Download Free Inquiry Science Teaching A Fire To Be Kindled Book in PDF and EPUB Free Download. You can read online Inquiry Science Teaching A Fire To Be Kindled and write the review.

The notion of Inquiry is often difficult for a science teacher to get a handle on. What is it exactly? And how can a teacher perform an inquiry lesson? This book begins by exploring this concept, then challenges the reader in an unconventional manner to take a stand about how they teach science. Step by step instructions are given to help the novice as well as the experienced middle and high school teacher to effectively conduct inquiry lessons. This book is linked to over six hours of video - providing teachers with model inquiry lessons in biology, chemistry, physics and earth science. Additionally, video-based evaluative guidelines are included to help teachers reflect on their instruction and improve how they conduct inquiry lessons. Coupling a clearly articulated process of doing inquiry, with video and self-assessment, science teachers will be empowered to take their instruction to the next level, and by so doing facilitate their students' understanding of science. (Please note that links within this book must be copied and pasted into your browser to function correctly.)
Global warming, our current and greatest challenge, is without precedent. Among the many consequences that are impacting our society, one unanticipated concern involves scientific truth. When the President of the United States, and others in his administration, declare that global warming is fake science, it calls into question what real science is and what real school science should be. I will argue that real science is quality science, one that is based on the rigorous collection of reliable and valid data. To collect quality data requires bending over backwards to get things right, and this is exactly what makes science so special. Truth is made when scientists go this extra yard and devise controlled experiments, collect large data sets, confirm the data, and rationally analyze their results. Making scientific truth sounds difficult to do in the science laboratory, but in reality, there are many straightforward ways that truth can be constructed. In the first of two volumes, I discuss twelve such ways – I call them Confidence Indicators – that can allow students to strongly believe in their data and their subsequent results. Many of these methods are intuitive and can be used by young students on the late elementary level all the way up to those taking introductory college science courses. As in life, science is not without doubt. In the second volume I introduce the concept of scientific uncertainty and the indicators used to calculate its magnitude. I will show that science is about connecting confidence with uncertainty in a specific manner, what I refer to as the Confidence-Uncertainty Continuum expression. This important relationship epitomizes the scientific enterprise as a search for probabilistic rather than absolute truth. This two-volume set will contain a variety of ways that data quality can be instituted into a science curriculum. To support its use, many of the examples that I will present involve science teachers as well as student work and feedback from different grade levels and in different scientific disciplines. Specific chapters will be devoted to reviewing the academic literature on data quality as well as describing my own personal research on this important but often neglected topic.
This volume focuses specifically on narrative inquiry as a means to interrogate research questions in music education, offering music education researchers indispensible information on the use of qualitative research methods, particularly narrative, as appropriate and acceptable means of conducting and reporting research. This anthology of narrative research work in the fields of music and education builds on and supports the work presented in the editors’ first volume in Narrative Inquiry in Music Education: Troubling Certainty (Barrett & Stauffer, 2009, Springer). The first volume provides a context for undertaking narrative inquiry in music education, as well as exemplars of narrative inquiry in music education and commentary from key international voices in the fields of narrative inquiry and music education respectively.
For the first time in science education, the subject of multiple solution methods is explored in book form. While a multiple method teaching approach is utilized extensively in math education, there are very few journal articles and no texts written on this topic in science. Teaching multiple methods to science students in order to solve quantitative word problems is important for two reasons. First it challenges the practice by teachers that one specific method should be used when solving problems. Secondly, it calls into question the belief that multiple methods would confuse students and retard their learning. Using a case study approach and informed by research conducted by the author, this book claims that providing students with a choice of methods as well as requiring additional methods as a way to validate results can be beneficial to student learning. A close reading of the literature reveals that time spent on elucidating concepts rather than on algorithmic methodologies is a critical issue when trying to have students solve problems with understanding. It is argued that conceptual understanding can be enhanced through the use of multiple methods in an environment where students can compare, evaluate, and verbally discuss competing methodologies through the facilitation of the instructor. This book focuses on two very useful methods: proportional reasoning (PR) and dimensional analysis (DA). These two methods are important because they can be used to solve a large number of problems in all of the four academic sciences (biology, chemistry, physics, and earth science). This book concludes with a plan to integrate DA and PR into the academic science curriculum starting in late elementary school through to the introductory college level. A challenge is presented to teachers as well as to textbook writers who rely on the single-method paradigm to consider an alternative way to teach scientific problem solving.