The Development and Validation of the Middle School-Life Science Concept Inventory (MS-LSCI) Using Rasch Analysis

Stammen, Andria

10 August 2018

No description available.

Educational Tests and Measurements

Education

Science Education

Secondary Education

Teaching

Biology

Ecology

concept inventory

middle school science education

life science assessment

biology assessment

concept inventory design

concept inventory validation

middle school life science assessment

middle school biology assessment

Rasch analysis

Rasch model

Conceptual Change: The Integration of Geologic Time into the Teaching of Evolution

Ramseyer, David L

15 December 2012

This study attempts to discern if geologic time is a threshold concept for student understanding of evolutionary theory. A threshold concept enables the learner to unpack other concepts because of its importance in thought construction. In this study three teachers and ten sections of biology were investigated from the same high school. Each teacher used the same activities, in the same sequence, and with identical evaluation methods. Students in the treatment group covered a unit on geologic time prior to completing course work on evolutionary theory. Student misconceptions in both control and treatment groups were assessed using a composite concept inventory administered post and prior to the study. Statistical analysis conducted revealed no statistical evidence to support the contention that the treatment method was more effective than traditional methods of teaching evolution. It was found that students agreed significantly more with evolution post study in both treatment and control groups.

conceptual change

preconceptions

naive conceptions

misconceptions

alternative conceptions

threshold concept

geologic time

deep time

evolution

concept inventory

best practices

science education

education

Conceptual change

Atomic emission misconceptions as investigated through student interviews and measured by the Flame Test Concept Inventory

Mayo, Ana Veronica

08 March 2013

No description available.

Chemistry

Education

Atomic emission misconceptions

flame test demonstrations

energy level diagrams

mode-node framework

student interviews

mixed-method research design

development of a concept inventory

Exploring the Neural Mechanisms of Physics Learning

Bartley, Jessica E

08 November 2018

This dissertation presents a series of neuroimaging investigations and achievements that strive to deepen and broaden our understanding of human problem solving and physics learning. Neuroscience conceives of dynamic relationships between behavior, experience, and brain structure and function, but how neural changes enable human learning across classroom instruction remains an open question. At the same time, physics is a challenging area of study in which introductory students regularly struggle to achieve success across university instruction. Research and initiatives in neuroeducation promise a new understanding into the interactions between biology and education, including the neural mechanisms of learning and development. These insights may be particularly useful in understanding how students learn, which is crucial for helping them succeed. Towards this end, we utilize methods in functional magnetic resonance imaging (fMRI), as informed by education theory, research, and practice, to investigate the neural mechanisms of problem solving and learning in students across semester-long University-level introductory physics learning environments. In the first study, we review and synthesize the neuroimaging problem solving literature and perform quantitative coordinate-based meta-analysis on 280 problem solving experiments to characterize the common and dissociable brain networks that underlie human problem solving across different representational contexts. Then, we describe the Understanding the Neural Mechanisms of Physics Learning project, which was designed to study functional brain changes associated with learning and problem solving in undergraduate physics students before and after a semester of introductory physics instruction. We present the development, facilitation, and data acquisition for this longitudinal data collection project. We then perform a sequence of fMRI analyses of these data and characterize the first-time observations of brain networks underlying physics problem solving in students after university physics instruction. We measure sustained and sequential brain activity and functional connectivity during physics problem solving, test brain-behavior relationships between accuracy, difficulty, strategy, and conceptualization of physics ideas, and describe differences in student physics-related brain function linked with dissociations in conceptual approach. The implications of these results to inform effective instructional practices are discussed. Then, we consider how classroom learning impacts the development of student brain function by examining changes in physics problem solving-related brain activity in students before and after they completed a semester-long Modeling Instruction physics course. Our results provide the first neurobiological evidence that physics learning environments drive
the functional reorganization of large-scale brain networks in physics students. Through this collection of work, we demonstrate how neuroscience studies of learning can be grounded in educational theory and pedagogy, and provide deep insights into the neural mechanisms by which students learn physics.

neuroeducation

physics education

neuroimaging

fMRI

problem solving

science reasoning

STEM learning

brain network

meta-analysis

functional connectivity

modeling instruction

Force Concept Inventory

Cognition and Perception

Cognitive Neuroscience

Curriculum and Instruction

Neurosciences

Other Education

Other Physics

Science and Mathematics Education

Biochemistry Students' Understandings of Enzyme-Substrate Interactions as Investigated through Multiple Representations and the Enzyme-Substrate Interactions Concept Inventory

Linenberger, Kimberly J.

18 November 2011

No description available.

Biochemistry

Biophysics

Chemistry

Educational Tests and Measurements

Educational Theory

Molecular Biology

Science Education

Teaching

Enzyme-Substrate Interactions

Misconceptions

Concept Inventory

Representations

Biochemistry

Student Understanding

Assessment

Serine Protease

Myoglobin

Biophysical Laboratory

The effectiveness of applying conceptual development teaching strategies to Newton's second law of motion / Carel Hendrik Meyer

Meyer, Carel Hendrik

January 2014

School science education prepares learners to study science at a higher level, prepares them to follow a career in science and to become scientific literate citizens. It is the responsibility of the educator to ensure the learners’ conceptual framework is developed to the extent that secures success at higher level studies. The purpose of this study was to test the effectiveness of conceptual change teaching strategies on the conceptual development of grade 11 learners on Newton’s second law of motion. The two strategies employed were the cognitive conflict strategy and the development of ideas strategy. A sequential explanatory mixed-method research design was used during this study. The qualitative data were used to elucidate the quantitative findings. The quantitative research consisted of a quasi-experimental design consisting of a single-group pre-test–post-test method. During the qualitative part of the research a phenomenological research approach was utilised to gain a better understanding of participants’ learning experiences during the intervention. The quantitative research made use of an adapted version of the Force Concept Inventory (FCI). The data collected from the pre-test were used to inform the intervention. The intervention was videotaped and the video analysis or qualitative data analysis was done. After the intervention the post-test was written by the learners. Hake’s average normalised learning gain <g> from pre- to post-scores was analysed to establish the effectiveness of the intervention. The two sets of results (quantitative and qualitative) were integrated. Information from the qualitative data analysis was used to support and explain the quantitative data. The quantitative results indicate that there was an improvement in the students’ force conception from their initial alternative conceptions, such as that of an internal force. Especially the learners’ understanding of contact forces and Newton’s first law of motion yielded significant improvement. The qualitative data revealed that the understanding of Newton’s second law of motion by the learners who partook in this study did improve, since the learners immediately recognised the mistakes made when confronted with the anchor concept. The cognitive conflict teaching strategy was effective in establishing the anchor concept of force which proved to be useful as bridging concept in the development of ideas teaching strategy. The data from both datasets revealed that the cognitive conflict teaching strategy for the initial part of the intervention was effective. It was evident that for development of the idea teaching strategy the two data sets revealed mixed results. Recommendations were made for future research and implementation of conceptual development teaching strategies. / MEd (Natural Sciences Education), North-West University, Potchefstroom Campus, 2014

Newton’s second law of motion

Teaching strategy

Conceptual development

Conceptual understanding

Learning

Cognitive learning theory

Information processing model

Cognitive resources

Newton’s laws of motion

Sequential Explanatory design

Force Concept Inventory (FCI)

Newton se tweede bewegings wet

Onderrig strategie

Konseptuele ontwikkeling

Konseptuele verstaan

Leer

Kognitiewe leer teorie

Inligtings prosseserings model

Kognitiewe hulpbronne

Newton se bewegings wet

Sekwensieële verduidelikings ontwerp

Krag Konsep Register

The effectiveness of applying conceptual development teaching strategies to Newton's second law of motion / Carel Hendrik Meyer

Meyer, Carel Hendrik

January 2014

School science education prepares learners to study science at a higher level, prepares them to follow a career in science and to become scientific literate citizens. It is the responsibility of the educator to ensure the learners’ conceptual framework is developed to the extent that secures success at higher level studies. The purpose of this study was to test the effectiveness of conceptual change teaching strategies on the conceptual development of grade 11 learners on Newton’s second law of motion. The two strategies employed were the cognitive conflict strategy and the development of ideas strategy. A sequential explanatory mixed-method research design was used during this study. The qualitative data were used to elucidate the quantitative findings. The quantitative research consisted of a quasi-experimental design consisting of a single-group pre-test–post-test method. During the qualitative part of the research a phenomenological research approach was utilised to gain a better understanding of participants’ learning experiences during the intervention. The quantitative research made use of an adapted version of the Force Concept Inventory (FCI). The data collected from the pre-test were used to inform the intervention. The intervention was videotaped and the video analysis or qualitative data analysis was done. After the intervention the post-test was written by the learners. Hake’s average normalised learning gain <g> from pre- to post-scores was analysed to establish the effectiveness of the intervention. The two sets of results (quantitative and qualitative) were integrated. Information from the qualitative data analysis was used to support and explain the quantitative data. The quantitative results indicate that there was an improvement in the students’ force conception from their initial alternative conceptions, such as that of an internal force. Especially the learners’ understanding of contact forces and Newton’s first law of motion yielded significant improvement. The qualitative data revealed that the understanding of Newton’s second law of motion by the learners who partook in this study did improve, since the learners immediately recognised the mistakes made when confronted with the anchor concept. The cognitive conflict teaching strategy was effective in establishing the anchor concept of force which proved to be useful as bridging concept in the development of ideas teaching strategy. The data from both datasets revealed that the cognitive conflict teaching strategy for the initial part of the intervention was effective. It was evident that for development of the idea teaching strategy the two data sets revealed mixed results. Recommendations were made for future research and implementation of conceptual development teaching strategies. / MEd (Natural Sciences Education), North-West University, Potchefstroom Campus, 2014

Newton’s second law of motion

Teaching strategy

Conceptual development

Conceptual understanding

Learning

Cognitive learning theory

Information processing model

Cognitive resources

Newton’s laws of motion

Sequential Explanatory design

Force Concept Inventory (FCI)

Newton se tweede bewegings wet

Onderrig strategie

Konseptuele ontwikkeling

Konseptuele verstaan

Leer

Kognitiewe leer teorie

Inligtings prosseserings model

Kognitiewe hulpbronne

Newton se bewegings wet

Sekwensieële verduidelikings ontwerp

Krag Konsep Register

Use of Multiple Representations to Explore Students’ Understandings of Covalent and Ionic Bonding as Measured by the Bonding Representations Inventory

Luxford, Cynthia Joan

19 April 2013

No description available.

Chemistry

Education

Educational Tests and Measurements

Educational Theory

Higher Education

Inorganic Chemistry

Molecules

Science Education

Secondary Education

Teaching

Covalent

Ionic

Bonding

Representations

Models

Lewis Structures

Ball-and-Stick

Spacefilling

3D Manipulatives

Formulas

Misconceptions

Student Understanding

Concept Inventory

Assessment

Inorganic Symmetry

Group Theory

Guided Inquiry

POGIL