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Science, technology, society and environment (STSE) education, originates from the science technology and society (STS) movement in Science Education . This is an outlook on science education that emphasizes the teaching of scientific and technological developments in their cultural, economic, social and political contexts. In this view of science education, students are encouraged to engage in issues pertaining to the impact of science on everyday life and make responsible decisions about how to address such issues (Solomon, 1993 and Aikenhead, 1994). HISTORICAL CONTEXT STS is rooted in the Postmodernist view of Science (Fensham 1985; Pedretti 1997 and Aikenhead, 2003). This sees science as a human endeavour, embedded in the social, economic and political contexts in which scientific developments occur, rather than as sets of theories, facts or observable outcomes (Solomon, 1993 and Bingle & Gaskell,1994). This article provides information about the evolution of STSE, along with the theoretical and pedagogical implications of including STSE perspectives in science education. Science technology and society (STS) The STS movement has a long history in science education reform, and embraces a wide range of theories about the intersection between science, technology and society (Solomon and Aikenhead, 1994; Pedretti 1997). Over the last twenty years, the work of Peter Fensham, the noted Australian science educator, is considered to have heavily contributed to reforms in science education. Fensham's efforts included giving greater prominence to STS in the school science curriculum (Aikenhead, 2003). The key aim behind these efforts was to ensure the development of a broad-based science curriculum, embedded in the socio-political and cultural contexts in which it was formulated. From Fensham's point of view, this meant that students would engage with different viewpoints on issues concerning the impact of science and technology on everyday life. They would also understand the relevance of scientific discoveries, rather than just concentrate on learning scientific facts and theories that seemed distant from their realities (Fensham, 1985 & 1988). However, although the wheels of change in science education had been set in motion during the late 1970s, it was not until the 1980s that STS perspectives began to gain a serious footing in science curricula, in largely Western contexts (Gaskell, 1982). This occurred at a time when issues such as, Animal Testing , Environmental Pollution and the growing impact of technological innovation on social infrastructure, were beginning to raise ethical, moral, economic and political dilemmas (Fensham, 1988 and Osborne, 2000). There were also concerns among communities of researchers, educators and governments pertaining to the general public's lack of understanding about the interface between science and society (Bodmer, 1985; Durant ''et al.'' 1989 and Millar 1996). In addition, alarmed by the poor state of scientific literacy among school students, science educators began to grapple with the quandary of how to prepare students to be informed and active citizens, as well as the scientists, medics and engineers of the future (e.g. Osborne, 2000 and Aikenhead, 2003). Hence, STS advocates called for reforms in science education that would equip students to understand scientific developments in their cultural, economic, political and social contexts. This was considered important in making science accessible and meaningful to all students -- and, most significantly, engaging them in real world issues (Fensham, 1985; Solomon, 1993; Aikenhead, 1994 and Hodson 1998). Goals of STS The key goals of STS are:
Scope and emphasis Over the last two decades, STS curricula have taken a variety of forms. These emphasize a particular aspect of STS according to the socio-political environment in which they are formulated, as well as the particular views of curriculum developers on STS education and what is considered valid knowledge in a science curriculum (Solomon & Aikenhead 1994 and Aikenhead, 2003). For example, in Canada and Israel, STS goals directed towards understanding environmental issues were given greater emphasis. Hence, the addition of “E” to STS, producing STSE and STES respectively. Whereas, in Belgium, goals focusing on ethics were given greater prominence in STS education, and resulted in the publication of the journal ''Science Technologies Ethique Societé'', (Aikenhead, 2003). However, for the most part, STS curricula are bound by an overarching curriculum framework. This reflects the three curriculum content areas for STS education described by Hodson (1998): ''Learning science and technology'': acquiring and developing conceptual and theoretical knowledge in science and technology, and gaining a familiarity with a range of technologies. ''Learning about science and technology'': developing an understanding of the nature and methods of science and technology, an awareness of the complex interactions among science, technology, society and environment, and a sensitivity to the personal, social and ethical implications of particular technologies. ''Doing science and technology'': engaging in and developing expertise in scientific inquiry and problem solving; developing confidence and competence in tackling a wide range of “real world” technological tasks. STSE EDUCATION There is no uniform definition for STSE education. As mentioned before, STSE is a form of STS education, but places greater emphasis on the environmental consequences of scientific and technological developments. In STSE curricula, scientific developments are explored from a variety of economic, environmental, ethical, moral, social and political (Kumar and Chubin, 2000 & Pedretti, 2005) perspectives. At best, STSE education can be loosely defined as a movement that attempts to bring about an understanding of the interface between science, society, technology and the environment. A key goal of STSE is to help students realize the significance of scientific developments in their daily lives and foster a voice of active citizenship (Pedretti & Forbes, 2000). Improving scientific literacy Over the last two decades, STSE education has taken a prominent position in the science curricula of different parts of the world, such as Australia, Europe, the UK and USA (Kumar & Chubin, 2000). In Canada, the inclusion of STSE perspectives in science education has largely come about as a consequence of the ''Common Framework of science learning outcomes, Pan Canadian Protocol for collaboration on School Curriculum (1997)'' {Link without Title} . This document highlights a need to develop scientific literacy in conjunction with understanding the interrelationships between science, technology, and environment. According to Osborne (2000) & Hodson (2003), scientific literacy can be perceived in four different ways:
Rationale and goals In the context of STSE education, the goals of teaching and learning are largely directed towards engendering cultural and democratic notions of scientific literacy. Here, advocates of STSE education argue that in order to broaden students understanding of science, and better prepare them for active and responsible citizenship in the future, the scope of science education needs to go beyond learning about scientific theories, facts and technical skills. Therefore, the fundamental aim of STSE education is to equip students to understand and situate scientific and technological developments in their cultural, environmental, economic, political and social contexts (Solomon & Aikenhead, 1994; Bingle & Gaskell, 1994; Pedretti 1997 & 2005). For example, rather than learning about the facts and theories of weather patterns, students can explore them in the context of issues such as global warming. They can also debate the environmental, social, enconomic and political consequences of relevant legislation, such as the Kyoto Protocol . This is thought to provide a richer, more meaningful and relevant canvas against which scientific theories and phenomena relating to weather patterns can be explored (Pedretti ''et al.'' 2005). In essence, STSE education aims to develop the following skills and perspectives (Aikenhead, 1994; Pedretti, 1996; Alsop & Hicks, 2001):
Curriculum content Since STSE education has multiple facets, there are a variety of ways in which it can be approached in the classroom. This offers teachers a degree of flexibility, not only in the incorporation of STSE perspectives into their science teaching, but in integrating other curricular areas such as history, geography, social studies and language arts (Richardson & Blades, 2001). The table below summarizes the different approaches to STSE education described in the literature (Ziman, 1994 & Pedretti, 2005): Summary table: Curriculum content Opportunities and challenges of STSE education Although advocates of STSE education keenly emphasize its merits in science education, they also recognize inherent difficulties in its implementation. The opportunities and challenges of STSE education have been articulated by Hughes (2000) and Pedretti & Forbes, (2000), at five different levels, as described below: Values & beliefs: The goals of STSE education may challenge the values and beliefs of students and teachers -- as well as conventional, culturally entrenched views on scientific and technological developments. Students gain opportunities to engage with, and deeply examine the impact of scientific development on their lives from a critical and informed perspective. This helps to develop students' analytical and problem solving capacities, as well as their ability to make informed choices in their everyday lives. As they plan and implement STSE education lessons, teachers need to provide a balanced view of the issues being explored. This enables students to formulate their own thoughts, independently explore other opinions and have the confidence to voice their personal viewpoints. Teachers also need to cultivate safe, non-judgmental classroom environments, and must also be careful not to impose their own values and beliefs on students. Knowledge & understanding: The interdisciplinary nature of STSE education requires teachers to research and gather information from a variety of sources. At the same time, teachers need to develop a sound understanding of issues from various disciplines -- philosophy, history, geography, social studies, politics, economics, environment and science. This is so that students’ knowledge base can be appropriately scaffolded to enable them to effectively engage in discussions, debates and decision-making processes. This ideal raises difficulties. Most science teachers are specialized in a particular field of science. Lack of time and resources may effect how deeply teachers and students can examine issues from multiple perspectives. Nevertheless, a multi-disciplinary approach to science education enables students to gain a more rounded perspective on the dilemmas, as well as the opportunities, that science presents in our daily lives. Pedagogic approach: Depending on teacher experience and comfort levels, a variety of Pedagogic approaches based on Constructivism can be used to stimulate STSE education in the classroom. As illustrated in the table below, the pedagogies used in STSE classrooms need to take students through different levels of understanding to develop their abilities and confidence to critically examine issues and take responsible action. Teachers are often faced with the challenge of transforming classroom practices from task-oriented approaches to those which focus on developing students' understanding and transferring agency for learning to students (Hughes, 2000). The table below is a compilation of pedagogic approaches for STSE education described in the literature (e.g. Hodson, 1998; Pedretti & Forbes 2000; Richardson & Blades, 2001): Summary table: Classroom practice Time & resources: The multi-faceted approach of STSE education requires teachers to move beyond conventional curriculum materials, and explore resources in other disciplines -- social geography, history, social studies and politics. A teacher's time and effort are needed to collect such resources, develop background knowledge, and integrate them for successful and effective STSE lesson planning. Assessment & evaluation: The broad, inquiry-based approach to STSE education requires tools that assess students understanding of issues and skills-development (e.g. problem solving, analysis, communication, presentation), rather than their decisions or opinions. Hence, STSE education calls for the use of qualitative rather than quantitative Assessment methods. It is difficult to develop assessment or evaluation criteria for such a personalized, objective, view of science. Teachers need to clarify for students that it is their efforts and skill development that are being assessed, rather than opinions. Examples of assessment tools might include quizzes, questionnaires, journal writing, development of portfolios, observations and one-on-one exit interviews. SEE ALSO REFERENCES
EXTERNAL LINKS AND RESOURCES FOR STSE EDUCATION Websites
Samples of science curricula
The Councils of Ministers of Education, Canada, website is a useful resource for understanding the goals and position of STSE education in Canadian Curricula.
Books These are examples of books available for information on STS/STSE education, teaching practices in science and issues that may be explored in STS/STSE lessons.
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