Technology and science education

The incorporation of technology into the school curriculum is part of a worldwide trend in education. The way in which technology is incorporated depends on which country the reform is initiated in. The New Zealand Curriculum Framework (Ministry of Education, 1993a) includes science and technology as distinct learning areas. This chapter considers the view of technology expressed in both science in the New Zealand Curriculum (Ministry of Education, 1993b) and in Technology in the New Zealand Curriculum (Ministry of Education, 1995). The chapter is divided into four sections. Firstly, the concept of technology in the science curriculum is identified and discussed; secondly, the use of some types of technological application to enhance the learning of science outcomes is considered; thirdly, the technology curriculum itself is discussed in order to highlight the concept of technology underpinning this statement so that comparisons can be made with the concept employed in the science curriculum, and finally the introduction of technology outcomes by science teachers in a science environment is explored

Computer science in Dutch secondary education: independent or integrated?

Nowadays, in Dutch secondary education, computer science is integrated within school subjects. About ten years ago computer science was considered an independent subject, but in the mid-1980s this idea changed. In our study we investigated whether the objectives of teaching computer science as an independent subject are met when computer science is integrated within school subjects. The main problem was that there was no formal curriculum of computer science as an independent subject. Therefore we interviewed 13 experts in the field of computer science and then compared this formal curriculum with the operational (integrated) curriculum, which is still in the development stage. It appears that most of the components of the formal curriculum are being covered by the operational curriculum, and we therefore concluded that these curricula are equivalent, although there may be differences in the level of teaching. In our opinion the best approach to computer science is to combine the independent and the integrated approaches

Earth-Science Education: From all over the World to East-Timor

Earth Science education (ESE) emerges as a relatively new research area and there is an unquestioned need for improving students´ abilities on that field (American Geological Institute, 2008), taking into account that it is important for students’ everyday lives and thus, relevant for scientific literacy. So, the inclusion of a section concerned with this issue, was a very wise decision of the 1st Geological Congress at East-Timor Organising Committee, revealing an up to date vision about education for the XXI century. The paper will be divided in four sections: - Science Education - meaning, epistemology and rationale; - Earth- science-education all over the World in the context of Science Education; - Earth- science education in East-Timor secondary school curriculum; - Earth-science education and challenges for the futur

The story of a physiclal science curriculum: transformation or transmutation?

This is an Accepted Manuscript of an article published by Taylor & Francis in African Journal of Research in Mathematics, Science and Technology Education on 20 Aug 2013, available online: http://www.tandfonline.com/10.1080/10288457.2012.10740745.Recently Curriculum and Assessment Policy Statements (CAPS) were introduced in South Africa in response to confusion precipitated by previous curriculum documents. The purpose of this paper is to explore that confusion in the subject 'Physical Sciences' and consider the nature of the transformation from the previous curriculum by looking at curriculum documents and examination papers. We present a two phase curriculum change model which suggests that congruency between curriculum documents and examinations is critical for effective curriculum change. We analyse the pre-CAPS curriculum, the National Curriculum Statement (NCS), on its own terms by using the stated outcomes as our reference point. Our analysis reveals that the weighting and conceptualization of the outcomes shifted through successive documents, which undermined congruency between the documents and meant that content-oriented science masqueraded as inquiry-oriented science. This led to a retreat from the original vision of weighting skills and relevance equally with content. The examinations took this retreat a step further. Evidence of the retreat is that the nature of the questions asked in the 2008 examinations on the NCS was similar to that of the 2007 examinations on the previous curriculum which had not changed since apartheid. However, in the NCS examinations there was a small shift towards contextualisation and inquiry oriented science. The retreat means the vision of transformation which was the rationale for the NCS curriculum was eroded – instead of transformation, there was transmutation back to the old apartheid curriculum. The Physical Sciences CAPS cements the retreat and creates new confusion by changing the syllabus again without signposting the change

Enhancing science education in the elementary schools

This article describes some collaborative activities of the authors, aimed at improving science education in elementary schools. These include curriculum enhancement, development of new apparatus (a wind tunnel), science-education web site contributions and production of a film about the physics of flight. The output of these projects is intended to be generally accessible or reproducible.Comment: To appear in the American Journal of Physics, 3 page

Career-related learning and science education: the changing landscape

Pupils ask STEM subject teachers about jobs and careers in science, but where else do they learn about work? This article outlines career-related learning within schools in England alongside other factors that influence pupils’ career decisions. The effect of the Education Act 2011 will be to change career learning in schools. The impact on science educators as advisers, facilitators, commissioners or managers of career-related learning is discussed, with a conclusion that, while science educators are not career educators, they nevertheless can support career-related learning in their delivery of the curriculum alongside enhancement and enrichment activities.Association for Science Education(ASE)http://www.ase.org.uk/home

The curricular content of primary education in developing countries

This paper examines the curriculum policies for primary schools in a wide range of developing countries in the 1980s and, to a lesser extent, the 1960s. The research covers what subjects are taught, what percentage of instructional time is allocated to each subject, and how much instructional time is available overall in primary education. The results indicate that there is little international debate about primary school curricula. The curricula of mass education systems are increasingly alike all over the world, with surprisingly little regional and national variation. Almost all national educational systems emphasize certain core subjects: language (35%), math (18%), science (8%), and social science (9%).Curriculum&Instruction,Teaching and Learning,Primary Education,Gender and Education,ICT Policy and Strategies

Something for everyone? The different approaches of academic disciplines to Open Educational Resources and the effect on widening participation

This article explores the relationship between academic disciplines‘ representation in the United Kingdom Open University‘s (OU) OpenLearn open educational resources (OER) repository and in the OU‘s fee-paying curriculum. Becher‘s (1989) typology was used to subdivide the OpenLearn and OU fee-paying curriculum content into four disciplinary categories: Hard Pure (e.g., Science), Hard Applied (e.g., Technology), Soft Pure (e.g., Arts) and Soft Applied (e.g., Education). It was found that while Hard Pure and Hard Applied disciplines enjoy an increased share of the OER curriculum, Soft Applied disciplines are under-represented as OER. Possible reasons for this disparity are proposed and Becher‘s typology is adapted to be more appropriate to 21st-century higher education

Relationship between science and technology in the New Zealand curriculum

New Zealand underwent major curriculum reforms in the early1990s. These reforms were determined by the New Zealand Curriculum Framework (Ministry of Education 1993), which provides an overarching framework for the development of curricula in New Zealand and which defines seven broad essential learning areas. The seven essential learning areas that describe in broad terms the knowledge and understanding that all students need to acquire, are health and well-being, the arts, social sciences, technology, science, mathematics,and language and languages. For example, the essential learning area of science includes the subjects of science, biology, chemistry, physics, earth sciences, agriculture, horticulture, and geography, as well as aspects of home economics and environmental studies

High School in Bali

In the Indonesian education system, high school is comprised of 10th, 11th, and 12th grades. In their first year of high school, a Balinese student’s curriculum might look very similar to an American student’s. At this point in their education, the Balinese are still following the national general curriculum, studying mathematics, science, language, and history. During the eleventh and twelfth years of school the Balinese school structure diverges from the American system. Indonesian students must choose one of three areas of study on which to focus for the last two years of high school, a concept similar to a college major. [excerpt