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Well it is a myth that unbelievers own science and are smarter.Th truth is Israel is leader in all the field science, due that God is with them.Watch this:Science and technology in Israel is one of the country's most developed sectors. Israel spent 4.2% of its gross domestic product (GDP) on civil research and development in 2013, one of the highest ratios in the world.[1][2] Israel ranks fifth among the most innovative countries in the Bloomberg Innovation Index.[3][4] It ranks thirteenth in the world for scientific output as measured by the number of scientific publications per million citizens.[5] In 2014, Israel's share of scientific articles published worldwide (0.9%) was much higher than its share of the global population (0.1%).[6][2] It also has one of the highest per capita rates of filed patents.[7]Israel counts 140 scientists and technicians per 10,000 employees, one of the highest ratios in the world. In comparison, there are 85 per 10,000 in the United States and 83 per 10,000 in Japan.[8] In 2012, Israel counted 8,337 full-time equivalent researchers per million inhabitants.[2] This compares with 3,984 in the USA, 6,533 in the Republic of South Korea and 5,195 in Japan. Israel's high technology industry has benefited from both the country's highly educated and technologically skilled workforce coupled with the strong presence of foreign high-tech firms and sophisticated research centres.[9][2]Israel is home to major players in the high-tech industry and has one of the world's most technologically literate populations.[10] In 1998, Tel Aviv was named by Newsweek as one of the ten most technologically influential cities in the world.[11] Since 2000, Israel has been a member of EUREKA, the pan-European research and development funding and coordination organization, and held the rotating chairmanship of the organization for 2010–2011.[12][13] In 2010, American journalist David Kaufman wrote that the high tech area of Yokneam, Israel, has the "world's largest concentration of aesthetics-technology companies".[14] Google Chairman Eric Schmidt has complimented the country during a visit there, saying that “Israel has the most important high-tech center in the world after the US.”[15]ContentsHistory EditJewish settlement in Mandate Palestine was ideologically motivated. Return to the homeland was perceived as contingent on a return to the soil. To establish the rural villages that formed the core of Zionist ideology and produce self-supporting Jewish farmers, agronomic experiments were conducted.[16] The foundations of agricultural research in Israel were laid by the teachers and graduates of the Mikveh Yisrael School, the country's first agricultural school, established by the Alliance Israelite Universelle in 1870.[17] On a field trip to Mount Hermon in 1906, the agronomist Aaron Aaronsohn discovered Triticum dicoccoides, or emmer wheat, believed to be the "mother of all wheat."[18] In 1909, he founded an agricultural research station in Atlit where he built up an extensive library and collected geological and botanical samples.[19] The Agricultural Station, founded in Rehovot in 1921, engaged in soil research and other aspects of farming in the country's difficult climatic conditions.[20] This station, which became the Agricultural Research Organization (ARO), is now Israel’s major institution of agricultural research and development.Albert Einstein at the Technion; c. 1925In 1912, the first cornerstone of the Technion - Israel Institute of Technology was laid at a festive ceremony in Haifa, which was then occupied by the Ottoman Empire. The Technion would become a unique university worldwide in its claim to precede and create a nation. As Jews were often barred from technical education in Europe,[21] the Technion claims to have brought the skills needed to build a modern state.[22]Established before World War I, the Hebrew Health Station in Jerusalem, founded by Nathan Straus engaged in medical and public health research, operating departments for public hygiene, eye diseases and bacteriology.[23] The station manufactured vaccines against typhus and cholera, and developed methods of pest control to eliminate field mice. The Pasteur Institute affiliated with the station developed a rabies vaccine.[23] Departments for microbiology, biochemistry, bacteriology, and hygiene were opened at the Hebrew University of Jerusalem, founded on Mount Scopus in 1925. In 1936, Jewish workers in the center of the country donated two-days' pay toward the establishment of the "Hospital of Judea and Sharon," later renamed Beilinson Hospital. In 1938, Beilinson established the country's first blood bank.[24] The Rothschild-Hadassah University Hospital on Mount Scopus opened in 1939 and was the first teaching hospital and medical center in the country. Since renamed the Hadassah Medical Center, it has become a leader in medical research.[25]WEIZAC, the first modern computer in the Middle EastIndustrial research began at the Technion - Israel Institute of Technology, was also initiated at the Daniel Sieff Research Center (later the Weizmann Institute of Science), established in 1934 in Rehovot. The Dead Sea Laboratories opened in the 1930s. The first modern electronic computer in Israel and the Middle East, and one of the first large-scale, stored-program, electronic computers in the world, called WEIZAC, was built at the Weizmann Institute during 1954–1955, based on the Institute for Advanced Study (IAS) architecture developed by John von Neumann.[26] WEIZAC has been recognized by the IEEE as a milestone in the history of electrical engineering and computing.[27] IBM Israel, registered on June 8, 1950, was the country's first high-tech firm. The company, located on Allenby Street in Tel Aviv, assembled and repaired punch card machines, sorting machines and tabulators. In 1956, a local plant was opened to produce punch cards, and a year later, the first service center opened, offering computerized data processing services.[28]Scientific and technological research in Israel was boosted by the appointment of a chief scientist for the Industry and Trade Ministry at the recommendation of a committee headed by Ephraim Katzir, later president of Israel.[29] The Israeli government provided grants that covered 50–80 percent of the outlay for new start-ups, with no conditions, no shareholding and no participation in management.[29] In the early 1980s, Control Data Corporation, a partner in Elron Electronic Industries, formed the country's first venture capital firm.[29]Origin of Israeli high-tech industry EditIsrael’s high-tech industries are a spin-off of the rapid[clarification needed] development of computer science and technology in the 1980s in such places as Silicon Valley and Massachusetts Route 128 in the USA, which ushered in the current high-tech era. Up until that point, Israel’s economy had been essentially based on agriculture, mining and secondary sectors such as diamond polishing and manufacturing in textiles, fertilizers and plastics.The key factor which enabled high-tech industries based on information and communication technologies to take root and flourish in Israel was the heavy[clarification needed] investment by the defence and aerospace industries, which spawned new technologies and know-how. Israel devoted 17.1% of its GDP to military expenditure in 1988. Even though this share had dropped to 5.8% of GDP by 2016, Israel military spending remains among the highest in the world. For the purposes of comparison, the United States devoted 5.7% of its GDP to military expenditure in 1988 and 3.3% in 2016.[30] This heavy investment in defence and aerospace formed the basis for Israel’s high-tech industries in medical devices, electronics, telecommunications, computer software and hardware.The massive[clarification needed] Russian immigration of the 1990s reinforced this phenomenon, doubling the number of engineers and scientists in Israel overnight. Between 1989 and 2006, about 979 000 Russian Jews and their relatives migrated to Israel, which had a population of just 4.5 million in 1989.[2]Today, Israel has the world’s most research-intensive business sector; in 2013, it alone performed 3.49% of GDP. Competitive grants and tax incentives are the two main policy instruments supporting business research and development. Thanks to government incentives and the availability of highly trained human capital, Israel has become an attractive location for the research centres of leading multinationals. The country’s national innovation ecosystem relies on both foreign multinationals and large corporate investors in research and development, as well as on start-ups. According to the Israel Venture Capital Database, 264 foreign research centres are currently active in Israel. Many of these centres are owned by large multinational firms that have acquired Israeli companies, technology and know-how and transformed them through mergers and acquisitions into their own local research facilities. The activity of some research centres even spans more than three decades, such as those of Intel, Applied Materials, Motorola and IBM.[2]In 2011, foreign research centres employed 33,700 workers through local subsidiaries, two-thirds of whom (23,700) worked in research and development. The same year, these research centres spent a total of NIS 14.17 billion on research and development across the full spectrum of industry, up from 17% over the previous year.[2]Higher education policy EditSixth Higher Education Plan EditIsrael’s higher education system is regulated by the Council for Higher Education and its Planning and Budgeting Committee. The Israeli higher education system operates under a multi-year plan agreed upon by the Planning and Budgeting Committee (PBC) and the Ministry of Finance. Each plan determines policy objectives and, accordingly, the budgets to be allocated in order to achieve these objectives.[2]The annual government allocation to universities totalled about US$1 750 million in 2015, providing 50–75% of their operating budgets. Much of the remainder of their operating budget (15–20%) comes from annual student tuition fees, which are uniform at about US$2 750 per year. The Sixth Higher Education Plan (2011–2016) makes provision for a 30% rise in the Council for Higher Education’s budget. The Sixth Plan changes the budgeting model of the PBC by placing greater emphasis on excellence in research, along with quantitative measures for the number of students. Under this model, 75% of the committee’s budget (NIS 7 billion over six years) is being allocated to institutions offering higher education. The Sixth Higher Education Plan launched the Israeli Centres of Research Excellence (I-CORE) programme in October 2011. This reflects a renewed interest in funding academic research and constitutes a strong indication of a reversal in government policy.[2]Israeli Centres of Research Excellence EditThe Israeli Centres of Research Excellence (I-CORE) programme, which dates from 2011, envisions the establishment of cross-institutional clusters of top researchers in specific fields and returning young Israeli scientists from abroad, with each centre being endowed with state-of-the-art research infrastructure. The Sixth Higher Education Plan invests NIS 300 million over six years in upgrading and renovating academic infrastructure and research facilities.[2]I-CORE is run jointly by the Council for Higher Education’s Planning and Budgeting Committee and the Israel Science Foundation. By 2015, 16 centres had been established in two waves across a wide spectrum of research areas: six specialize in life sciences and medicine, five in the exact sciences and engineering, three in social sciences and law and two in humanities. Each centre of excellence has been selected via a peer review process conducted by the Israel Science Foundation. By May 2014, around 60 young researchers had been absorbed into these centres, many of whom had previously worked abroad.[2]The research topics of each centre are selected through a broad bottom-up process consisting of consultations with the Israeli academic community, in order to ensure that they reflect the genuine priorities and scientific interests of Israeli researchers.[2]I-CORE is funded by the Council for Higher Education, the host institutions and strategic business partners, with a total budget of NIS 1.35 billion (US$365 million). The original goal was to set up 30 centres of research excellence in Israel by 2016. However, the establishment of the remaining 14 centres has provisionally been shelved, for lack of sufficient external capital.[2]In 2013–2014, the Planning and Budgeting Committee’s budget for the entire I-CORE programme amounted to NIS 87.9 million, equivalent to about 1% of the total for higher education that year. This budget appears to be insufficient to create the critical mass of researchers in various academic fields and thus falls short of the programme’s objective. The level of government support for the centres of excellence has grown each year since 2011 as new centres have been established and is expected to reach NIS 93.6 million by 2015–2016 before dropping to 33.7 million in 2017–2018. According to the funding model, government support should represent one-third ofall funding, another third being funded by the participating universities and the remaining third by donors or investors.[2]University recruitment targets EditIn the 2012–2013 academic year, there were 4,066 faculty members. The targets fixed by the Planning and Budgeting Committee for faculty recruitment are ambitious: universities are to recruit another 1 600 senior faculty within the six-year period – about half of whom will occupy new positions and half will replace faculty expected to retire. This will constitute a net increase of more than 15% in university faculty. In colleges, another 400 new positions are to be created, entailing a 25% net increase. The new faculty will be hired via the institutions’ regular recruitment channels, some in specific research areas, through the Israeli Centers of Research Excellence program.[2]The increase in faculty numbers will also reduce the student-to-faculty ratio, the target being to achieve a ratio of 21.5 university students to every faculty member, compared to 24.3 at present, and 35 students for every faculty member in colleges, compared to 38 at present. This increase in the number of faculty positions, alongside the upgrading of research and teaching infrastructure and the increase in competitive research funds, should help Israel to staunch brain drain by enabling the best Israeli researchers at home and abroad to conduct their academic work in Israel, if they so wish, at institutions offering the highest academic standards.[2]The new budgeting scheme described above is mainly concerned with the human and research infrastructure in universities. Most of the physical development (e.g. buildings) and scientific infrastructure (e.g. laboratories and expensive equipment) of universities comes from philanthropic donations, primarily from the American Jewish community (CHE, 2014). This latter source of funding has greatly compensated for the lack of sufficient government funding for universities up until now but it is expected to diminish significantly in the years to come. Unless the government invests more in research infrastructure, Israel’s universities will be ill-equipped and insufficiently funded to meet the challenges of the 21st century.[2]Expanding access to higher education EditIsrael has offered virtually universal access to its universities and academic colleges since the wave of Jewish immigration from the former Soviet Union in the 1990s prompted the establishment of numerous tertiary institutions to absorb the additional demand. However, the Arab and ultra-orthodox minorities still attend university in insufficient numbers. The Sixth Higher Education Plan places emphasis on encouraging minority groups to enroll in higher education. Two years after the Mahar program was implemented in late 2012 for the ultra-orthodox population, student enrollment had grown by 1400. Twelve new programs for ultra-orthodox students have since been established, three of them on university campuses. Meanwhile, the Pluralism and Equal Opportunity in Higher Education program addresses the barriers to integration of the Arab minority in the higher education system. Its scope ranges from providing secondary-school guidance through preparation for academic studies to offering students comprehensive support in their first year of study, a stage normally characterized by a high drop-out rate. The program renews the Ma’of fund supporting outstanding young Arab faculty members. Since the introduction of this program in 1995, the Ma’of fund has opened tenure track opportunities for nearly 100 Arab lecturers, who act as role models for younger Arab students embarking on their own academic careers.[2]Science, technology and innovation policy EditPolicy framework EditAlthough Israel does not have an ‘umbrella type’ policy for science, technology and innovation optimizing priorities and allocating resources, it does implement, de facto, an undeclared set of best practices combining bottom-up and top-down processes via government offices, such as those of the Chief Scientist or the Minister of Science, Technology and Space, as well as ad hoc organizations like the Telem forum. The procedure for selecting research projects for the Israeli centers for research excellence is one example of this bottom-up process.[2]Israel has no specific legislation regulating the transfer of knowledge from the academic sector to the general public and industry. Nevertheless, the Israeli government influences policy formulation by universities and technology transfer by providing incentives and subsidies through programmes such as Magnet and Magneton, as well as through regulation. There were attempts in 2004 and 2005 to introduce bills encouraging the transfer of knowledge and technology for the public benefit but, as these attempts failed, each university has since defined its own policy.[2]The Israeli economy is driven by industries based on electronics, computers and communication technologies, the result of over 50 years of investment in the country’s defence infrastructure. Israeli defence industries have traditionally focused on electronics, avionics and related systems. The development of these systems has given Israeli high-tech industries a qualitative edge in civilian spin-offs in the software, communications and Internet sectors. However, the next waves of high technologies are expected to emanate from other disciplines, including molecular biology, biotechnology and pharmaceuticals, nanotechnology, material sciences and chemistry, in intimate synergy with information and communication technologies. These disciplines are rooted in the basic research laboratories of universities rather than the defence industries. This poses a dilemma. In the absence of a national policy for universities, let alone for the higher education system as a whole, it is not clear how these institutions will manage to supply the knowledge, skills and human resources needed for these new science-based industries.[2]Evaluation of science policy instruments EditThe country’s various policy instruments are evaluated by the Council for Higher Education, the National Council for Research and Development, the Office of the Chief Scientist, the Academy of Sciences and Humanities and the Ministry of Finance. In recent years, the Magnet administration in the Office of the Chief Scientist has initiated several evaluations of its own policy instruments, most of which have been carried out by independent research institutions. One such evaluation was carried out in 2010 by the Samuel Neaman Institute; it concerned the Nofar programme within the Magnet directorate. Nofar tries to bridge basic and applied research, before the commercial potential of a project has caught the eye of industry. The main recommendation was for Nofar to extend programme funding to emerging technological domains beyond biotechnology and nanotechnology. The Office of the Chief Scientist accepted this recommendation and, consequently, decided to fund projects in the fields of medical devices, water and energy technology and multidisciplinary research.[2]An additional evaluation was carried out in 2008 by Applied Economics, an economic and management research-based consultancy, on the contribution of the high-tech sector to economic productivity in Israel. It found that the output per worker in companies that received support from the Office of the Chief Scientist was 19% higher than in ‘twin’ companies that had not received this support. The same year, a committee headed by Israel Makov examined the Office of the Chief Scientist’s support for research and development in large companies. The committee found economic justification for providing incentives for these companies.[2]Research funding programmes EditThe Israeli Science Foundation is the main source of research funding in Israel and receives administrative support from the Academy of Sciences and Humanities. The foundation provides competitive grants in three areas: exact sciences and technology; life sciences and medicine; and humanities and social sciences. Complementary funding is provided by binational foundations, such as the USA–Israel Binational Science Foundation (est. 1972) and the German–Israeli Foundation for Scientific Research and Development (est. 1986).[2]The Ministry of Science, Technology and Space funds thematic research centres and is responsible for international scientific co-operation. The Ministry’s National Infrastructure Programme aims to create a critical mass of knowledge in national priority fields and to nurture the younger generation of scientists. Investment in the programme mainly takes the form of research grants, scholarships and knowledge centres. Over 80% of the ministry’s budget is channelled towards research in academic institutions and research institutes, as well as towards revamping scientific infrastructure by upgrading existing research facilities and establishing new ones. In 2012, the ministry resolved to invest NIS 120 million over three years in four designated priority areas for research: brain science; supercomputing and cybersecurity; oceanography; and alternative transportation fuels. An expert panel headed by the Chief Scientist in the Ministry of Science, Technology and Space chose these four broad disciplines in the belief that they would be likely to exert the greatest practical impact on Israeli life in the near future.[2]The main ongoing programmes managed by the Office of the Chief Scientist within the Ministry of the Economy are: the Research and Development Fund; Magnet Tracks (est. 1994; Tnufa (est. 2001) and the Incubator Programme (est.1991). Between 2010 and 2014, the Office of the Chief Scientist initiated several new programmes:[2]Grand Challenges Israel (since 2014): an Israeli contribution to the Grand Challenges in Global Health programme, which is dedicated to tackling global health and food security challenges in developing countries; Grand Challenges Israel is offering grants of up to NIS 500 000 at the proof of concept/feasibility study stage.Research and development in the field of space technology (2012): encourages research to find technological solutions in various fields.Technological Entrepreneurship Incubators (2014): encourages entrepreneurial technology and supports start-up technology companies.Magnet – Kamin programme (2014) provides direct support for applied research in academia that has potential for commercial application.Cyber – Kidma programme (2014): promotes Israel’s cybersecurity industry.Cleantech – Renewable Energy Technology Centre (2012): supports research through projects involving private–public partnerships in the field of renewable energy.Life Sciences Fund (2010): finances the projects of Israeli companies, with emphasis on biopharmaceuticals, established together with the Ministry of Finance and the private sector.Biotechnology – Tzatam programme (2011): provides equipment to support research and development in life sciences. The Chief Scientist supports industrial organizations and the PBC provides research institutions with assistance.Investment in high-tech industries (2011): encourages financial institutions to invest in knowledge-based industries, through a collaboration between the Office of the Chief Scientist and the Ministry of Finance.Another source of public research funding is the Forum for National Research and Development Infrastructure (Telem). This voluntary partnership involves the Office of the Chief Scientist of the Ministry of the Economy and the Ministry of Science, Technology and Space, the Planning and Budgeting Committee and the Ministry of Finance. Telem projects focus on establishing infrastructure for research and development in areas that are of common interest to most Telem partners. These projects are financed by the Telem members’ own resources.[2]Trends in research funding EditIn 2014, Israel topped the world for research intensity, reflecting the importance of research and innovation for the economy. Since 2008, however, Israel’s research intensity has weakened somewhat (4.21% of GDP in 2013), even as this ratio has experienced impressive growth in the Republic of Korea (4.15% in 2014), Denmark (3.06% in 2013) and Germany (2.94% in 2013). The OECD average was 2.40% of GDP in 2014. Business expenditure on research and development (BERD) continues to account for ~84% of GERD, or 3.49% of GDP.[2]The share of higher education in gross domestic expenditure on research and development (GERD) has decreased since 2003 from 0.69% of GDP to 0.59% of GDP (2013). Despite this drop, Israel ranks 8th among OECD countries for this indicator. The lion’s share of GERD (45.6%) in Israel is financed by foreign companies, reflecting the large scale of activity by foreign multinational companies and research centres in the country.[2]The share of foreign funding in university-performed research is also quite significant (21.8%). By the end of 2014, Israel had received €875.6 million from the European Union’s (EU’s) Seventh Framework Programme for Research and Innovation (2007–2013), 70% of which had gone to universities. Its successor, Horizon 2020 (2014–2020), has been endowed with nearly €80 billion in funding, making it the EU’s most ambitious research and innovation programme ever. As of February 2015, Israel had received €119.8 million from the Horizon 2020 programme.[2]In 2013, more than half (51.5%) of government spending was allocated to university research and an additional 29.9% to the development of industrial technologies. Research expenditure on health and the environment has doubled in absolute terms in the past decade but still accounts for less than 1% of total government GERD. Israel is unique among OECD countries in its distribution of government support by objective. Israel ranks at the bottom in government support of research in health care, environmental quality and infrastructure development.[2]There has been insufficient government funding for universities in recent years. University research in Israel is largely grounded in basic research, even though it also engages in applied research and partnerships with industry. Basic research in Israel only accounted for 13% of research expenditure in 2013, compared to 16% in 2006. There has since been an increase in General University Funds and those destined for non-oriented research.[2]Trends in human resources EditIn 2012, there were 77 282 full-time equivalent researchers in Israel, 82% of whom had acquired an academic education, 10% of whom were practical engineers and technicians and 8% of whom held other qualifications. Eight out of ten (83.8%) were employed in the business sector, 1.1% in the government sector, 14.4% in the higher education sector and 0.7% in non-profit institutions.[2]In 2011, 28% of senior academic staff were women, up by 5% over the previous decade (from 25% in 2005). Although the representation of women has increased, it remains very low in engineering (14%), physical sciences (11%), mathematics and computer sciences (10%) relative to education (52%) and paramedical occupations (63%).[2]There is a visible ageing of scientists and engineers in some fields. For instance, about three-quarters of researchers in the physical sciences are over the age of 50 and the proportion is even higher for practical engineers and technicians. The shortage of professional staff will be a major handicap for the national innovation system in the coming years, as the growing demand for engineers and technical professionals begins to outpace supply. [2]During the 2012/2013 academic year, 34% of bachelor's degrees were obtained in fields related to science and engineering in Israel. This compares well with the proportion in the Republic of Korea (40%) and most Western countries (about 30% on average). The proportion of Israeli graduates in scientific disciplines and engineering was slightly lower at the master’s level (27%) but dominated at PhD level (56%).[2]Recent statistics support the assertion that Israel may be living on the ‘fruits of the past’, that is to say, on the heavy investment made in primary, secondary and tertiary education during the 1950s, 1960s and 1970s. Between 2007 and 2013, the number of graduates in physical sciences, biological sciences and agriculture dropped, even though the total number of university graduates progressed by 19% (to 39 654). Recent data reveal that Israeli educational achievements in the core curricular subjects of mathematics and science are low in comparison to other OECD countries, as revealed by the exam results of Israeli 15-year olds in the OECD’s Programme for International Student Assessment. Public spending on primary education has also fallen below the OECD average. The public education budget accounted for 6.9% of GDP in 2002 but only 5.6% in 2011. The share of this budget going to tertiary education has remained stable at 16–18% but, as a share of GDP, has passed under the bar of 1%. There is concern at the deteriorating quality of teachers at all levels of education and the lack of stringent demands on students to strive for excellence.[2]Research universities EditFurther information: List of Israeli universities and colleges, Education in Israel, and List of multinationals with research and development centres in IsraelIsrael has seven research universities: Bar-Ilan University, Ben-Gurion University of the Negev, the University of Haifa, Hebrew University of Jerusalem, the Technion – Israel Institute of Technology, Tel Aviv University and the Weizmann Institute of Science, Rehovot. Other scientific research institutions include the Volcani Institute of Agricultural Research in Beit Dagan, the Israel Institute for Biological Research and the Soreq Nuclear Research Center. The Ben-Gurion National Solar Energy Center at Sde Boker is an alternative energy research institute established in 1987 by the Ministry of National Infrastructures to study alternative and clean energy technologies.Israeli universities are ranked among the top 50 academic institutions in the world in the following scientific disciplines: in chemistry (Technion);[31] in computer science (Weizmann Institute of Science, Technion, Hebrew University, Tel Aviv University);[32] in mathematics and natural sciences (Hebrew University, Technion)[33] and in engineering (Technion).[34]In 2009, Mor Tzaban, an Israeli high school student from Netivot, won first prize in the First Step to Nobel Prize in Physics competition. In 2012, Yuval Katzenelson of Kiryat Gat won first prize with a paper entitled "Kinetic energy of inert gas in a regenerative system of activated carbon." The Israeli delegation won 14 more prizes in the competition: 9 Israelis students won second prize, one won third prize and one won fourth prize.[35]Scientific output EditThe number of Israeli publications stagnated between 2005 and 2014, according to Thomson Reuters' Web of Science (Science Citation Index Expanded). Consequently, the number of Israeli publications per million inhabitants also declined: between 2008 and 2013, it dropped from 1 488 to 1 431; this trend reflects a relative constancy in scholarly output in the face of relatively high population growth (1.1% in 2014) for a developed country and near-zero growth in the number of full-time equivalent researchers in universities. Between 2005 and 2014, Israeli scientific output was particularly high in life sciences. Israeli universities do particularly well in computer science but publications in this field tend to appear mostly in conference proceedings, which are not included in the Web of Science.[2]Israeli publications have a high citation rate and a high share of papers count among the 10 percent most-cited. The share of papers with foreign co-authors is almost twice the OECD average, which is typical of small countries with a developed scientific and technological ecosystem. A team of 50 Israeli scientists work full-time at CERN, the European Organization for Nuclear Research, which operates the Large Hadron Collider in Switzerland. Israel was granted observer status in 1991 before becoming a fully fledged member in 2014. An Israeli delegation headed by President Shimon Peres visited the particle accelerator in 2011.[36]Israeli scientists collaborate mostly with Western countries such as the European Union and the United States but there has been strong growth in recent years in collaboration with East Asian countries such as China, Japan, and South Korea as well as India and Singapore.[2]Technology transfer EditHistory EditResearch conducted at Israeli universities and institutes is shared with the private sector through technology transfer (TT) units.[37] Israel's first university TT unit, Yeda, was established by the Weizmann Institute of Science in the 1950s.[38] Research in such fields as arid and semi-arid zone agricultural engineering was transferred to kibbutzim and private farmers on a gratis basis and agricultural knowledge was shared with developing countries.[39]In 1964, Yissum, the technology transfer company of the Hebrew University of Jerusalem, was founded.[40]Since the 1990s, the traditional dual mission of universities of teaching and research has broadened to include a third mission: engagement with society and industry. This evolution has been a corollary of the rise of the electronics industry and information technology services, along with a surge in the number of research personnel following the wave of immigration from the former Soviet Union.[2]Israel has no specific legislation regulating the transfer of knowledge from the academic sector to the general public and industry. There were attempts in 2004 and 2005 to introduce bills encouraging the transfer of knowledge and technology for the public benefit but, as these attempts failed, each university has since defined its own policy.[2]University-industry collaboration EditAll Israeli research universities have technology transfer offices. Recent research conducted by the Samuel Neaman Institute has revealed that, between 2004 and 2013, the universities’ share of patent applications constituted 10–12% of the total inventive activity of Israeli applicants. This is one of the highest shares in the world and is largely due to the intensive activity of the universities’ technology transfer offices. The Weizmann Institute’s technology transfer office, Yeda, has been ranked the third-most profitable in the world. Through exemplary university–industry collaboration, the Weizmann Institute of Science and Teva Pharmaceutical Industries have discovered and developed the Copaxone drug for the treatment of multiple sclerosis. Copaxone is Teva’s biggest-selling drug, with US$1.68 billion in sales in the first half of 2011. Since the drug’s approval by the US Food and Drug Administration in 1996, it is estimated that the Weizmann Institute of Science has earned nearly US$2 billion in royalties from the commercialization of its intellectual property.[2]International technology transfer EditIn 2007, the United Nations General Assembly's Economic and Financial Committee adopted an Israeli-sponsored draft resolution on agricultural technology transfer to developing countries. The resolution called on developed countries to make their knowledge and know-how accessible to the developing world as part of the UN campaign to eradicate hunger and dire poverty by 2015. The initiative is an outgrowth of Israel's many years of contributing its know-how to developing nations, especially Africa, in the spheres of agriculture, fighting desertification, rural development, irrigation, medical development, computers and the empowerment of women.[41]Venture capital EditAs new technology companies require money and seed capital to grow and thrive, Israel's science and technology sector is backed by a strong venture capital industry. Between 2004 and 2013, the Israeli venture capital industry played a fundamental role in funding the development of Israel’s high-tech sector. In 2013, Israeli companies had raised more venture capital as a share of GDP than companies in any other country as it attracted US$2 346 million alone during that year. Today, Israel is considered one of the biggest venture capital centers in the world outside the United States of America. Several factors have contributed to this growth. These include tax exemptions on Israeli venture capital, funds established in conjunction with large international banks and financial companies and the involvement of major organizations desirous to capitalize on the strengths of Israeli high-tech companies. These organizations include some of the world’s largest multinational technology companies, including Apple, Cisco, Google, IBM, Intel, Microsoft, Oracle, Siemens and Samsung. In recent years, the share of venture capital invested in the growth stages of enterprises has flourished at the expense of early stage investments.[2]Intellectual property rights EditIntellectual property rights in Israel protect copyright and performers’ rights, trademarks, geographical indicators, patents, industrial designs, topographies of integrated circuits, plant breeds and undisclosed business secrets. Both contemporary Israeli legislation and case law are influenced by laws and practices in modern countries, particularly Anglo-American law, the emerging body of EU law and proposals by international organizations.[2]Israel has made a concerted effort to improve the economy’s ability to benefit from an enhanced system of intellectual property rights. This includes increasing the resources of the Israel Patent Office, upgrading enforcement activities and implementing programmes to bring ideas funded by government research to the market. Between 2002 and 2012, foreigners accounted for nearly 80% of the patent applications filed with the Israel Patent Office. A sizeable[clarification needed] share of foreign applicants seeking protection from the Israel Patent Office are pharmaceutical companies such as F. Hoffmann-La Roche, Janssen, Novartis, Merck, Bayer-Schering, Sanofi-Aventis and Pfizer, which happen to be the main business competitors of Israel’s own Teva Pharmaceutical Industries.[2]Israel ranks tenth in the world for the number of patent applications filed with the United States Patent and Trademark Office (USPTO) by country of residence of the first-named inventor. Israeli inventors file far more applications with USPTO (5 436 in 2011) than with the European Patent Office (EPO). Moreover, the number of Israeli filings with EPO dropped from 1400 to 1063 between 2006 and 2011. This preference for USPTO is largely because foreign research centres implanted in Israel are primarily owned by US firms such as IBM, Intel, Sandisk, Microsoft, Applied Materials, Qualcomm, Motorola, Google or Hewlett–Packard. The inventions of these companies are attributed to Israel as the inventor of the patent but not as the owner (applicant or assignee). The loss of intellectual property into the hands of multinationals occurs mainly through the recruitment of the best Israeli talent by the local research centres of multinational firms. Although the Israeli economy benefits from the activity of the multinationals’ subsidiaries through job creation and other means, the advantages are relatively small compared to the potential economic gains that might have been achieved, had this intellectual property been utilized to support and foster the expansion of mature Israeli companies of a considerable size.[2]Applied science and engineering EditEnergy EditSolar power EditFurther information: Solar power in IsraelThe world's largest solar parabolic dish at the Ben-Gurion National Solar Energy Center[42]As of 2014, Israel leads the 2014 Global Cleantech Innovation Index.[43] The country's lack of conventional energy sources has spurred extensive research and development of alternative energy sources and Israel has developed innovative technologies in the solar energy field.[44] Israel has become the world's largest per capita user of solar water heaters in the home. A new, high-efficiency receiver to collect concentrated sunlight has been developed, which will enhance the use of solar energy in industry as well.[45]In a 2009 report by the CleanTech Group, Israel ranked number 5 clean tech country in the world.[46] The Arrow Ecology company has developed the ArrowBio process a patented system which takes trash directly from collection trucks and separates organic and inorganic materials through gravitational settling, screening, and hydro-mechanical shredding. The system is capable of sorting huge volumes of solid waste, salvaging recyclables, and turning the rest into biogas and rich agricultural compost. The system is used in California, Australia, Greece, Mexico, the United Kingdom and in Israel. For example, an ArrowBio plant that has been operational at the Hiriya landfill site since December 2003 serves the Tel Aviv area, and processes up to 150 tons of garbage a day.[47]In 2010, Technion – the Israel Institute of Technology – established the Grand Technion Energy Program (GTEP). This multidisciplinary task-force brings together Technion's top researchers in energy science and technology from over nine different faculties. GTEP's 4-point strategy targets research and development of alternative fuels; renewable energy sources; energy storage and conversion; and energy conservation. GTEP is presently the only center in Israel offering graduate studies in energy science and technology to bring the energy skills and know-how to address the energy challenges of the future.Natural gas EditSince 1999, large reserves of natural gas have been discovered off Israel’s coast. This fossil fuel has become the primary fuel for electricity generation in Israel and is gradually replacing oil and coal. In 2010, 37% of electricity in Israel was generated from natural gas, leading to savings of US$1.4 billion for the economy. In 2015, this rate is expected to surpass 55%.[2]In addition, the usage of natural gas in industry – both as a source of energy and as a raw material – is rapidly expanding, alongside the requisite infrastructure. This is giving companies a competitive advantage by reducing their energy costs and lowering national emissions. Since early 2013, almost the entire natural gas consumption of Israel has been supplied by the Tamar field, an Israeli–American private partnership. The estimated reserves amount to about 1 000 BCM, securing Israel’s energy needs for many decades to come and making Israel a potentially major regional exporter of natural gas. In 2014, initial export agreements were signed with the Palestinian Authority, Jordan and Egypt; there are also plans to export natural gas to Turkey and the EU via Greece.[2]In 2011, the government asked the Academy of Sciences and Humanities to convene a panel of experts to consider the full range of implications of the most recent discoveries of natural gas. The panel recommended encouraging research into fossil fuels, training engineers and focusing research efforts on the impact of gas production on the Mediterranean Sea’s ecosystem. The Mediterranean Sea Research Centre of Israel was established in 2012 with an initial budget of NIS 70 million; new study programmes have since been launched at the centre to train engineers and other professionals for the oil and gas industry. Meanwhile, the Office of the Chief Scientist, among others, plans to use Israel’s fledgling natural gas industry as a stepping stone to building capacity in advanced technology and opening up opportunities for Israeli innovation targeting the global oil and gas markets.[2]Space science and technology EditFurther information: Israel Space AgencyOfek-7 satellite launch through Shavit vehicleDuring the 1970s and 1980s Israel began developing the infrastructure needed for research and development in space exploration and related sciences. In November 1982, the Minister of Science and Technology, Yuval Ne'eman, established the Israel Space Agency (ISA), to coordinate and supervise a national space program as well as to conduct space, planetary, and aviation research. Because of geographical constraints, as well as safety considerations, the Israeli space program focuses on very small satellites loaded with payloads of a high degree of sophistication, and cooperation with other national space agencies.[48] The Technion Asher Space Research Institute plays a central role in educating the aerospace engineers of the next generation.[49] In 2009 Israel was ranked 2nd among 20 top countries in space sciences by Thomson Reuters agency.[50]Israel launched its first satellite, Ofeq-1, from the locally built Shavit launch vehicle on September 19, 1988, and has made important[clarification needed] contributions in a number of areas in space research, including laser communication, research into embryo development and osteoporosis in space, pollution monitoring, and mapping geology, soil and vegetation in semi-arid environments.[51]Key projects include the TAUVEX telescope, the Tel Aviv University Ultra Violet Experiment, a UV telescope for astronomical observations which was developed in the 1990s to be accommodated on an Indian Space Research Organisation (ISRO) geo-synchronous satellite GSAT-4, for joint operation and use by Indian and Israeli scientists; the VENUS microsatellite, developed in collaboration with the French space agency, CNES, which will use an Israeli-developed space camera, electric space engine and algorithms; and MEIDEX (Mediterranean – Israel Dust Experiment), in collaboration with NASA.[52]Ilan Ramon was Israel's first astronaut. Ramon was the space shuttle payload specialist on board the fatal STS-107 mission of Space Shuttle Columbia, in which he and the six other crew members were killed in a re-entry accident over the southern United States. Ramon had been selected as a payload specialist in 1997 and trained at the Johnson Space Center, Houston, Texas, from 1998 until 2003.[53] Among other experiments, Ramon was responsible for the MEIDEX project in which he was required to take pictures of atmospheric aerosol (dust) in the Mediterranean area using a multispectral camera designed to provide scientific information about atmospheric aerosols and the influence of global changes on the climate, and data for the Total Ozone Mapping Spectrometer (TOMS) and Moderate-Resolution Imaging Spectroradiometer (MODIS) instruments. Researchers from Tel Aviv University (TAU) were responsible for the scientific aspect of the experiment. The TAU team also worked with a US company, Orbital Sciences Corporation, to construct and test special flight instruments for the project.[54]Aerospace engineering EditFurther information: Israel Aerospace IndustriesGulfstream G280 transcontinental business jet was designed and is currently produced for Gulfstream Aerospace by Israel Aircraft Industries (IAI)Aerospace engineering related to the country's defense needs has generated technological development with consequent civilian spin-offs. The Arava short take-off and landing (STOL) plane manufactured by Israel Aerospace Industries was the first aircraft to be produced in Israel, in the late 1960s, for both military and civilian uses.[55] This was followed by the production of the Westwind business jet[56] from 1965 to 1987, and later variants, the Astra[57] and the Gulfstream G100, which are still in active service.Israel is among the few countries capable of launching satellites into orbit and locally designed and manufactured satellites have been produced and launched by Israel Aerospace Industries(IAI), Israel's largest military engineering company, in cooperation with the Israel Space Agency. The AMOS-1 geostationary satellite began operations in 1996 as Israel's first commercial communications satellite. It was built primarily for direct-to-home television broadcasting, TV distribution and VSAT services. AMOS-2 was launched in December 2003 and a further series of AMOS communications satellites (AMOS 2 – 5i) are operated or in development by the Spacecom Satellite Communications company, headquartered in Ramat-Gan, Israel. Spacecom provides satellite telecommuncations services to countries in Europe, the Middle East and Africa.[58] Another satellite, the Gurwin-II TechSAT, designed and manufactured by the Technion, was launched in July 1998 to provide communications, remote sensing and research services. EROS, launched in 2000, is a non-geostationary orbit satellite for commercial photography and surveillance services.[59]Israel also develops, manufactures, and exports a large number of related aerospace products, including rockets and satellites, display systems, aeronautical computers, instrumentation systems, drones and flight simulators. Israel's second largest defense company is Elbit Systems, which makes electro-optical systems for air, sea and ground forces; drones; control and monitoring systems; communications systems and more.[60] The Technion - Israel Institute of Technology is home to the Asher Space Research Institute, which is unique in Israel as a university-based center of space research. At ASRI, Israeli students designed, built and launched their own satellite: Gurwin TechSat.[61]Agricultural engineering EditMain article: Agricultural research in IsraelAnaerobic digesters at Hiriya waste facilityIsrael’s agricultural sector is characterized by an intensive system of production stemming from the need to overcome the scarcity in natural resource, particularly water and arable land, in a country where more than half of its area is desert. The growth in agricultural production is based on close cooperation of scientists, farmers and agriculture-related industries and has resulted in the development of advanced agricultural technology, water-conserving irrigation methods, anaerobic digestion, greenhouse technology, desert agriculture and salinity research.[62] Israeli companies also supply irrigation, water conservation and greenhouse technologies and know-how to other countries.[63][64][65]The modern technology of drip irrigation was invented in Israel by Simcha Blass and his son Yeshayahu. Instead of releasing water through tiny holes, blocked easily by tiny particles, water was released through larger and longer passageways by using velocity to slow water inside a plastic emitter. The first experimental system of this type was established in 1959 when Blass partnered with Kibbutz Hatzerim to create an irrigation company called Netafim. Together they developed and patented the first practical surface drip irrigation emitter.[66] This method was very successful and had spread to Australia, North America and South America by the late 1960s.Israeli farmers rely heavily on greenhouse technology to ensure a constant, year-round supply of high quality produce, while overcoming the obstacles posed by adverse climatic conditions, and water and land shortages. Technologies include computerized greenhouse climate control, greenhouse shading, irrigation, fertigation, greenhouse water recycling and biological control of plant disease and insects, allow farmers to control most production parameters. As a result, Israeli farmers successfully grow 3 million roses per hectare in season and an average of 300 tons of tomatoes per hectare, four times the amount harvested in open fields.[67]Computer engineering EditTechnion - Israel Institute of Technology (faculty of Computer Science) buildingIsraeli companies excel in computer software and hardware development, particularly computer security technologies, semiconductors and communications. Israeli firms include Check Point, a leading firewall firm; Amdocs, which makes business and operations support systems for telecoms; Comverse, a voice-mail company; and Mercury Interactive, which measures software performance.[68] A high concentration of high-tech industries in the coastal plain of Israel has led to the nickname Silicon Wadi (lit: "Silicon Valley").[69] Both Israeli and international companies are based there. Intel[70] and Microsoft[71] built their first overseas research and development centers in Israel, and other high-tech multi-national corporations, such as IBM, Cisco Systems, and Motorola, have opened facilities in the country. Intel developed its dual-core Core Duo processor at its Israel Development Center in Haifa.[72] More than 3,850 start-ups have been established in Israel, making it second only to the US in this sector[73] and has the largest number of NASDAQ-listed companies outside North America.[74]Optics, electro-optics, and lasers are significant fields and Israel produces fiber-optics, electro-optic inspection systems for printed circuit boards, thermal imaging night-vision systems, and electro-optics-based robotic manufacturing systems.[75] Research into robotics first began in the late 1970s, has resulted in the production of robots designed to perform a wide variety of computer aided manufacturing tasks, including diamond polishing, welding, packing, and building. Research is also conducted in the application of artificial intelligence to robots.[75]Israel's Weizmann Institute of Science and Technion – Israel Institute of Technology are ranked among the top 20 academic institutions in the world in computer science.[32] An Israeli, CEO and president of M-Systems, Dov Moran, invented the first flash drive in 1998.[76]Cybersecurity EditIn November 2010, the Israeli prime minister entrusted a task force with responsibility for formulating national plans to place Israel among the top five countries in the world for cybersecurity. On 7 August 2011, the government approved the establishment of the National Cyber Bureau to promote the Israeli cyberdefence industry. The bureau is based in the Prime Minister’s Office. The National Cyber Bureau allocated NIS 180 million (circa US$50 million) over 2012–2014 to encourage cyber research and dual military–civilian R&D; the funding is also being used to develop human capital, including through the creation of cybersecurity centres at Israeli universities that are funded jointly by the National Cyber Bureau and the universities themselves.[2]In January 2014, the prime minister launched CyberSpark, Israel’s cyber innovation park, as part of plans to turn Israel into a global cyber hub. Located in the city of Beer-Sheva to foster economic development in southern Israel, CyberSpark is a geographical cluster of leading cyber companies, multinational corporations and universities, involving Ben Gurion University of the Negev, technology defence units, specialized educational platforms and the national Cyber Event Readiness Team.[2]About half of the firms in CyberSpark are Israeli, mostly small to medium-sized. Multinational companies operating in CyberSpark include EMC2, IBM, Lockheed Martin and Deutsche Telekom. PayPal recently acquired the Israeli start-up CyActive and has since announced plans to set up its second Israeli research centre in CyberSpark, with a focus on cybersecurity. This acquisition is just one of the many Israeli cybersecurity start-ups acquired by multinational companies in the past few years. Major acquisitions of Israeli start-ups in 2014 include Intellinx, purchased by Bottomline Technologies, and Cyvera, purchased by Palo Alto Networks.[2]The National Cyber Bureau has estimated that the number of Israeli cyberdefence companies had doubled in the past five years to about 300 by 2014. Israeli companies account for an estimated 10% of global sales, which currently total an estimated US$60 billion. Total research spending on cyberdefence in Israel quadrupled between 2010 and 2014 from US$50 million to US$200 million, bringing Israel’s spending to about 15% of global research spending on cyberdefence in 2014. Cybersecurity technologies are exported by Israel in accordance with the Wassenaar Arrangement, a multilateral agreement on Export Controls for Conventional Arms and Dual-Use Goods and Technologies.[2]Hydraulic engineering EditSee also: Water supply and sanitation in IsraelSince rain falls only in the winter, and largely in the northern part of the country, irrigation and water engineering is vital to the country's economic survival and growth. Large-scale projects to direct water from rivers and reservoirs in the north, to make optimal use of groundwater, and to reclaim flood overflow and sewage have been undertaken. The largest such project was a national water distribution system called the National Carrier, completed in 1964, flowing from the country's biggest freshwater lake, the Sea of Galilee, to the northern Negev desert, through huge channels, pipes and tunnels.[77] The Ashkelon seawater reverse osmosis (SWRO) desalination plant was the largest in the world at the time it was built.[78] The project was developed as a BOT (build-operate-transfer) by a consortium of three international companies: Veolia water, IDE Technologies and Elran.[79]Water-saving technologies EditAccording to water experts, pipe leakage is one of the major problems confronting the global water supply today. For Israel, which is two-thirds desert, water-saving technologies are of critical importance. The International Water Association has cited Israel as one of the leaders in innovative methods to reduce "non-revenue water," i.e., water lost in the system before reaching the customer.[80]Military engineering EditFurther information: Rafael Advanced Defense SystemsIAI Harop, Israel, is the world's largest exporter of drones.Rejection of requests for weapons and technologies, arms sanctions and massive rearmament of the Arab countries prodded Israel into the development of a broad-based indigenous arms industry.[81] The Israel Defense Forces relies heavily on local military technology and high-tech weapons systems designed and manufactured in Israel. Israeli-developed military equipment includes small arms, anti-tank rockets and missiles, boats and submarines, tanks, armored vehicles, artillery, unmanned surface vehicles, aircraft, unmanned aerial vehicles (UAVs), air-defense systems, weapon stations and radar. An impetus for the development of the industry was the embargo on arms sales to Israel during the Six-Day War which prompted Israel Aircraft Industries (IAI), founded as a maintenance facility in 1953, to begin developing and assembling its own aircraft, including the Kfir, the Arava and the Nesher.[82]Israeli soldier with Spike (missile)Notable technology includes the Uzi submachine gun, introduced in 1954,[83] the country's main battle tank, the Merkava, and the jointly designed Israeli and U.S. Arrow missile, one of the world's only operational, advanced anti-ballistic missile systems.[84] The Iron Dome mobile air defense system developed by Rafael Advanced Defense Systems is designed to intercept short-range rockets and artillery shells. The system was created as a defensive countermeasure to the rocket threat against Israel's civilian population on its northern and southern borders, and was declared operational and initially deployed in the first quarter of 2011.[85] It is designed to intercept very short-range threats up to 70 kilometers in all-weather situations.[86] On April 7, 2011, the system successfully intercepted a Grad rocket launched from Gaza, marking the first time in history a short-range rocket was ever intercepted.[87]Israel has also developed a network of reconnaissance satellites.[88] The Ofeq (lit. Horizon) series (Ofeq 1 – Ofeq 7) were launched between 1988 and 2007.[89] The satellites were carried by Shavit rockets launched from Palmachim Airbase. Both the satellites and the launchers were designed and manufactured by Israel Aerospace Industries (IAI), with Elbit Systems' El-Op division supplying the optical payload.Israel also has the first all-around operational active defense system for tanks named Trophy, successfully intercepting anti tank missiles fired at Merkava tanks.[citation needed]Life sciences EditGiven endoscopic capsuleIsrael has an advanced[clarification needed] infrastructure of medical and paramedical research and bioengineering capabilities. Biotechnology, biomedical, and clinical research account for over half of the country's scientific publications, and the industrial sector has used this extensive knowledge to develop pharmaceuticals, medical equipment and treatment therapies.[90]Biotechnology EditIsrael has over 900 biotechnology and life sciences companies in operation throughout the country with nearly 50 to 60 formed each year. Many multinational corporations such as J&J, Perrigo, GE Healthcare and Phillips Medical have all established branches in Israel.[9]Genetics and cancer research EditIsraeli scientists have developed methods for producing a human growth hormone and interferon, a group of proteins effective against viral infections. Copaxone, a medicine effective in the treatment of multiple sclerosis, was developed in Israel from basic research to industrial production. Genetic engineering has resulted in a wide range of diagnostic kits based on monoclonal antibodies, with other microbiological products.[90]Advanced stem cell research takes place in Israel. The first steps in the development of stem cell studies occurred in Israel, with research in this field dating back to studies of bone marrow stem cells in the early 1960s. By 2006, Israeli scientists were leaders on a per capita basis in the number of articles published in scientific journals related to stem cell research.[91] In 2011, Israeli scientist Inbar Friedrich Ben-Nun led a team which produced the first stem cells from endangered species, a breakthrough that could save animals in danger of extinction.[92] In 2012, Israel was one of the world leaders in stem cell research, with the largest number of articles, patents and research studies per capita.[93]Solomon Wasser, a professor from Haifa University, has found that Cyathus striatus is effective in treating pancreatic cancer based on early animal trials.[94]Biomedical engineering EditSophisticated medical equipment for both diagnostic and treatment purposes has been developed and marketed worldwide, such as computer tomography (CT) scanners, magnetic resonance imaging (MRI) systems, ultrasound scanners, nuclear medical cameras, and surgical lasers. Other innovations include a controlled-release liquid polymer to prevent accumulation of tooth plaque, a device to reduce both benign and malignant swellings of the prostate gland, the use of botulin to correct eye squint, and a miniature camera encased in a swallowable capsule used to diagnose gastrointestinal disease,[90] developed by Given Imaging.[95]In 2009, scientists from several European countries and Israel developed a robotic prosthetic hand, called SmartHand, which functions like a real one, allowing patients to write with it, type on a keyboard, play piano and perform other fine movements. The prosthesis has sensors which enable the patient to sense real feeling in its fingertips.[96] A new MRI system for identifying and diagnosing tumors developed at the Weizmann Institute has received approval from the U.S. Food and Drug Administration and is already being used in diagnosing breast and testicular cancer. The new system will replace invasive procedures and eliminate waiting time for the results.[97]Pharmaceutical sciences EditTeva Pharmaceutical Industries, headquartered in Petah Tikva, Israel, is the largest generic drug manufacturer in the world and one of the 20 largest pharmaceutical companies worldwide.[98] It specializes in generic drugs and active pharmaceutical ingredients and has developed proprietary pharmaceuticals such as Copaxone and Laquinimod for the treatment of multiple sclerosis, and Rasagiline for the treatment of Parkinson's disease.[99]Weizmann Institute of Science particle acceleratorNobel Prize laureates EditFor a more comprehensive list, see List of Israeli Nobel laureates.Six Israelis have won the Nobel Prize for Chemistry. In 2004, biologists Avram Hershko and Aaron Ciechanover of the Technion – Israel Institute of Technology were two of the three winners of the prize, for the discovery of ubiquitin-mediated protein degradation.[100] In 2009, Ada Yonath was a co-winner of the prize for her studies of the structure and function of the ribosome. She is the first Israeli woman to win a Nobel Prize.[101] Michael Levitt and Arieh Warshel received the Nobel Prize in Chemistry in 2013 for the development of multiscale models for complex chemical systems.[102]Additionally, 1958 Medicine laureate Joshua Lederberg was born to Israeli Jewish parents, and 2004 Physics laureate David Gross grew up partly in Israel, where he obtained his undergraduate degree. In the social sciences, the Nobel Prize for Economics was awarded to Daniel Kahneman in 2002, and to Robert Aumann of the Hebrew University in 2005.Science and technology in Israel - Wikipedia

Tell you what, if you can't be bothered to type "history of brisbane" into your broswer and click THE FIRST LINK in the results, I can't be bothered to do more than cut and paste it into my answer.From History of Brisbane... Enjoy.---------------------------------------------History of BrisbaneFrom Wikipedia, the free encyclopediahttps://en.wikipedia.org/wiki/History_of_BrisbanePart of a series on theHistory of AustraliaChronologicalPrehistoryExploration by seaLand exploration1788–18501851–19001901–19451945–presentTimelineBy topicConstitutionDiplomacyEconomyFederationImmigrationIndigenous peopleMilitaryMonarchyRail transportBrisbane's recorded history dates from 1799, when Matthew Flinders explored Moreton Bay on an expedition from Port Jackson, although the region had long been occupied by the Jagera and Turrbal aboriginal tribes. The town was conceived initially as a penal colony for British convicts sent from Sydney. Its suitability for fishing, farming, timbering, and other occupations, however, caused it to be opened to free settlement in 1838. The town became amunicipality in 1859 and a consolidatedmetropolitan area in 1924. The city hosted the1982 Commonwealth Games and the 2014 G20 Brisbane summit.Contents [hide]1Etymology2Aboriginal occupation and European exploration31824 colony4Free settlement5Development in the early years of the colony of Queensland5.1Amalgamation of local government areas6Brisbane during the Second World War7Post-War Brisbane7.1Brisbane floods7.21980s8Brisbane's historical timeline9See also10References11Further reading12External linksEtymology[edit]Brisbane, Queensland, Australia, is named for Sir Thomas Brisbane (1773–1860), British soldier and colonial administrator born in Ayrshire, Scotland. Sir Thomas Brisbane was Governor of New South Wales at the time that Brisbane was named.Aboriginal occupation and European exploration[edit]Prior to European colonisation, the Brisbane region was occupied by aboriginal tribes, notably the Yuggera and Turrbal aboriginal clans. Before European settlement, the land, the river and its tributaries were the source and support of life in all its dimensions. The river's abundant supply of food included fish, shellfish, crab, and shrimp. Good fishing places became campsites and the focus of group activities. The district was characterized by open woodlands with rainforest in some pockets or bends of the Brisbane River.A resource-rich area and a natural avenue for seasonal movement, Brisbane was a way station for groups travelling to ceremonies and spectacles. The region had several large (200–600 person) seasonal camps, the biggest and most important located along waterways north and south of the current city heart: Barambin or 'York's Hollow' camp (today's Victoria Park) and Woolloon-cappem (Woolloongabba/South Brisbane), also known as Kurilpa. These camping grounds continued to function well into historic times.The region was first explored by Europeans in 1799, when Matthew Flindersexplored Moreton Bay during his expedition from Port Jackson north to Hervey Bay. He made a landing at what is now Woody Point in Redcliffe, and also touched down at Coochiemudlo Island and Pumicestone Passage. During the fifteen days he spent in Moreton Bay, Flinders was unable to find the Brisbane River.[1]A permanent settlement in the region was not founded until 1823, when New South Wales Governor Thomas Brisbane was petitioned by free settlers in Sydney to send their worst convicts elsewhere and the area chosen became the city of Brisbane.On 23 October 1823, Surveyor General John Oxley set out with a party in the cutterMermaid from Sydney to "survey Port Curtis (now Gladstone), Moreton Bay, and Port Bowen (north of Rockhampton, 22.5°S 150.75°E),[2] with a view to forming convict settlements there". The party reached Port Curtis on 5 November 1823. Oxley suggested that the location was unsuitable for a settlement, since it would be difficult to maintain.As he approached Point Skirmish by Moreton Bay, he noticed several indigenous Australians approaching him and in particular one as being "much lighter in colour than the rest". The white man turned out to be a shipwrecked lumberjack by the name of Thomas Pamphlett who, along with John Finnegan, Richard Parsons, andJohn Thompson had left Sydney on 21 March 1823 to sail south along the coast and bring cedar from Illawarra but during a large storm were pushed north. Not knowing where they were, the group attempted to return to Sydney, eventually being shipwrecked on Moreton Island on 16 April.[3] They lived with the indigenous tribe seven months.After meeting with them, Oxley proceeded approximately 100 kilometres (62 mi) up what he later named the Brisbane River in honour of the governor. Oxley explored the river as far as what is now the suburb of Goodna in the city of Ipswich, about 20 kilometres (12 mi) upstream Brisbane's central business district. Several places were named by Oxley and his party, including Breakfast Creek (at the mouth of which they cooked breakfast), Oxley Creek, and Seventeen Mile Rocks.1824 colony[edit]See also: Early Streets of BrisbaneIn 1824, the first convict colony was established at Redcliffe Point under LieutenantHenry Miller. Meanwhile, Oxley and Allan Cunningham explored further up the Brisbane River in search of water, landing at the present location of North Quay. Only one year later, in 1825, the colony was moved south from Redcliffe to a peninsula on the Brisbane River, site of the present central business district, called "Meen-jin" by its Turrbul inhabitants.https://en.wikipedia.org/wiki/File:StateLibQld_2_148511_Early_drawing_of_a_section_of_the_town_of_Brisbane,_Queensland_including_the_Convict_Hospital,_1835.jpgAn early drawing of the townAt the end of 1825, the official population of Brisbane was "45 males and 2 females". Until 1859, when Queensland was separated from the state ofNew South Wales, the name Moreton Bay was used to describe the new settlement and surrounding areas. "Edenglassie" was the name first bestowed on the growing town by Chief JusticeFrancis Forbes,[4] a portmanteau of the two Scottish cities Edinburgh and Glasgow. The name soon fell out of favour with many residents and the current name in honour of Governor Thomas Brisbane was adopted instead.The colony was originally established as a "prison within a prison"—a settlement, deliberately distant from Sydney, to which recidivist convicts could be sent as punishment. It soon garnered a reputation, along with Norfolk Island, as one of the harshest penal settlements in all of New South Wales. In July 1828 work began on the construction of the Commissariat Store. It remains intact today as a museum of the Royal Historical Society of Queensland and is only one of two convict era buildings still standing in Queensland. The other is The Old Windmill on Wickham Terrace.Over twenty years, thousands of convicts passed through the penal colony. Hundreds of these fled the stern conditions and escaped into the bush. Although most escapes were unsuccessful or resulted in the escapees perishing in the bush, some (e.g. James Davis) succeeded in living as "wild white men" amongst the aboriginal people.During these decades, the local aboriginals tried to "starve out" the settlement bydestroying its crops—most notably their "corn fields" at today's South Bank. In retaliation, colony guards shot and killed aboriginals entering the corn fields.Free settlement[edit]As a penal colony, Brisbane did not permit the erection of private settlements nearby for many years. As the inflow of new convicts steadily declined, the population dropped. From the early 1830s the British government questioned the suitability of Brisbane as a penal colony. Allan Cunningham's discovery of a route to the fertileDarling Downs in 1828, the commercial pressure to develop a pastoral industry, and increasing reliance on Australian wool, as well as the expense of transporting goods from Sydney, were the major factors contributing to the opening of the region to free settlement.[5] In 1838, the area was opened up for free settlers, as distinct from convicts. An early group of Lutheran missionaries from Germany were granted land in what is now the north side suburb of Nundah.https://en.wikipedia.org/wiki/File:StateLibQld_1_186935_Buildings_on_the_banks_of_the_Brisbane_River_downstream_from_Gardens_Point,_ca._1840.jpgEarly development along the Brisbane River, ~1840In 1839 the first three surveyors, Dixon, Stapylton and Warner arrived in Moreton Bay to prepare the land for greater numbers of European settlers by compiling a trigonometrical survey.[6] From the 1840s, settlers took advantage of the abundance of timber in local forests. Once cleared, land was quickly utilized for grazing and other farming activities. The convict colony eventually closed.The free settlers did not recognise local aboriginal ownership and were not required to provide compensation to the Turrbul aboriginals. Some serious affrays and conflicts ensued—most notably resistance activities of Yilbung, Dundalli, Ommuli, and others. Yilbung, in particular, sought to extract regular rents from the white population on which to sustain his people, whose resources had been heavily depleted by the settlers. By 1869, many of the Turrbul had died from gunshot or disease, but the Moreton Bay Courier makes frequent mention of local indigenous people who were working and living in the district. In fact, between the 1840s and 1860s, the settlement relied increasingly on goods obtained by trade with aboriginals—firewood, fish, crab, shellfish—and services they provided such as water-carrying, tree-cutting, fencing, ring-barking, stock work and ferrying. Some Turrbul escaped the region with the help of Thomas Petrie, who gave his name to the suburb of Petrie in the Moreton Bay region north of Brisbane.Development in the early years of the colony of Queensland[edit]https://en.wikipedia.org/wiki/File:JohnPetrie01.jpgBrisbane's first mayor wasJohn Petriehttps://en.wikipedia.org/wiki/File:StateLibQld_1_63671_Town_of_Brisbane,_ca._1870.jpgBrisbane town, 1870On 6 September 1859, the Municipality of Brisbane was proclaimed. The next month, polling for the first council was conducted. John Petrie was elected the first mayor of Brisbane.[7] Queensland was formally established as a self-governing colony of Great Britain, separate from New South Wales, in 1859.Originally the neighbouring city of Ipswich was intended to be the capital of Queensland, but it proved to be too far inland to allow access by large ships, so Brisbane was chosen instead. But it was not until 1902 that Brisbane was officially designated a city.https://en.wikipedia.org/wiki/File:Brisbane_1893.jpgFlooding on Queen Street, 1893.The 1893 Black February floods caused severe flooding in the region and devastated the city. Raging flood waters destroyed the first of several versions of the Victoria Bridge. Even though gold was discovered north of Brisbane, around Maryborough and Gympie, most of the proceeds went south to Sydney and Melbourne. The city remained an underdeveloped regional outpost, with comparatively little of the classical Victorian architecture that characterized southern cities.A demonstration of electric lighting of lamp posts along Queen Street in 1882 was the first recorded use of electricity for public purposes in the world.[8] The first railway in Brisbane was built in 1879, when the line from the western interior was extended from Ipswich to Roma Street Station. First horse-drawn, then electric trams operated in Brisbane from 1885 until 1969.In 1887, the Yungaba Immigration Centre was established at Kangaroo Point. The two-storey brick building is listed on the Queensland Heritage Register.[9] Tramway employees stood down for wearing union badges on 18 January 1912 sparked Australia's first General strike, the 1912 Brisbane General Strike which lasted for five weeks. The first ceremony to honour the fallen soldiers at Gallipoli was held at St John's Cathedral on 10 June 1915.[10] The tradition would later grow into the popularAnzac Day ceremony.In an effort to prevent overcrowding and control urban development, the Parliament of Queensland passed the Undue Subdivision of Land Prevention Act 1885, preventing congestion in Queensland cities relative to others in Australia. This legislation, in addition to the construction of efficient public transport in the form of steam trains and electric trams, encouraged urban sprawl. Although the initial tram routes reached out into established suburbs such as West End, Fortitude Valley,New Farm, and Newstead, later extensions and new routes encouraged housing developments in new suburbs, such as the western side of Toowong, Paddington,Ashgrove, Kelvin Grove and Coorparoo.https://en.wikipedia.org/wiki/File:StateLibQld_1_48448_Woman_getting_on_a_tram,_Brisbane,_1910-1920.jpgA Brisbane tram in the early 20th centuryhttps://en.wikipedia.org/wiki/File:StateLibQld_1_101716_Victoria_Bridge_ca._1933.jpgThe Victoria Bridge over theBrisbane River, 1933This pattern of development continued through to the 1950s, with later extensions encouraging new developments aroundStafford, Camp Hill, Chermside, Enoggeraand Mount Gravatt. Generally, these new train lines linked established communities, although the Mitchelton line (later extended to Dayboro) and before being cut back toFerny Grove) did encourage suburban development out as far as Keperra.Subsequently, as private motor cars became affordable, land between tram and train routes was developed for settlement, resulting in the construction of Ekibin,Tarragindi, Everton Park, Stafford Heights, and Wavell Heights.Amalgamation of local government areas[edit]In 1924, the City of Brisbane Act was passed by the Queensland Parliament, consolidating the City of Brisbane and the City of South Brisbane; the Towns of Hamilton, Ithaca, Sandgate, Toowong, Windsor, and Wynnum; and the Shires of Balmoral, Belmont, Coorparoo, Enoggera, Kedron, Moggill, Sherwood, Stephens, Taringa, Tingalpa, Toombul, and Yeerongpilly to form the current City of Greater Brisbane, now known simply as the City of Brisbane, in 1925.To accommodate the new, enlarged city council, the current Brisbane City Hall was opened in 1930. Many former shire and town halls were then remodelled into public libraries, becoming the nucleus of Greater Brisbane's branch system. During the Great Depression, a number of major projects were undertaken to provide work for the unemployed, including the construction of the William Jolly Bridge and theWynnum Wading Pool.Brisbane during the Second World War[edit]Due to Brisbane's proximity to the South West Pacific Area theatre of World War II, the city played a prominent role in the defence of Australia. The city became a temporary home to thousands of Australian and American servicemen. Buildings and institutions around Brisbane were given over to the housing of military personnel as required.The present-day MacArthur Central building became the Pacific headquarters of U.S. General Douglas MacArthur,[11] and the University of Queensland campus at St Lucia was converted to a military barracks for the final three years of the war. St Laurence's College and Somerville House Girls' School in South Brisbane were also used by American forces.During this time St Laurence's College was moved to Greenslopes to continue classes. Newstead House was also used to house American servicemen during the war.Brisbane was used to mark the position of the "Brisbane Line", a controversial defence proposal allegedly formulated by the Menzies government, that would, upon a land invasion of Australia, surrender the entire northern part of the country. The line was, allegedly, at a latitude just north of Brisbane and spanned the entire width of the continent. Surviving from this period are several cement bunkers and gun forts in the northern suburbs of Brisbane and adjacent areas (Sunshine Coast/ Moreton Bay islands).On 26 November and 27 November 1942, rioting broke out between US and Australian servicemen stationed in Brisbane. By the time the violence had been quelled one Australian soldier was dead, and hundreds of Australian and US servicemen were injured along with civilians caught up in the fighting.[12] Hundreds of soldiers were involved in the rioting on both sides. This incident, which was heavily censored at the time and apparently was not reported in the US at all, is known as the Battle of Brisbane.Post-War Brisbane[edit]https://en.wikipedia.org/wiki/File:BrisbaneSuburbanOuthouses1950.jpgThe consequence of years of inadequate civic finances—a city largely unsewered, with outhousesbehind each home. The city was not completely sewered until the early 1970s.Immediately after the war, the Brisbane City Council, along with most governments in Australia, found it difficult to raise finances for much-needed repairs and development. Even where funds could be obtained materials were scarce. Adding to these difficulties was the political environment encouraged by some aldermen, led by Archibald Tait, to reduce the city's rates (land taxes). Ald Tait successfully ran on a slogan of "Vote for Tait, he'll lower the rate." Rates were indeed lowered, exacerbating Brisbane's financial difficulties.Although Brisbane's tram system continued to be expanded, roads and streets remained unsealed. Water supply was limited, although the City Council built and subsequently raised the level of the Somerset Dam on the Stanley River. Despite this, most residences continued to rely heavily on rainwater stored in tanks.The limited water supply and lack of funding also meant that despite the rapid increase in the city's population, little work was done to upgrade the city's sewage collection, which continued to rely on the collection of nightsoil. Other than the CBD and the innermost suburbs, Brisbane was a city of "thunderboxes" (outhouses) or ofseptic tanks.What finances could be garnered by the Council were poured into the construction ofTennyson Powerhouse, and the extension and upgrading of the powerhouse in New Farm Park to meet the growing demands for electricity. Brisbane's first modern apartment building, Torbreck at Highgate Hill, was completed in 1960.[13]Work continued slowly on the development of a town plan, hampered by the lack of experienced staff and a continual need to play "catch-up" with rapid development. The first town plan was adopted in 1964.1961 saw the election of Clem Jones as Lord Mayor. Ald Jones, together with the town clerk J.C. Slaughter sought to fix the long term problems besetting the city. Together they found cost-cutting ways to fix some problems. For example, new sewers were laid 4 feet deep and in footpaths, rather than 6 feet deep and under roads. In the short term, "pocket" or local sewerage treatment plants were established around the city in various suburbs to avoid the expense of developing a major treatment plants and major connecting sewers.They were also fortunate in that finance was becoming less difficult to raise and the city's rating base had by the 1960s significantly grown, to the point where revenue streams were sufficient to absorb the considerable capital outlays.Under Jones' leadership, the City Council's transport policy shifted significantly. The City Council hired American transport consultants Wilbur Smith to devise a new transport plan for the city.[14] They produced a report known as the Wilbur Smith "Brisbane Transportation Study" which was published in 1965. It recommended the closure of most suburban railway lines, closure of the tram and trolley-bus networks, and the construction of a massive network of freeways through the city. Under this plan the suburb of Woolloongabba would have been almost completely obliterated by a vast interchange of three major freeways.Although the trams and trolley-buses were rapidly eliminated between 1968 and 1969, only one freeway was constructed, the trains were retained and subsequently electrified. The first train line to be so upgraded was the Ferny Grove to Oxley line in 1979. The train line to Cleveland, which had been cut back to Lota in 1960, was also reopened.Brisbane floods[edit]https://en.wikipedia.org/wiki/File:Brisbane_River_in_flood_(1).jpgSwollen Brisbane River, 2011Brisbane has been inundated by severefloods of the Brisbane River in 1864, 1893, 1897, 1974, 2011 and 2013. A comprehensive flood mitigation scheme was instituted for the Brisbane River catchment area in the aftermath of the 1974 flood. Since then the city remained largely flood free, until the floods in January 2011 and 2013 floods.1980s[edit]https://en.wikipedia.org/wiki/File:Opening_ceremony_(8075978683).jpgThe 1982 Commonwealth Gameswas officially opened by The Duke of Edinburgh and closed by The Queen.Brisbane hosted the Commonwealth Gamesin 1982 and the World's Fair in 1988. Between the late 1970s and mid-1980s, Brisbane was the focus of early land rights protests (e.g. during the Commonwealth Games)and several well-remembered clashes between students, union workers, police and the then-Queensland government. Partly from this context, innovative Brisbane music groups emerged (notably Punk groups) that added to the city's renown.Later in that decade, emission control regulation had a major effect on improving the cities air quality. The banning of backyard incinerators in 1987, together with the closure of two local coal fired power stations in 1986 and a 50% decrease in lead levels found in petrol, resulted in a lowering of pollution levels.Brisbane's historical timeline[edit]1770 Captain James Cook sails up Queensland coast with botanist Joseph Banks; names Cape Moreton, Point Lookout and Glass House Mountains. Takes possession of eastern Australia, naming it New South Wales.1799 Captain Matthew Flinders explores Moreton and Hervey bays; names Red Cliff Point (now Redcliffe), Pumice-stone River (now Pumicestone Passage). Also lands on Coochiemudlo Island.1823 Emancipated convicts John Finnegan, Richard Parsons, and Thomas Pamphlett were shipwrecked off Moreton Island while looking for timber (a fourth person, John Thomson, died at sea). Following a quarrel, Parsons continues north while others stay on the island.1823 Surveyor-general John Oxley arrives at Bribie Island to evaluate Moreton Bay as a site for penal settlement. Discovers Finnegan and Pamphlett who guide him to the Brisbane River; names Peel Island, Pine River and Deception Bay.1824 Oxley discovers Parsons and returns him to Sydney.1824 First commandant Lt. Henry Miller arrives at Red Cliffe Pt from Sydney with soldiers, a storekeeper and their families, John Oxley, botanist Allan Cunningham, stock and seeds.1824 First settler born in colony named Amity Moreton Thompson.1825 Shipping channel via South Passage found; settlement moves to Brisbane River; first convict buildings built along William St.1825 Edmund Lockyer of 57th Regiment explores Brisbane River. Notes flood debris 100 feet above river levels at Mount Crosby, finds first coal deposits. Names Redbank after soil colour.1826 Captain Patrick Logan takes over as commandant of colony. Achieves extensive stone building program using convict labour. Discovers Southport bar and Logan River.1827 Allan Cunningham leaves Hunter Region to seek link via New England Tableland to Darling Downs.1827 Indigenous resistance leader "Napoleon" exiled to St Helena Island. Aborigines raid maize plots, resist advances. Frequent conflict until the 1840s.1828 Cunningham discovers gap in Great Dividing Range, providing access from Moreton Bay to Darling Downs. Also explores Esk-Lockyer basin and upper Brisbane Valley in 1829.1829 Moreton Bay Aborigines seriously affected by smallpox.1830 Captain Logan mysteriously murdered near Esk, commemorated in folk song, "The Convict's Lament".1831 Moreton Bay settlement population reaches 1241, including 1066 convicts.1833 Ship Stirling Castle wrecked on Swain Reef; first of many ships to wreck on Queensland coast over next 40 years.1836 Quaker missionaries report Moreton Bay indigenous population infected with venereal disease from American whalers.1837 Brisbane's pioneering Petrie family arrives in Moreton Bay. Andrew Petrie(builder and stonemason) is clerk of government works; stays on with wife Mary and five children after penal settlement closes. Son John Petrie becomes Brisbane's first mayor; other son Tom writes sympathetically about local indigenous people.1839 Calls to cease convict transportation successful; Moreton Bay is closed as a penal settlement. 2062 men and 150 women served sentences at the settlement, half of them being Irish; 10 percent died, 700 fled, 98 never recaptured.1840 Escaped convict John Baker surrenders after 14 years of living with indigenous Australians.1841 Indigenous people Merridio and Neugavil are executed at Wickham Terrace windmill for the murder of surveyor Stapylton and his assistant in Logan.1842 New South Wales Governor George Gipps proclaims Moreton Bay a free settlement. Land is offered for sale from Sydney.1846 Squatter and entrepreneur Evan Mackenzie succeeds in making Brisbane a port independent from Sydney.1846 Recorded population of Moreton Bay area is 4000 Aborigines and 2257 migrants.1848 First 240 government-assisted British migrants arrive in Brisbane. FirstChinese labourers arrive.1849 Rev Dr J.D. Lang, local clergyman and journalist, brings his first English, Irish, Welsh and Scottish migrants with unauthorised promise of land grants. Government rations issued to prevent starvation. Lang envisages a colony of self-sufficient, thrifty and hard-working farmers, workers and artisans.1849 Brisbane School of Arts established.1849 William Pettigrew arrives in colony. He later becomes the mayor of Brisbane in 1870 and is a member of the Legislative Assembly of Queensland between 1877–94.1850 Areas beyond inner Brisbane suburbs, such as Bulimba, Coorparoo,Enoggera, Nundah, Sherwood and Stafford are used for agriculture and grazing until the 1880s.1850 Displaced aborigines from Bribie Island, Redcliffe peninsula and Wide Bay make gunyah camps in Breakfast Creek/Eagle Farm region (until the 1860s).1850 Arthur Lyon sends sample of cotton from New Farm to The Great Exhibitionin London.1851 Influenza epidemic hits Brisbane (lasting in 1852).1855 Nearly 1000 German migrants arrive in Brisbane after political unrest and the introduction of compulsory military training; most settle in the Nundah area.1855 (5 January) Aboriginal resistance leader Dundalli hanged near current Post Office. Large-scale protests by indigenous tribes.1862 Old Government House is completed.1864 Great Fire of Brisbane1866 11 September, food riots that were instigated by the recently retrenched workers.[15]1867 Parliament House opens.1885 Horse-drawn tram system commences operation.1893 Brisbane flood.1897 Electric trams introduced.1899 Queensland Museum leaves the old State Library Building to move into Exhibition Hall (later called the Old Museum), at Gregory Terrace, Bowen Hills.1901 Celebrations held to mark Federation, on New Year's Day.1901 Fire alarms and pillar hydrants introduced to Brisbane city streets.1902 Central Railway Station in Ann Street, Brisbane completed.1902 Brisbane officially designated city status by the Government of Queensland.1909 Government House opens at Bardon1909 University of Queensland opens near Parliament House.1922 Queensland Government purchases privately owned tram system and establishes the Brisbane Tramways Trust.1925 Amalgamation of 25 local government areas to form the City of Greater Brisbane.1925 Queensland Government transfers responsibility for the tram system from the Brisbane Tramways Trust to the Brisbane City Council.1927 Lone Pine Koala Sanctuary founded1928 Sir Charles Kingsford Smith lands in Brisbane, from San Francisco, USA, after the first flight across the Pacific Ocean.1930 Brisbane City Hall opened.1939 Forgan Smith building completed at the St. Lucia campus of the University of Queensland. (Forgan Smith building was named after the, then, Premier of Queensland)1940 Story Bridge completed1942 General Douglas MacArthur arrives in Brisbane and takes offices in the AMP building (later called MacArthur Central) for the Pacific campaign duringWorld War II1946 Following a delay caused by World War II the University of Queenslandbegan its move from George Street, Brisbane, to its St Lucia campus, which it completed in 1972.1964 Adoption of first Brisbane Town Plan1965 Queensland Institute of Technology (later Queensland University of Technology) established1968 Brisbane City Council announces conversion of tram and trolley-bus systems to all-bus operations1969 Tram and trolley bus systems close, new Victoria Bridge opened1974 Brisbane River flooding, the result of continual heavy rain from Cyclone Wanda, causes major damage across city1982 Commonwealth Games1984 Queensland Performing Arts Centre opened at the Queensland Cultural Centre1986 Queensland Museum moves to the Queensland Cultural Centre1986 Tennyson and Bulimba coal-fired power station closed down1986 Gateway Bridge completed.1988 State Library of Queensland leaves the old State Library Building to move to the Queensland Cultural Centre1988 World Expo 88 held at reclaimed industrial land at South Brisbane1989 Queensland Institute of Technology changed status to Queensland University of Technology.1995 Treasury Casino opens2001 Commonwealth Heads of Government Meeting (CHOGM), scheduled for Brisbane, but postponed after heightened security concerns resulting fromterrorist attacks on New York City. Instead it was held in Coolum in early 20022001 Goodwill Games Opening ceremony included performances from Traditional Owners – Nunukul Yuggera Aboriginal Dancers, The Corrs, Keith Urban.2011 Brisbane River flooding2014 Host city of the 9th G-20 Summit – Opening Ceremony included performances from Nunukul Yuggera Aboriginal Dancers and Bangurra Dance Theatre.See also[edit]Brisbane portalHistory of QueenslandHistory of association football in Brisbane, QueenslandReferences[edit]Jump up^ The Life of Captain Matthew FlindersJump up^ "Port Bowen (entry 7456)". Queensland Place Names. Queensland Government. Retrieved 30 March 2015.Jump up^ Field's New South Wales p. 89 (published 1925)[1] see footnoteJump up^ Seeing South-East Queensland (2 ed.). RACQ. 1980. p. 7. ISBN 0-909518-07-6.Jump up^ Laverty, John (2009). The Making of a Metropolis: Brisbane 1823—1925. Salisbury, Queensland: Boolarong Press. pp. 2–3. ISBN 978-0-9751793-5-2.Jump up^ "First surveys". History of Mapping and Surveying. Department of Natural Resources and Mines, Queensland Government. Retrieved 27 September 2013.Jump up^ Laverty, John (1974). "Petrie, John (1822–1892)". Australian Dictionary of Biography. Canberra: Australian National University. Retrieved 8 November 2011.Jump up^ Dunn, Col (1985). The History of Electricity in Queensland. Bundaberg: Col Dunn. p. 21. ISBN 0-9589229-0-X.Jump up^ "Yungaba Immigration Depot (entry 600245)". Queensland Heritage Register. Queensland Heritage Council. Retrieved 13 July 2015.Jump up^ Tony Moore (16 July 2013). "Push to remember Brisbane clergyman's role in Anzac history". Brisbane Times (Fairfax Media). Retrieved 19 July 2013.Jump up^ Dunn, Peter. "General Headquarters (GHQ) - South West Pacific Area: AMP Building, corner of Queen and Edward Streets, Brisbane". Oz At War. Retrieved 18 April 2015.Jump up^ Dunn, Peter. "The Battle of Brisbane - 26 & 27 November 1942". Oz At War. Retrieved 18 April 2015.Jump up^ McBride, Frank; et al. (2009). Brisbane 150 Stories. Brisbane City Council Publication. p. 226. ISBN 978-1-876091-60-6.Jump up^ Allan Krosch (9 March 2009). "History of Brisbane's Major Arterial Roads: A Main Roads Perspective Part 1" (PDF). Queensland Roads, Edition 7. Department of Transport and Main Roads. Retrieved 5 November 2011.Jump up^ Evans, Raymond (2007). A History of Queensland. Port Melbourne, Victoria: Cambridge University Press. p. 85. ISBN 978-0-521-87692-6.Further reading[edit]J.R. Cole, Shaping a City: Greater Brisbane 1925–1985, Brisbane 1984G. Greenwood and J. Laverty, Brisbane 1859–1959, BCC, 1959J. G. Steele (1975). Brisbane Town in convict days, 1824–1842. University of Queensland Press. ISBN 0702209252.External links[edit]Wikimedia Commons has media related to History of Brisbane.Australian Heritage Historical Towns Directory: BrisbaneBrisbane Tramway MuseumThe Home Front – World War 2Brisbane’s role in WWII focus of new book regarding Brisbane as a large submarine base in World War IIState Library of QueenslandGoogle map of Pre 1925 merger Brisbane CouncilsCategories:History of BrisbaneAustralian timelinesTimelines of cities in AustraliaQueensland timelinesNavigation menuNot logged inTalkContributionsCreate accountLog inArticleTalkReadEditView historyhttps://en.wikipedia.org/wiki/Main_PageMain pageContentsFeatured contentCurrent eventsRandom articleDonate to WikipediaWikipedia storeInteractionHelpAbout WikipediaCommunity portalRecent changesContact pageToolsWhat links hereRelated changesUpload fileSpecial pagesPermanent linkPage informationWikidata itemCite this pagePrint/exportCreate a bookDownload as PDFPrintable versionLanguagesதமிழ்Edit linksThis page was last modified on 26 November 2015, at 12:32.Text is available under the Creative Commons Attribution-ShareAlike License; additional terms may apply. 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