Courtesy : School of Science in UK

Science education in England is generally regulated at all levels for assessments that are England’s, from ‘primary’ to ‘tertiary’ (university). Below university level, science education is the responsibility of three bodies: the Department for Education, Ofqual and the QAA, but at university level, science education is regulated by various professional bodies, and the Bologna Process via the QAA. The QAA also regulates science education for some qualifications that are not university degrees via various qualification boards, but not content for GCSEs, and GCE AS and A levels. Ofqual on the other hand regulates science education for GCSEs and AS/A levels, as well as all other qualifications, except those covered by the QAA, also via qualification boards. # ISO certification in India

The Department for Education prescribes the content for science education for GCSEs and AS/A levels, which is implemented by the qualification boards, who are then regulated by Ofqual. The Department for Education also regulates science education for students aged 16 years and under. The department’s policies on science education (and indeed all subjects) are implemented by local government authorities on all state schools (also called publicly funded schools) in England. The content of the nationally organised science curriculum (along with other subjects) for England is published in the National Curriculum, which covers key stage 1 (KS1), key stage 2 (KS2), key stage 3 (KS3) and key stage 4 (KS4). The four key stages can be grouped a number of ways; how they are grouped significantly affects the way the science curriculum is delivered. In state schools, the four key stages are grouped into KS1–2 and KS3–4; KS1–2 covers primary education while KS3–4 covers secondary education. But in independent or public (which in the United Kingdom are historic independent) schools (not to be confused with ‘publicly funded’ schools), the key stage grouping is more variable, and rather than using the terms ‘primary’ and ‘secondary’, the terms ‘prep’ and ‘senior’ are used instead.# ISO certification in India

Science is a compulsory subject in the National Curriculum of England, Wales and Northern Ireland; state schools have to follow the National Curriculum while independent schools need not follow it. That said, science is compulsory in the Common Entrance Examination for entry into senior schools, so it does feature prominently in the curricula of independent schools. Beyond the National Curriculum and Common Entrance Examination, science is voluntary, but the government of the United Kingdom (comprising England, Wales, Scotland and Northern Ireland) provides incentives for students to continue studying science subjects. Science is regarded as vital to the economic growth of the United Kingdom (UK). For students aged 16 years (the upper limit of compulsory school age in England, but not compulsory education as a whole) and over, there is no compulsory nationally organised science curriculum for all state/publicly funded education providers in England to follow, and individual providers can set their own content, although they often (and in the case of England’s state/publicly funded post-16 schools and colleges have to) get their science (and indeed all) courses accredited or made satisfactory (ultimately by either Ofqual or the QAA via the qualification boards). Universities do not need such approval, but there is a reason for them to seek accreditation regardless. Moreover, UK universities have obligations to the Bologna Process to ensure high standards. Science education in England has undergone significant changes over the centuries; facing challenges over that period, and still facing challenges to this day.# ISO certification in India

History

Up to 1800

Gillard (2011) gives a documented account of science curriculum and education during this period. According to his work, the teaching of science in England dates back to at least Anglo-Saxon times. Gillard explains that the first schools in England (that are known of) were created by St Augustine when he brought Christianity to England around the end of the sixth century—there were almost certainly schools in Roman Britain before St Augustine, but they did not survive after the Romans left. It is thought the first grammar school was established at Canterbury in 598 during the reign of King Ethelbert. Gillard also mentions Bede’s Ecclesiastical History, here science (in the form of astronomy) was already part of the curriculum in the early schools of the 600s. As the founding of grammar schools spread from south to north of England, science education spread with it. Science as it is known today developed from two spheres of knowledge: natural philosophy and natural history. The former was associated with the reasoning and explanation of nature while the latter focused more on living things. Both strands of knowledge can be identified in a curriculum provided by a school in York run by Alcuin in the 770s and 780s. Subsequent Viking invasions of England interrupted the development of schools, but despite this, through the ages, education in England was provided by the church and grammar schools (which were linked to the church). The link between church and school started to change in the 1300s when schools independent of the church began to emerge. University education in England started in Oxford in the 1100s (although there is evidence that teaching began there in the 1000s). Like pre-university education, science at Oxford University was initially taught in the form of astronomy (as part of the quadrivium). The Renaissance spurred physical inquiry into nature which led to natural philosophy developing into physics and chemistry, and natural history developing into biology; these three disciplines form natural science, from which interdisciplinary fields (or at least their modern versions) that overlap two or all three branches of natural science develop. This emerging trend in physical inquiry do not appear to have been reflected in the science curriculum in schools at the time. Even in universities, the changes to science education that were necessary as a result of the Renaissance occurred very slowly. It was not till the 1800s that the science curriculum and education recognised in England today at all levels truly began to emerge.# ISO certification in India

1800s

Up until the 1800s there were only two stages of education: elementary and university. However, in the nineteenth century, elementary education began to divide into primary (still called elementary) and secondary education. Elementary schools were defined in law in England through a series of Acts of Parliament which made education compulsory and free for children up to the age of 11 (later increased to 12). There were six (and later seven) standards for children to pass; science education did not feature in any of these standards, but for some schools it was an add-on especially at the higher standards (such as sixth and seventh—science subjects included physics, chemistry, mechanics). Promotion from one standard to the next was on merit and not age. Not all children completed all standards, which meant that by the age of 12, there were children that had not ‘completed’ their elementary education. Of course families that could afford (and wanted) to keep their children in school post-compulsory age to pass all standards did so. In fact some children stayed in school beyond the seventh standard. Schools that offered post-seventh standard education became known as higher grade schools, of which science education was a recognised feature of their curricula.# ISO certification in India

Taunton Report 1868

This was by far the single most important development for science education in schools in England in the nineteenth century from a British parliament point of view. Ironically the original purpose of the committee that authored the ‘Taunton’ Report of 1868, or more formally, Volume II Miscellaneous Papers of the Schools Inquiry Commission (1868), was to examine how best endowed schools should be managed; something Parliament at the time thought was of utmost importance. The committee for the report was chaired by Lord Taunton (born Henry Labouchere). In heading the preparation for the report, Lord Taunton sent a circular letter listing four questions to a number of prominent people in different parts of England on 28 May 1866; the first three were endowment-related issues, but the fourth question was on how to encourage a due supply of qualified teachers. Apart from the contents page, the word “science” first appears on page 45 of the report in a reply by one of the recipients of the circular letter; that recipient was Reverend W C Lake. The reverend comments: The question as to the best mode to be adopted for obtaining teachers both in sufficient numbers, and of the kind desirable for middle-class, education, seems to me more difficult than it would at first appear. … you want men with an University culture, and yet not with exactly an University education. You do not, I presume, want them to teach Greek; and as to Latin it ought not, in my opinion at least, to be the staple work of the school compared with arithmetic, some mathematics, modern languages, and history, and the principles of some important branches of physical science.(Rev. Lake’s reply to Lord Taunton IN Report by Schools Inquiry Commission, 1868: p45)

This was by far the single most important development for science education in schools in England in the nineteenth century from a British parliament point of view. Ironically the original purpose of the committee that authored the ‘Taunton’ Report of 1868, or more formally, Volume II Miscellaneous Papers of the Schools Inquiry Commission (1868), was to examine how best endowed schools should be managed; something Parliament at the time thought was of utmost importance. The committee for the report was chaired by Lord Taunton (born Henry Labouchere). In heading the preparation for the report, Lord Taunton sent a circular letter listing four questions to a number of prominent people in different parts of England on 28 May 1866; the first three were endowment-related issues, but the fourth question was on how to encourage a due supply of qualified teachers. Apart from the contents page, the word “science” first appears on page 45 of the report in a reply by one of the recipients of the circular letter; that recipient was Reverend W C Lake. The reverend comments: The question as to the best mode to be adopted for obtaining teachers both in sufficient numbers, and of the kind desirable for middle-class, education, seems to me more difficult than it would at first appear. … you want men with an University culture, and yet not with exactly an University education. You do not, I presume, want them to teach Greek; and as to Latin it ought not, in my opinion at least, to be the staple work of the school compared with arithmetic, some mathematics, modern languages, and history, and the principles of some important branches of physical science.(Rev. Lake’s reply to Lord Taunton IN Report by Schools Inquiry Commission, 1868: p45)

On page 77 of the report, Edward Twisleton, a member of the Schools Inquiry Commission, comments on the answers provided to the four questions set by the committee’s chairman, Lord Taunton, based on feedback from the circular letter sent. To the first question, Twisleton writes:In providing,—what is generally a part of the arrangements of Prussian gymnasia—a museum of natural history and a cabinet with the philosophical instruments and other materials requisite for instruction in the experimental sciences. The Prussian system should be followed, in which two hours of each week are devoted throughout the school to lessons in these branches of knowledge; the instruction in the lower classes being in sciences of pure observation, such, as zoology and botany, while in the upper parts of the school instruction is given in the sciences usually called experimental, such as pneumatics, hydrostatics, and others. This system, however, cannot be adopted, unless there is a certain preliminary outlay of money, and it seems unobjectionable that this money should come from an endowment.(Twisleton’s response IN Report by Schools Inquiry Commission, 1868: p77)

There were noticeable opinions on the issue of science education from contributors that wrote to the committee to express their views. One by Robert Mosley of Holgate Seminary, York (pages 104 to 105 of the report), suggested the inclusion of physical sciences in a ‘National education’; this national education being the best way to utilise educational endowment. Based on feedback from contributors, the Taunton Committee gave several arguments in favour of science education; two of them are:

• As providing the best discipline in observation and collection of facts, in the combination of inductive with deductive reasoning, and in accuracy both of thought and language.

and

• Because the methods and results of science have so profoundly affected all the philosophical thought of the age, that an educated man is under a very great disadvantage if he is unacquainted with them.

(Report by Schools Inquiry Commission, 1868: p219)

The committee subsequently made several recommendations; the first three on promoting scientific education in schools are listed below: I. That in all schools natural science be one of the subjects to be taught, and that in every public school at least one natural science master be appointed for the purpose. ii. That at least three hours a week be devoted to such scientific instruction. iii. That natural science should be placed on an equal footing with mathematics and modern languages in effecting promotions and in winning honors’ and prizes.(Report by Schools Inquiry Commission, 1868: p222)

The issue of increased cost for fee payers played heavily on the minds of the committee, and although the committee felt that for “a wealthy country like England” (page 219 of the report), a slight increase in cost should not be a barrier to science education, it was left to individual schools to decide how to incorporate science into their curricula.

Red brick universities

By the time of the Taunton Report there were four universities in England (Oxford, Cambridge, Durham and London), but from the 1880s, a new wave of universities / university colleges completely separate from the original four began to emerge; these universities were called red brick universities. The first of these universities was established in Manchester in 1880 and was called Victoria University. Over the subsequent 80 years, a further 11 universities outside London, Cambridge, Durham and Oxford were founded, significantly expanding the availability of university (science) education throughout England. All through the 1800s, science was becoming increasingly specialised into the different areas we know today.

1900s

The Education Act 1902 led to the higher grade schools (alluded to earlier) and fee-paying schools being absorbed into the legally defined “higher education” (meaning any education that was not elementary (as primary education was known at the time)). Despite science education in higher grade schools and the recommendations of the Taunton Report, as well as the British Association for the Advancement of Science’s campaign for a science curriculum, science was still seen as a minor subject by the most prestigious public schools. The problem was that most of these public schools had close relationships with Oxford and Cambridge universities which offered the majority of their scholarships in classics, and so science was regarded in low importance by the prestigious schools. Consequently, science education varied significantly across English schools. Numerous education-related acts were passed throughout the twentieth century, but the most important in the history of science education in England was the Education Reform Act 1988 (see next subsection). Another Act of importance to the development of science education below university level in England was the Education Act 1944. The 1944 Act’s contribution was indirect though—it raised the compulsory school age to 15, but made provisions for it to be raised to 16 at a future date—which happened in 1972 (which is still the case today). By raising the school leaving age to 16, this formed the basis for creating a nationally organised science curriculum and education in England. However, the 1944 Education Act did not stipulate that science be taught. For university level science education, two significant developments were the expansion of distance learning science courses and the introduction of the World Wide Web (via the Internet) into the delivery of science teaching, although this has also been adopted below university level.

Education Reform Act 1988

This was the most important development in the history of science education in England. It was this Act that established the National Curriculum and made science compulsory across both secondary and primary schools (alongside maths and English). The 1988 Act in effect implemented the recommendation of the Taunton Committee made more than a century earlier. The act also established the now familiar “key stages”.