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| title | chunk | source | category | tags | date_saved | instance |
|---|---|---|---|---|---|---|
| Science education | 3/6 | https://en.wikipedia.org/wiki/Science_education | reference | science, encyclopedia | 2026-05-05T04:18:54.994028+00:00 | kb-cron |
Preconceptions Prior ideas about how things work are remarkably tenacious and an educator must explicitly address a student's specific misconceptions if the student is to reconfigure his misconception in favour of another explanation. Therefore, it is essential that educators know how to learn about student preconceptions and make this a regular part of their planning. Knowledge organization In order to become truly literate in an area of science, students must, "(a) have a deep foundation of factual knowledge, (b) understand facts and ideas in the context of a conceptual framework, and (c) organize knowledge in ways that facilitate retrieval and application." Metacognition Students will benefit from thinking about their thinking and their learning. They must be taught ways of evaluating their knowledge and what they do not know, evaluating their methods of thinking, and evaluating their conclusions. Some educators and others have practiced and advocated for discussions of pseudoscience as a way to understand what it is to think scientifically and to address the problems introduced by pseudoscience. Educational technologies are being refined to meet the specific needs of science teachers. One research study examining how cellphones are being used in post-secondary science teaching settings showed that mobile technologies can increase student engagement and motivation in the science classroom. According to a bibliography on constructivist-oriented research on teaching and learning science in 2005, about 64 percent of studies documented are carried out in the domain of physics, 21 percent in the domain of biology, and 15 percent in chemistry. The major reason for this dominance of physics in the research on teaching and learning appears to be that understanding physics includes difficulties due to the particular nature of physics. Research on students' conceptions has shown that most pre-instructional (everyday) ideas that students bring to physics instruction are in stark contrast to the physics concepts and principles to be achieved – from kindergarten to the tertiary level. Quite often students' ideas are incompatible with physics views. This also holds true for students' more general patterns of thinking and reasoning.
== By country ==
=== Australia === As in England and Wales, science education in Australia is compulsory up until year 11, where students can choose to study one or more of the branches mentioned above. If they wish to no longer study science, they can choose none of the branches. The science stream is one course up until year 11, meaning students learn in all of the branches giving them a broad idea of what science is all about. The National Curriculum Board of Australia (2009) stated that "The science curriculum will be organised around three interrelated strands: science understanding; science inquiry skills; and science as a human endeavour." These strands give teachers and educators the framework of how they should be instructing their students. In 2011, it was reported that a major problem that has befallen science education in Australia over the last decade is a falling interest in science. Fewer year 10 students are choosing to study science for year 11, which is problematic as these are the years where students form attitudes to pursue science careers. This issue is not unique in Australia, but is happening in countries all over the world.
=== China === Educational quality in China suffers because a typical classroom contains 50 to 70 students. With over 200 million students, China has the largest educational system in the world. However, only 20% percent of students complete the rigorous ten-year program of formal schooling. As in many other countries, the science curriculum includes sequenced courses in physics, chemistry, and biology. Science education is given high priority and is driven by textbooks composed by committees of scientists and teachers. Science education in China places great emphasis on memorization, and gives far less attention to problem solving, application of principles to novel situations, interpretations, and predictions.
=== United Kingdom ===
In English and Welsh schools, science is a compulsory subject in the National Curriculum. All pupils from 5 to 16 years of age must study science. It is generally taught as a single subject science until sixth form, then splits into subject-specific A levels (physics, chemistry and biology). However, the government has since expressed its desire that those pupils who achieve well at the age of 14 should be offered the opportunity to study the three separate sciences from September 2008. In Scotland the subjects split into chemistry, physics and biology at the age of 13–15 for National 4/5s in these subjects, and there is also a combined science standard grade qualification which students can sit, provided their school offers it. In September 2006 a new science program of study known as 21st Century Science was introduced as a GCSE option in UK schools, designed to "give all 14 to 16-year-old's a worthwhile and inspiring experience of science". In November 2013, Ofsted's survey of science in schools revealed that practical science teaching was not considered important enough. At the majority of English schools, students have the opportunity to study a separate science program as part of their GCSEs, which results in them taking 6 papers at the end of Year 11; this usually fills one of their option 'blocks' and requires more science lessons than those who choose not to partake in separate science or are not invited. Other students who choose not to follow the compulsory additional science course, which results in them taking 4 papers resulting in 2 GCSEs, opposed to the 3 GCSEs given by taking separate science.
=== United States ===