research policies.
The government first set its sights on moving from a resource-based economy to one based on knowledge in its 20-year development plan, Vision 2025, adopted in 2005. This transition became a priority after international sanctions were progressively hardened from 2006 onwards and the oil embargo tightened its grip. In February 2014, the Supreme Leader Ayatollah Ali Khamenei introduced what he called the 'economy of resistance', an economic plan advocating innovation and a lesser dependence on imports that reasserted key provisions of Vision 2025.
Vision 2025 challenged policy-makers to look beyond extractive industries to the country's human capital for wealth creation. This led to the adoption of incentive measures to raise the number of university students and academics, on the one hand, and to stimulate problem-solving and industrial research, on the other.
Iran's successive five-year plans aim to realize collectively the goals of Vision 2025. For instance, in order to ensure that 50% of academic research was oriented towards socio-economic needs and problem-solving, the Fifth Five-Year Economic Development Plan (2010-2015) tied promotion to the orientation of research projects. It also made provision for research and technology centres to be set up on campus and for universities to develop linkages with industry. The Fifth Five-Year Economic Development Plan had two main thrusts relative to science policy. The first was the "islamization of universities', a notion that is open to broad interpretation. According to Article 15 of the Fifth Five-Year Economic Development Plan, university programmes in the humanities were to teach the virtues of critical thinking, theorization and multidisciplinary studies. A number of research centres were also to be developed in the humanities. The plan's second thrust was to make Iran the second-biggest player in science and technology by 2015, behind Turkey. To this end, the government pledged to raise domestic research spending to 3% of GDP by 2015. Yet, R&D's share in the GNP is at 0.06% in 2015 (where it should be at least 2.5% of GDP) and industry-driven R&D is almost non-existent.
Vision 2025 fixed a number of targets, including that of raising domestic expenditure on research and development to 4% of GDP by 2025. In 2012, spending stood at 0.33% of GDP.
In 2009, the government adopted a National Master Plan for Science and Education to 2025 which reiterates the goals of Vision 2025. It lays particular stress on developing university research and fostering university-industry ties to promote the commercialization of research results.
In line with the goals of Vision 2025, policy-makers have made a concerted effort to increase the number of students and academic researchers. To this end, the government raised its commitment to higher education to 1% of GDP in 2006. After peaking at this level, higher education spending stood at 0.86% of GDP in 2015. Higher education spending has resisted better than public expenditure on education overall. The latter peaked at 4.7% of GDP in 2007 before slipping to 2.9% of GDP in 2015. Vision 2025 fixed a target of raising public expenditure on education to 7% of GDP by 2025.
The result of greater spending on higher education has been a steep rise in tertiary enrollment. Between 2007 and 2013, student rolls swelled from 2.8 million to 4.4 million in the country's public and private universities. Some 45% of students were enrolled in private universities in 2011. There were more women studying than men in 2007, a proportion that has since dropped back slightly to 48%.
Enrollment has progressed in most fields. The most popular in 2013 were social sciences (1.9 million students, of which 1.1 million women) and engineering (1.5 million, of which 373 415 women). Women also made up two-thirds of medical students. One in eight bachelor's students go on to enroll in a master's/PhD programme. This is comparable to the ratio in the Republic of Korea and Thailand (one in seven) and Japan (one in ten).
The number of PhD graduates has progressed at a similar pace as university enrollment overall. Natural sciences and engineering have proved increasingly popular among both sexes, even if engineering remains a male-dominated field. In 2012, women made up one-third of PhD graduates, being drawn primarily to health (40% of PhD students), natural sciences (39%), agriculture (33%) and humanities and arts (31%). According to the UNESCO Institute for Statistics, 38% of master's and PhD students were studying science and engineering fields in 2011.
There has been an interesting evolution in the gender balance among PhD students. Whereas the share of female PhD graduates in health remained stable at 38-39% between 2007 and 2012, it rose in all three other broad fields. Most spectacular was the leap in female PhD graduates in agricultural sciences from 4% to 33% but there was also a marked progression in science (from 28% to 39%) and engineering (from 8% to 16% of PhD students). Although data are not readily available on the number of PhD graduates choosing to stay on as faculty, the relatively modest level of domestic research spending would suggest that academic research suffers from inadequate funding.
The Fifth Five-Year Economic Development Plan (2010-2015) fixed the target of attracting 25 000 foreign students to Iran by 2015. By 2013, there were about 14 000 foreign students attending Iranian universities, most of whom came from Afghanistan, Iraq, Pakistan, Syria and Turkey. In a speech delivered at the University of Tehran in October 2014, President Rouhani recommended greater interaction with the outside world. He said that 'scientific evolution will be achieved by criticism [...] and the expression of different ideas. [...] Scientific progress is achieved, if we are related to the world. [...] We have to have a relationship with the world, not only in foreign policy but also with regard to the economy, science and technology. [...] I think it is necessary to invite foreign professors to come to Iran and our professors to go abroad and even to create an English university to be able to attract foreign students.'
One in four Iranian PhD students were studying abroad in 2012 (25.7%). The top destinations were Malaysia, the USA, Canada, Australia, UK, France, Sweden and Italy. In 2012, one in seven international students in Malaysia was of Iranian origin. There is a lot of scope for the development of twinning between universities for teaching and research, as well as for student exchanges.
According to the UNESCO Institute for Statistics, the number of (full-time equivalent) researchers rose from 711 to 736 per million inhabitants between 2009 and 2010. This corresponds to an increase of more than 2 000 researchers, from 52 256 to 54 813. The world average is 1 083 per million inhabitants. One in four (26%) Iranian researchers is a woman, which is close to the world average (28%). In 2008, half of researchers were employed in academia (51.5%), one-third in the government sector (33.6%) and just under one in seven in the business sector (15.0%). Within the business sector, 22% of researchers were women in 2013, the same proportion as in Ireland, Israel, Italy and Norway. The number of firms declaring research activities more than doubled between 2006 and 2011, from 30 935 to 64 642. The increasingly tough sanctions regime oriented the Iranian economy towards the domestic market and, by erecting barriers to foreign imports, encouraged knowledge-based enterprises to localize production.
Iran's national science budget was about $900 million in 2005 and it had not been subject to any significant increase for the previous 15 years. In 2001, Iran devoted 0.50% of GDP to research and development. Expenditure peaked at 0.67% of GDP in 2008 before receding to 0.33% of GDP in 2012, according to the UNESCO Institute for Statistics. The world average in 2013 was 1.7% of GDP. Iran's government has devoted much of its budget to research on high technologies such as nanotechnology, biotechnology, stem cell research and information technology (2008). In 2006, the Iranian government wiped out the financial debts of all universities in a bid to relieve their budget constraints. According to the UNESCO science report 2010, most research in Iran is government-funded with the Iranian government providing almost 75% of all research funding. Domestic expenditure on research stood at 0.7% of GDP in 2008 and 0.3% of GDP in 2012. Iranian businesses contributed about 11% of the total in 2008. The government's limited budget is being directed towards supporting small innovative businesses, business incubators and science and technology parks, the type of enterprises which employ university graduates.
The share of private businesses in total national R&D funding according to the same report is very low, being just 14%, as compared with Turkey's 48%. The rest of approximately 11% of funding comes from higher education sector and non-profit organizations. A limited number of large enterprises (such as IDRO, NIOC, NIPC, DIO, Iran Aviation Industries Organization, Iranian Space Agency, Iran Electronics Industries or Iran Khodro) have their own in-house R&D capabilities.
Vision 2025 foresaw an investment of US$3.7 trillion by 2025 to finance the transition to a knowledge economy. It was intended for one-third of this amount to come from abroad but, so far, FDI has remained elusive. It has contributed less than 1% of GDP since 2006 and just 0.5% of GDP in 2014. Within the country's Fifth Five-Year Economic Development Plan (2010-2015), a National Development Fund has been established to finance efforts to diversify the economy. By 2013, the fund was receiving 26% of oil and gas revenue.
Much of the US$3.7 trillion earmarked in Vision 2025 is to go towards supporting investment in research and development by knowledge-based firms and the commercialization of research results. A law passed in 2010 provides an appropriate mechanism, the Innovation and Prosperity Fund. According to the fund's president, Behzad Soltani, 4600 billion Iranian rials (circa US$171.4 million) had been allocated to 100 knowledge-based companies by late 2014. Public and private universities wishing to set up private firms may also apply to the fund.
Some 37 industries trade shares on the Tehran Stock Exchange. These industries include the petrochemical, automotive, mining, steel, iron, copper, agriculture and telecommunications industries, 'a unique situation in the Middle East'. Most of the companies developing high technologies remain state-owned, including in the automotive and pharmaceutical industries, despite plans to privatize 80% of state-owned companies by 2014. It was estimated in 2014 that the private sector accounted for about 30% of the Iranian pharmaceutical market.
The Industrial Development and Renovation Organization (IDRO) controls about 290 state-owned companies. IDRO has set up special purpose companies in each high-tech sector to co-ordinate investment and business development. These entities are the Life Science Development Company, Information Technology Development Centre, Iran InfoTech Development Company and the Emad Semiconductor Company. In 2010, IDRO set up a capital fund to finance the intermediary stages of product- and technology-based business development within these companies.
As of 2012, Iran had officially 31 science and technology parks nationwide. Furthermore, as of 2014, 36 science and technology parks hosting more than 3,650 companies were operating in Iran. These firms have directly employed more than 24,000 people. According to the Iran Entrepreneurship Association, there are totally 99 parks of science and technology, which operate without official permits. Twenty-one of those parks are located in Tehran and affiliated with University Jihad, Tarbiat Modares University, Tehran University, Ministry of Energy (Iran), Ministry of Health and Medical Education, and Amir Kabir University among others. Fars Province, with 8 parks and Razavi Khorasan Province, with 7 parks, are ranked second and third after Tehran respectively. Iran has nearly 3,000 knowledge-based companies in 2016.
|Park's name||Focus area||Location|
|Guilan Science and Technology Park||Agro-Food, Biotechnology, Chemistry, Electronics, Environment, ICT, Tourism.||Guilan|
|Pardis Technology Park||Advanced Engineering (mechanics and automation), Biotechnology, Chemistry, Electronics, ICT, Nano-technology.||25 km North-East of Tehran|
|Tehran Software and Information Technology Park (planned)||ICT||Tehran|
|Tehran University and Science Technology Park||Tehran|
|Khorasan Science and Technology Park (Ministry of Science, Research and Technology)||Advanced Engineering, Agro-Food, Chemistry, Electronics, ICT, Services.||Khorasan|
|Sheikh Bahai Technology Park (Aka "Isfahan Science and Technology Town")||Materials and Metallurgy, Information and Communications Technology, Design & Manufacturing, Automation, Biotechnology, Services.||Isfahan|
|Semnan Province Technology Park||Semnan|
|East Azerbaijan Province Technology Park||East Azerbaijan|
|Yazd Province Technology Park||Yazd|
|Markazi Province Technology Park||Arak|
|"Kahkeshan" (Galaxy) Technology Park||Aerospace||Tehran|
|Pars Aero Technology Park||Aerospace & Aviation||Tehran|
|Energy Technology Park (planned)||Energy||N/A|
As of 2004, Iran's national innovation system (NIS) had not experienced a serious entrance to the technology creation phase and mainly exploited the technologies developed by other countries (e.g. in the petrochemicals industry).
In 2016, Iran ranked second in the percentage of graduates in science and engineering in the Global Innovation Index. Iran also ranked fourth in tertiary education, 26 in knowledge creation, 31 in gross percentage of tertiary enrollment, 41 in general infrastructure, 48 in human capital as well as research and 51 in innovation efficiency ratio.
According to the State Registration Organization of Deeds and Properties, a total of 9,570 national inventions was registered in Iran during 2008. Compared with the previous year, there was a 38-percent increase in the number of inventions registered by the organization.
Iran has several funds to support entrepreneurship and innovation:
The 5th Development Plan (2010-15) requires the private sector to communicate research needs to universities so that universities would coordinate research projects in line with these needs, with sharing of expenses by both sides.
Because of its weakness or absence, the support industry makes little contribution to the innovation/technology development activities. Supporting the development of small and medium enterprises in Iran will strengthen greatly the supplier network.
As of 2014, Iran had 930 industrial parks and zones, of which 731 are ready to be ceded to the private sector. The government of Iran has plans for the establishment of 50-60 new industrial parks by the end of the fifth Five-Year Socioeconomic Development Plan (2015).
A 2003-report by the United Nations Industrial Development Organization regarding small and medium-sized enterprises (SMEs) identified the following impediments to industrial development:
The economic complexity ranking of Iran has increased by 1 places over the past 50 years from 66th in 1964 to 65th in 2014. According to UNCTAD in 2016, private companies in Iran need better marketing strategies with emphasis on innovation.
Despite these problems, Iran has progressed in various scientific and technological fields, including petrochemical, pharmaceutical, aerospace, defense, and heavy industry. Even in the face of economic sanctions, Iran is emerging as an industrialized country.
Parallel to academic research, several companies have been founded in Iran during last few decades. For example, CinnaGen, established in 1992, is one of the pioneering biotechnology companies in the region. CinnaGen won Biotechnology Asia 2005 Innovation Awards due to its achievements and innovation in biotechnology research. In 2006, Parsé Semiconductor Co. announced it had designed and produced a 32-bit computer microprocessor inside the country for the first time.Software companies are growing rapidly. In CeBIT 2006, ten Iranian software companies introduced their products.Iran's National Foundation for Computer Games unveiled the country's first online video game in 2010, capable of supporting up to 5,000 users at the same time.
Theoretical and computational sciences are highly developed in Iran. Despite the limitations in funds, facilities, and international collaborations, Iranian scientists have been very productive in several experimental fields such as pharmacology, pharmaceutical chemistry, and organic and polymer chemistry. Iranian biophysicists, especially molecular biophysicists, have gained international reputations since the 1990s. High field nuclear magnetic resonance facility, microcalorimetry, circular dichroism, and instruments for single protein channel studies have been provided in Iran during the past two decades. Tissue engineering and research on biomaterials have just started to emerge in biophysics departments.
Considering the country's brain drain and its poor political relationship with the United States and some other Western countries, Iran's scientific community remains productive, even while economic sanctions make it difficult for universities to buy equipment or to send people to the United States to attend scientific meetings. Furthermore, Iran considers scientific backwardness, as one of the root causes of political and military bullying by developed countries over developing states. After the Iranian Revolution, there have been efforts by the religious scholars to assimilate Islam with modern science and this is seen by some as the reason behind the recent successes of Iran to augment its scientific output. Currently Iran aims for a national goal of self-sustainment in all scientific arenas. Many individual Iranian scientists, along with the Iranian Academy of Medical Sciences and Academy of Sciences of Iran, are involved in this revival. The Comprehensive Scientific Plan has been devised based on about 51,000 pages of documents and includes 224 scientific projects that must be implemented by the year 2025. The Science and Technology Department of the Iranian President's Office has released a book to review Iran's achievements in various fields of science and technology in 2017.
With over 400 medical research facilities and 76 medical magazine indexes available in the country, Iran is the 19th country in medical research and is set to become the 10th within 10 years (2012). Clinical sciences are invested in highly in Iran. In areas such as rheumatology, hematology, and bone marrow trasplantation, Iranian medical scientists publish regularly. The Hematology, Oncology and Bone Marrow Transplantation Research Center (HORC) of Tehran University of Medical Sciences in Shariati Hospital was established in 1991. Internationally, this center is one of the largest bone marrow transplantation centers and has carried out a large number of successful transplantations. According to a study conducted in 2005, associated specialized pediatric hematology and oncology (PHO) services exist in almost all major cities throughout the country, where 43 board-certified or eligible pediatric hematologist-oncologists are giving care to children suffering from cancer or hematological disorders. Three children's medical centers at universities have approved PHO fellowship programs. Besides hematology, gastroenterology has recently attracted many talented medical students. The gasteroenterology research center based at Tehran University of Medical Sciences has produced increasing numbers of scientific publications since its establishment.
Modern organ transplantation in Iran dates to 1935, when the first cornea transplant in Iran was performed by Professor Mohammad-Qoli Shams at Farabi Eye Hospital in Tehran, Iran. The Shiraz Nemazi transplant center, also one of the pioneering transplant units of Iran, performed the first Iranian kidney transplant in 1967 and the first Iranian liver transplant in 1995. The first heart transplant in Iran was performed 1993 in Tabriz. The first lung transplant was performed in 2001, and the first heart and lung transplants were performed in 2002, both at Tehran University of Medical Sciences. Iran developed the first artificial lung in 2009 to join five other countries in the world that possess such technology. Currently, renal, liver, and heart transplantations are routinely performed in Iran. Iran ranks fifth in the world in kidney transplants. The Iranian Tissue Bank, commencing in 1994, was the first multi-facility tissue bank in country. In June 2000, the Organ Transplantation Brain Death Act was approved by the Parliament, followed by the establishment of the Iranian Network for Transplantation Organ Procurement. This act helped to expand heart, lung, and liver transplantation programs. By 2003, Iran had performed 131 liver, 77 heart, 7 lung, 211 bone marrow, 20,581 cornea, and 16,859 renal transplantations. 82 percent of these were donated by living and unrelated donors; 10 percent by cadavers; and 8 percent came from living-related donors. The 3-year renal transplant patient survival rate was 92.9%, and the 40-month graft survival rate was 85.9%.
Neuroscience is also emerging in Iran. A few PhD programs in cognitive and computational neuroscience have been established in the country during recent decades. Iran ranks first in Mideast and region in ophthalmology.
Iranian surgeons treating wounded Iranian veterans during Iran-Iraq War invented a new neurosurgical treatment for brain injured patients that laid to rest the previously prevalent technique developed by US Army surgeon Dr Ralph Munslow. This new surgical procedure helped devise new guidelines that have decreased death rates for comatosed patients with penetrating brain injuries from 55% of 1980 to 20% of 2010. It has been said that these new treatment guidelines benefited US congresswoman Gabrielle Giffords who had been shot in the head.
Iran has a growing biotechnology sector that is one of the most advanced in the developing world. The Razi Institute for Serums and Vaccines and the Pasteur Institute of Iran are leading regional facilities in the development and manufacture of vaccines. In January 1997, the Iranian Biotechnology Society (IBS) was created to oversee biotechnology research in Iran.
Agricultural research has been successful in releasing high yielding varieties with higher stability as well as tolerance to harsh weather conditions. The agriculture researchers are working jointly with international Institutes to find the best procedures and genotypes to overcome produce failure and to increase yield. In 2005, Iran's first genetically modified (GM) rice was approved by national authorities and is being grown commercially for human consumption. In addition to GM rice, Iran has produced several GM plants in the laboratory, such as insect-resistant maize; cotton; potatoes and sugar beets; herbicide-resistant canola; salinity- and drought-tolerant wheat; and blight-resistant maize and wheat. The Royan Institute engineered Iran's first cloned animal; the sheep was born on 2 August 2006 and has passed the critical first two months of his life.
In the last months of 2006, Iranian biotechnologists announced that they, as the third manufacturer in the world, have sent CinnoVex (a recombinant type of Interferon b1a) to the market. According to a study by David Morrison and Ali Khademhosseini (Harvard-MIT and Cambridge), stem cell research in Iran is amongst the top 10 in the world. Iran will invest 2.5 billion dollars in the country's stem cell research over the next five years (2008-2013). Iran ranks 2nd in world in transplantation of stem cells.
In 2010, Iran begun mass-producing ocular bio-implants named SAMT. Iran began investing in biotechnological projects in 1992 and this is the tenth facility in Iran. 'Lifepatch' is the fourth bio-implant mass-produced by Iran after bone, heart valve, and tendon bio-implants. 12 countries in the world produce bio-tech drugs, which Iran is one of them. According to Scopus, Iran ranked 21st in biotechnology by producing nearly 4,000 related-scientific articles in 2014.
In 2010, AryoGen Biopharma established the biggest and most modern knowledge-based facility for production of therapeutic monoclonal antibodies in the region. As at 2012, Iran produces 15 types of monoclonal/anti-body drugs. These anti-cancer drugs are now produced by only two to three western companies.
In 2015, Noargen company established as first officially registered CRO & CMO in Iran. Noargen uses concept of CMO and CRO servicing to biopharma sector of Iran as its main activity to fill the gap and promote developing biotech ideas/products toward commercialization.
Iran had some significant successes in nuclear technology during recent decades, especially in nuclear medicine. However, little connection exists between Iran's scientific society and that of the nuclear program of Iran. Iran is the 7th country in production of uranium hexafluoride (or UF6). Iran now controls the entire cycle for producing nuclear fuel. Iran is among the 14 countries in possession of nuclear [energy] technology. In 2009, Iran was developing its first domestic Linear particle accelerator (LINAC). It is among the few countries in the world that has the technology to produce zirconium alloys. Iran produces a wide range of lasers in demand within the country in medical and industrial fields. In 2011, Iranian scientists at the Atomic Energy Organization of Iran (AEOI) have designed and built a nuclear fusion device, named IR-IECF. Iran is the 6th country with such technology.
Center of Excellence in Design, Robotics, and Automation was established in 2001 to promote educational and research activities in the fields of design, robotics, and automation. Besides these professional groups, several robotics groups work in Iranian high schools. "Sorena 2" Robot, which was designed by engineers at University of Tehran, was unveiled in 2010. The robot can be used for handling sensitive tasks without the need for cooperating with human beings. The robot is taking slow steps similar to human beings, harmonious movements of hands and feet and other movements similar to humans. Next the researchers plan to develop speech and vision capabilities and greater intelligence for this robot. the Institute of Electrical and Electronics Engineers (IEEE) has placed the name of Surena among the five prominent robots of the world after analyzing its performance. In 2010, Iranian researchers have, for the first time in the country, developed ten robots for the nation's automotive industry using domestic know how.
Ultra Fast Microprocessors Research Center in Tehran's Amirkabir University of Technology successfully built a supercomputer in 2007. Maximum processing capacity of the supercomputer is 860 billion operations per second. Iran's first supercomputer launched in 2001 was also fabricated by Amirkabir University of Technology. In 2009, a SUSE Linux-based HPC system made by the Aerospace Research Institute of Iran (ARI) was launched with 32 cores and now runs 96 cores. Its performance was pegged at 192 GFLOPS. Iran's National Super Computer made by Iran Info-Tech Development Company (a subsidiary of IDRO) was built from 216 AMD processors. The Linux-cluster machine has a reported "theoretical peak performance of 860 gig-flops". The Routerlab team at the University of Tehran successfully designed and implemented an access-router (RAHYAB-300) and a 40Gbit/s high capacity switch fabric (UTS). In 2011 Amirkabir University of Technology and Isfahan University of Technology produced 2 new supercomputers with processing capacity of 34,000 billion operations per second. The supercomputer at Amirkabir University of Technology is expected to be among the 500 most powerful computers in the world.
Research in nanotechnology has taken off in Iran since the Nanotechnology Initiative Council (NIC) was founded in 2002. The council determines the general policies for the development of nanotechnology and co-ordinates their implementation. It provides facilities, creates markets and helps the private sector to develop relevant R&D activities. In the past decade, 143 nanotech companies have been established in eight industries. More than one-quarter of these are found in the health care industry, compared to just 3% in the automotive industry.
Today, five research centres specialize in nanotechnology, including the Nanotechnology Research Centre at Sharif University, which established Iran's first doctoral programme in nanoscience and nanotechnology a decade ago. Iran also hosts the International Centre on Nanotechnology for Water Purification, established in collaboration with UNIDO in 2012. In 2008, NIC established an Econano network to promote the scientific and industrial development of nanotechnology among fellow members of the Economic Cooperation Organization, namely Afghanistan, Azerbaijan, Kazakhstan, Kyrgyzstan, Pakistan, Tajikistan, Turkey, Turkmenistan and Uzbekistan.
In 2007, Iranian scientists at the Medical Sciences and Technology Center succeeded in mass-producing an advanced scanning microscope--the Scanning Tunneling Microscope (STM). By 2017, Iran ranked 4th in nanotechnologies. Iran has designed and mass-produced more than 35 kinds of advanced nanotechnology devices. These include laboratory equipment, antibacterial strings, power station filters and construction related equipment and materials.
Iran recorded strong growth in the number of articles on nanotechnology between 2009 and 2013, according to Thomson Reuters' Web of Science. By 2013, Iran ranked seventh for this indicator. The number of articles per million population has tripled to 59, overtaking Japan in the process. Few patents are being granted to Iranian inventors in nanotechnology, as yet, however. The ratio of nanotechnology patents to articles was 0.41 per 100 articles for Iran in 2015.
On 17 August 2008, The Iranian Space Agency proceeded with the second test launch of a three stages Safir SLV from a site south of Semnan in the northern part of the Dasht-e-Kavir desert. The Safir (Ambassador) satellite carrier successfully launched the Omid satellite into orbit in February 2009. Iran is the 9th country to put a domestically-built satellite into orbit since the Soviet Union launched the first in 1957. Iran is among a handful of countries in the world capable of developing satellite-related technologies, including satellite navigation systems. Iran's first astronaut will be sent into space on board an Iranian shuttle by 2019. Iran is also the sixth country to send animals in space. Iran is one of the few countries capable of producing 20-25 ton sea patrol aircraft. In 2013, Iran constructed its first hypersonic wind tunnel for testing missiles and doing aerospace research. Iran is the 8th country capable of manufacturing jet engines.
The Iranian government has committed 150 billion rials (roughly 16 million US dollars) for a telescope, an observatory, and a training program, all part of a plan to build up the country's astronomy base. Iran wants to collaborate internationally and become internationally competitive in astronomy, says the University of Michigan's Carl Akerlof, an adviser to the Iranian project. "For a government that is usually characterized as wary of foreigners, that's an important development". In July 2010, Iran unveiled its largest domestically-manufactured telescope dubbed "Tara". in 2016, Iran unveiled its new optical telescope for observing celestial objects as part of APSCO. It will be used to understand and predict the physical location of natural and man-made objects in orbit around the Earth.
Iran has achieved the technical expertise to set up hydroelectric, gas and combined cycle power plants. Iran is among the four world countries that are capable of manufacturing advanced V94.2 gas turbines. Iran is able to produce all the parts needed for its gas refineries and is now the third country in the world to have developed Gas to liquids (GTL) technology. Iran produces 70% of its industrial equipment domestically including various turbines, pumps, catalysts, refineries, oil tankers, oil rigs, offshore platforms and exploration instruments. Iran is among the few countries that has reached the technology and "know-how" for drilling in the deep waters. Iran's indigenously designed Darkhovin Nuclear Power Plant is scheduled to come online in 2016.
Iran possesses the technology to launch superfast anti-submarine rockets that can travel at the speed of 100 meters per second under water, making the country second only to Russia in possessing the technology.Iran is among the five countries in the world to have developed ammunitions with laser targeting technology. Iran is among the few countries that possess the technological know-how of the unmanned aerial vehicles (UAV) fitted with scanning and reconnaissance systems. Iran is among the 12 countries with missile technology and advanced mobile air defense systems. Over the past years, Iran has made important breakthroughs in its defense sector and attained self-sufficiency in producing important military equipment and systems. Since 1992, it also has produced its own tanks, armored personnel carriers, sophisticated radars, guided missiles, a submarine, and fighter planes.
Iran annually hosts international science festivals. The International Kharazmi Festival in Basic Science and The Annual Razi Medical Sciences Research Festival promote original research in science, technology, and medicine in Iran. There is also an ongoing R&D collaboration between large state-owned companies and the universities in Iran.
Iranians welcome scientists from all over the world to Iran for a visit and participation in seminars or collaborations. Many Nobel laureates and influential scientists such as Bruce Alberts, F. Sherwood Rowland, Kurt Wüthrich, Stephen Hawking, and Pierre-Gilles de Gennes visited Iran after the Iranian revolution. Some universities also hosted American and European scientists as guest lecturers during recent decades.
Although sanctions have caused a shift in Iran's trading partners from West to East, scientific collaboration has remained largely oriented towards the West. Between 2008 and 2014, Iran's top partners for scientific collaboration were the USA, Canada, the UK and Germany, in that order. Iranian scientists co-authored almost twice as many articles with their counterparts in the USA (6 377) as with their next-closest collaborators in Canada (3 433) and the UK (3 318). Iranian and U.S. scientists have collaborated on a number of projects.
Malaysia is Iran's fifth-closest collaborator in science and India ranks tenth, after Australia, France, Italy and Japan. One-quarter of Iranian articles had a foreign co-author in 2014, a stable proportion since 2002. Scientists have been encouraged to publish in international journals in recent years, a policy that is in line with Vision 2025.
The volume of scientific articles authored by Iranians in international journals has augmented considerably since 2005, according to Thomson Reuters' Web of Science (Science Citation Index Expanded). Iranian scientists now publish widely in international journals in engineering and chemistry, as well as in life sciences and physics. Women contribute about 13% of articles, with a focus on chemistry, medical sciences and social sciences. Contributing to this trend is the fact that PhD programmes in Iran now require students to have publications in the Web of Science.
Iran has submitted a formal request to participate in a project which is building an International Thermonuclear Experimental Reactor (ITER) in France by 2018. This megaproject is developing nuclear fusion technology to lay the groundwork for tomorrow's nuclear fusion power plants. The project involves the European Union, China, India, Japan, Republic of Korea, Russian Federation and USA. A team from ITER visited Iran in November 2016 to deepen its understanding of Iran's fusion-related programmes.
Iran hosts several international research centres, including the following established between 2010 and 2014 under the auspices of the United Nations: the Regional Centre for Science Park and Technology Incubator Development (UNESCO, est. 2010), the International Centre on Nanotechnology (UNIDO, est. 2012) and the Regional Educational and Research Centre for Oceanography for Western Asia (UNESCO, est. 2014).
Iran is stepping up its scientific collaboration with developing countries. In 2008, Iran's Nanotechnology Initiative Council established an Econano network to promote the scientific and industrial development of nanotechnology among fellow members of the Economic Cooperation Organization, namely Afghanistan, Azerbaijan, Kazakhstan, Kyrgyzstan, Pakistan, Tajikistan, Turkey, Turkmenistan and Uzbekistan. The Regional Centre for Science Park and Technology Incubator Development is also initially targeting these same countries. It is offering them policy advice on how to develop their own science parks and technology incubators.
Iran is an active member of COMSTECH and collaborates on its international projects. The coordinator general of COMSTECH, Dr. Atta ur Rahman has said that Iran is the leader in science and technology among Muslim countries and hoped for greater cooperation with Iran in different international technological and industrialization projects. Iranian scientists are also helping to construct the Compact Muon Solenoid, a detector for the Large Hadron Collider of the European Organization for Nuclear Research (CERN) that is due to come online in 2008. Iranian engineers are involved in the design and construction of the first regional particle accelerator of the Middle East in Jordan, called SESAME.
Scientists with an Iranian background have made significant contributions 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 the medical community. The Vafa-Witten theorem was proposed by Cumrun Vafa, an Iranian string theorist, and his co-worker Edward Witten. The Kardar-Parisi-Zhang (KPZ) equation has been named after Mehran Kardar, notable Iranian physicist. Other notable discoveries and innovations by Iranian scientists and engineers (or of Iranian origin) include:
According to the Institute for Scientific Information (ISI), Iranian researchers and scientists have published a total of 60,979 scientific studies in major international journals in the last 19 years (1990-2008).
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