Analyse The Value Of Teaching Science Through Investigations

Standard: K-2, Science is a way of knowing… Science knowledge helps us know about the world.

The process skills approach to teaching is defined as the educator helping children develop science skills and processes to confidently undertake their own investigations (Campbell, 2012). These skills are developed through: communicating, science language, asking questions, making sense of phenomena, predicting, modelling, conducting investigations, planning, testing, observing, reasoning, and drawing conclusions of science concepts (Campbell, 2012). When the educator assist children’s learning, it is important to put the emphasis on the nature of science and scientific concepts. Guided discovery approach to teaching requires the educator to ask effective questions that encourage children to explore and extend their investigations throughout science learning (Campbell, 2012). This can be developed through play experiences as children explore their world around them. An interactive approach to teaching children is based on questions that lead explorations and the educators to provide essential resources to guide these explorations (Campbell, 2012). It is the educators’ responsibility to support children’s development, ideas, questions, ways of thinking, and develop scientific thinking. Furthermore, an inquiry approach to teaching relates to children investigating the answers to their own

In the two essays being discussed we learn that science has a vast range of definitions. Science is the effort to understand (or to understand better), the history of the natural world and how the natural world works with observable physical evidence as the base of understanding. Science is about how the hypothesis is developed and how well it is defended.

The WebQuery, the 5E lesson plan, and the field trip guide, are examples of through which students engage in investigations that enhance learning and that helps them meet the NGSS. These artifacts also indicate my ability to develop lesson plans that promote the learning of science; that align content to the NGSS; that demonstrate the use of assessment to ensure that the students are meeting the standards; and that showcase the use of literature to support grouping strategies and lesson rationale

When teaching natural sciences and technology, teachers need to promote an understanding of seeing these subjects as activities to promote curiosity and enjoyment about the world and that what we encounter around us. The history of science and technology should also be integrated with other subjects. Science and technology should be seen as a contribution to social justice and societal development (Motshekga, 2011). A growing need of discovery in science and technology needs to be promoted in order to form interest in ourselves, society and

On Tuesday the 20th of September, a presentation was required of all students to show a video of individual experiments after a week was given on the day of the original assigning. Given the task of performing an experiment in order to become acquainted with the Scientific method, students of Biology 621A were required to record their experimentations in full - providing a question to be answered, constructing a hypothesis, designing an experiment that would aid in the proving (or disproving) of the hypothesis and collecting the data found from the experiment. These would go on to be graded based on their overall presentation quality, and content in regards to the mastery of the scientific method while proving its functionality and existence in scientific experiments no matter how small, while determining factors like independent or dependant variables.

During the course of the year, we learned about the Investigation-Colloquium Method (I-CM) of the teaching science which emphasizes that children learn more by interacting with their peers, sharing their thoughts and collaborate information among themselves. As the word colloquium suggests, it is an informal gathering of peers during a discussion, it is during this discussion children expand on their learning experiences. This method is similar to what Vygotsky would have considered as the “Zone of Proximal Development.” His theory suggested that during a colloquium children tend to sharpen their perception which will, in turn, promote mental growth. As a future teacher of science, my goal is to base my lesson plans on the I-CM method by using it as a benchmark for my instructional practices. Some of these approaches would include concepts, materials, investigations, use of data charts, creative dramatics, and closure to name a few. Each of these subcategories of I-CM further enhances the concept of this method which will be discussed later in further detail. However, in my opinion, the role of a teacher is the pinnacle entity for a successful colloquium among children and an even more successful pedagogy of science.

A 2, 500 word assignment which examines the role of the learning mentor and analyses the strategies used in supporting science, evaluating the impact on pupils’ learning.

This framework builds on previous high quality works in science education: Science for All Americans (1989), Benchmarks for Science Literacy (1993), and NSES (1996). Unlike these previous standards, the importance of having the scientific and educational research communities was taken into the process for developing the framework. Thus, the most current research on science and science learning was grounded when identifying the science that all K-12 students should know, which increased its scientific validity and accuracy. The second step was facilitated by Achieve, Inc. with the recognition of the importance of state and educator leadership in the development of the actual standards. Thus, state policy leaders, higher education, K–12 teachers, and the science and business community were involved when developing Next Generation of Science Standards

As Whitehead says, “If a science forgets its heroes, it is lost.” Learning about nature of science and its social and cultural aspects will enhance of our understanding that science is a human endeavor. Science is a way of explaining natural phenomena by using interpretations and interferences with experimental data and observations. However, including history of science in our teachings, as well as a laboratory part, is a great way to illuminate students about the evolution of science and how scientists can take risks and sometimes fail while seeking information. Whether they study science fields or not, this history will encourage students to make and learn from mistakes while engaged in scientific practices that will expand their

Based on the NSTA Position statement, the curriculum of science from kindergarten through 12 grades has kept changing during the century of rapid development of science. Those changes increase the complexity of teaching and learning science. Teachers are required to design the science class that provides sufficient and effective activities of science to students. In addition, students are expected to complete the task by following the instruction and to adopt the factual knowledge replacing the superficial information or isolated facts. The importance of science programs is to assist students to adapt the community of the well-developed science, and develop student’s self-assessment skills.

This assignment is a case study of a child’s engagement, inquiry skills and understanding of physical or chemical understandings. There are two parts to the assignment that build to the final case study report. Part A is to design a science inquiry activity suitable for engaging a child at junior primary with physical or chemical science understandings that uses materials like water, sand, ball or tubes. At the next, it is needed to figure out how the planned inquiry activity links to the Australian Curriculum and the early Years Learning Framework. This report also needs to explain and justify the learning theory that underpins the activity and the proposed teaching and learning approach. At the last

The National Curriculum for Science (2013), anticipates to advance all pupils’ scientific knowledge and conceptualise understanding through the segmented scientific approaches; biology, chemistry and physics. In addition, pupils should have an awareness of the nature, processes and approaches used within science, through the various scientific enquires that enable pupils to answer questions related to the world and life. Finally, the aims of the science curriculum also consider that children must have the resources to fund the knowledge that is necessary to use science in the, present and future tense states the Department of Education (2013).

Students are considered to be scientists in the inquiry process. Children will view themselves as scientists as they learn. They look forward to science, demonstrate a desire to learn more, seek collaboration with their classmates, they are confident in doing science, and willing to take risks. Students are readily engaged in exploring science. They have curiosity, ponder observations, move around to get the materials they need, and have the opportunity to try out their ideas. Students are able to communicate using various amounts of methods. They express their ideas in journals, reporting, or drawing. They listen, speak, and write about science. They communicate their level of understanding of concepts and ideas. The students propose explanations and solutions based off their data. They use investigations to satisfy their own questions. They sort out information that is needed and important. They become willing to revise explanations and gain new knowledge. They raise questions, use questions to lead them to investigations, and students begin to enjoy using questions to ponder ideas. Students begin to observe rather than look. They see details, detect sequences, and notice change, similarities, and differences. The students begin to make

Science is, by its nature, inquiry based and science knowledge is built through processes in which discoveries of the natural world are made (Abruscato, 2000). It utilizes discovery and scientific thinking process to explore and learn knowledge and skills. Learning by doing is the new efficient method in teaching science. For kindergarten, this method leads to better understanding of science concepts and builds skills that children will use in future life .What a child can do with assistance now, they can later do on their own (Vygotsky, 1978). John Dewey (1916) stated that children must be engaged in an active quest for learning and new ideas. Inquiry is important in educating kindergarteners because it not only keeps them interested in lessons but also helps them retain more information when performing exploration and investigation. Children are naturally motivated to learn and actively seek out information to help their understanding (Piaget, 1950).The success of students who participate in hands- on inquiry activities suggests that if students have first hands experience with science, concepts are easier to understand and apply and students are generally more favorable to science and have better understanding of the nature of science .Within a conceptual framework, inquiry learning and active learner involvement can lead to important outcomes in the classroom. In kindergarten, students who are actively making observations, collecting results and drawing