Using computer simulations to enhance conceptual change: The roles of constructivist instruction and student epistemological beliefs

Learners enter the classroom with informal ideas (alternative conceptions) about scientific phenomena; these ideas affect how the corresponding scientific explanations are learned. In addition, studentsÕ epistemological beliefs concerning learning influence achievement. This study investigated the effects of a constructivist versus objectivist learning environment on college studentsÕ conceptual change, using a computer simulation of the human cardiovascular system as an instructional tool. This study also investigated the interaction between constructivist versus objectivist learning situations and the studentsÕ epistemological beliefs. The constructivist approach resulted in significantly greater conceptual change than the objectivist approach for 2 of 6 commonly held alternative conceptions; the other 4 of 6 areas showed no significant differences for treatment group. More important, however, the treatment interacted significantly with epistemological beliefs. Individuals with more advanced epistemological beliefs learned more with a constructivist treatment; individuals with less developmentally advanced beliefs learned more with an objectivist treatment. © 1998 John Wiley & Sons, Inc. J Res Sci Teach 35: 145–160, 1998.     

Effect of cooperative learning strategies on student verbal interactions and achievement during conceptual change instruction in 10th grade general science

This study evaluated the effects of cooperative learning on students' verbal interaction patterns and achievement in a conceptual change instructional model in secondary science. Current conceptual change instructional models recognize the importance of student–student verbal interactions, but lack specific strategies to encourage these interactions. Cooperative learning may provide the necessary strategies. Two sections of low-ability 10th-grade students were designated the experimental and control groups. Students in both sections received identical content instruction on the particle model of matter using conceptual change teaching strategies. Students worked in teacher-assigned small groups on in-class assignments. The experimental section used cooperative learning strategies involving instruction in collaborative skills and group evaluation of assignments. The control section received no collaborative skills training and students were evaluated individually on group work. Gains on achievement were assessed using pre- and posttreatment administrations of an investigator-designed short-answer essay test. The assessment strategies used in this study represent an attempt to measure conceptual change. Achievement was related to students' ability to correctly use appropriate scientific explanations of events and phenomena and to discard use of naive conceptions. Verbal interaction patterns of students working in groups were recorded on videotape and analyzed using an investigator-designed verbal interaction scheme. The targeted verbalizations used in the interaction scheme were derived from the social learning theories of Piaget and Vygotsky. It was found that students using cooperative learning strategies showed greater achievement gains as defined above and made greater use of specific verbal patterns believed to be related to increased learning. The results of the study demonstrated that cooperative learning strategies enhance conceptual change instruction. More research is needed to identify the specific variables mediating the effects of cooperative learning strategies on conceptual change learning. The methods employed in this study may provide some of the tools for this research.     

Effect of instruction using microcomputer simulations and conceptual change strategies on science learning

This article describes an investigation into the effects of instruction using microcomputer simulations and conceptual change strategies. The microcomputer program was designed in accord with a model of conceptual change to diagnose and remediate an alternative conception of velocity. Results show that, first, the microcomputer simulations are credible representations of reality, and second, that the remedial part of the program produced significant conceptual change in students holding the alternative conception.     

Effect of instruction using students' prior knowledge and conceptual change strategies on science learning

One of the factors affecting students' learning in science is their existing knowledge prior to instruction. The students' prior knowledge provides an indication of the alternative conceptions as well as the scientific conceptions possessed by the students. This study is concerned primarily with students' alternative conceptions and with instructional strategies to effect the learning of scientific conceptions; i.e., to effect conceptual change from alternative to scientific conceptions. The conceptual change model used here suggests conditions under which alternative conceptions can be replaced by or differentiated into scientific conceptions and new conceptions can be integrated with existing conceptions. The instructional strategy and materials were developed for a particular student population, namely, black high school students in South Africa, using their previously identified prior knowledge (conceptions and alternative conceptions) and incorporate the principles for conceptual change. The conceptions involved were mass, volume, and density. An experimental group of students was taught these concepts using the special instructional strategy and materials. A control group was taught the same concepts using a traditional strategy and materials. Pre- and posttests were used to assess the conceptual change that occurred in the experimental and control groups. The results showed a significantly larger improvement in the acquisition of scientific conceptions as a result of the instructional strategy and materials which explicitly dealt with student alternative conceptions.     

Teaching strategies associated with conceptual change learning in Science

The use of teaching strategies associated with a conceptual change model of science teaching was examined in a study of thirteen 7th-grade life science teachers. Teachers taught units on photosynthesis, cellular respiration, and matter cycling in ecosystems in their regular classes under conditions varying as to whether or not conceptual change-oriented instructional materials and training sessions were provided. Greater use of conceptual change teaching strategies was associated with use of the special instructional materials, but not with the training. Students in classes where teachers were provided with the materials tended to perform better on posttests than those where such materials were not provided. The use of the conceptual change strategies by teachers was also associated with higher student performance on tests designed to assess conceptual change learning. The results support claims for the usefulness of conceptual change teaching strategies, but few of the teachers in this study could successfully implement these strategies without the support of appropriately designed curriculum materials.     

The role of conceptual conflict in conceptual change and the design of science instruction

Conceptual conflict has long been recognized as a factor that could facilitate student learning. Due, however, to the lack of a convincing explanation of why it occurs, and how it can be resolved, it has seldom been used in instructional design. Its potential use in instruction is particularly relevant in the light of the recent, well-documented finding that students' existing conceptions frequently constitute a barrier to effective learning. This article examines conceptual conflict in the light of an epistemological model of learning as conceptual change. This analysis shows that the conceptual change model provides an explanation of conceptual conflict which is sufficiently detailed to allow it to be used in the design of instruction. The results of two studies, the first of which addressed the concepts of mass, volume, and density, and the second, the concept of speed, show that instruction, designed in this way, is effective in changing students' existing conceptions.     

Using examples and analogies to remediate misconceptions in physics: Factors influencing conceptual change

Examples are often recognized as important in teaching conceptual material, yet little research has been done concerning the best use of examples in attempts to remediate misconceptions. This study questions the effectiveness of a traditional teaching-by-example technique. Results indicate that when students hold a misconception, presenting a principle with supporting examples to show the range of application of the principle may be ineffective. Rather, it appears that examples are more effective when they help students draw on and analogically extend existing valid physical intuitions in constructing a new conceptual model of a target situation. To help students in this constructive effort, first, the examples used must be understandable and believable to the students, not simply to the teacher or textbook author. Second, even when an example is compelling to the student, it may not be seen as analogous to target problems drawing out a misconception. In that case, analogy relations may need to be explicitly developed. Third, qualitative, visualizable models may need to be developed which give mechanistic explanations for phenomena.     

The process of conceptual change in force and motion during computer‐supported physics instruction

The process of students' conceptual change was investigated during a computer‐supported physics unit in a Grade 10 science class. Computer simulation programs were developed to confront students' alternative conceptions in mechanics. A conceptual test was administered as a pre‐, post‐, and delayed posttest to determine students' conceptual change. Students worked collaboratively in pairs on the programs carrying out predict–observe–explain tasks according to worksheets. While the pairs worked on the tasks, their conversational interactions were recorded. A range of other data was collected at various junctures during instruction. At each juncture, the data for each of 12 students were analyzed to provide a conceptual snapshot at that juncture. All the conceptual snapshots together provided a delineation of the students' conceptual development. It was found that many students vacillated between alternative and scientific conceptions from one context to another during instruction, i.e., their conceptual change was context dependent and unstable. The few students who achieved context independent and stable conceptual change appeared to be able to perceive the commonalities and accept the generality of scientific conceptions across contexts. These findings led to a pattern of conceptual change which has implications for instructional practices. The article concludes with consequent implications for classsrooms. © 1999 John Wiley & Sons, Inc. J Res Sci Teach 36: 859–882, 1999     

Self‐assessment methods in writing instruction: a conceptual framework,successful practices and essential strategies

Student writing achievement is essential to lifelong learner success, but supporting writing can be challenging for teachers. Several large‐scale analyses of publications on writing have called for further study of instructional methods, as the current literature does not sufficiently address the need to support best teaching practices. Self‐assessment methods in writing instruction present meaningful ways to promote student writing achievement through reflection and meta‐cognition during the writing process. Self‐assessment practices are described in publications across the academic disciplines where writing is required, and close investigations of the methods are also published in the research fields of literacy, English education and composition. This study aims to bridge these fields to construct a clear and comprehensive understanding of self‐assessment methods. Self‐assessment encompasses a wide range of practices and varied terminology. It is essential to clarify effective methods of self‐assessment and to disseminate practical information to educators. This paper presents the findings of an analysis of the literature yielding: (1) a theoretical framework for self‐assessment methods in writing instruction; (2) an overview of concepts/practices; (3) a list of literature‐supported strategies for effective classroom use derived from a study of a vast body of literature. Results strongly support self‐assessment as a means to foster student writing achievement, middle school through higher education. Delineated strategies can assist instructors with self‐assessment implementation.     

Using educational games and simulation software in a computer science course: learning achievements and student flow experiences

This study investigates how educational games impact on students' academic performance and multimedia flow experiences in a computer science course. A curriculum consists of five basic learning units, that is, the stack, queue, sort, tree traversal, and binary search tree, was conducted for 110 university students during one semester. Two groups of students participated in learning activities: the experimental group was instructed using the gaming method; and the control group was instructed using the non-gaming method. During the study, tests, a survey, and interviews were conducted with students. The evaluation results for academic performance and multimedia flow experiences show that compared to the non-gaming method, incorporating the gaming method into the learning process can enhance students' academic performance and multimedia flow experiences. The results also indicated that there is a non-significant and positive relationship between students' academic performance and multimedia flow experiences.     

Learning environment, attitudes and conceptual development associated with innovative strategies in middle-school mathematics

This study of middle-school students in California focused on the effectiveness of using innovative teaching strategies for enhancing the classroom environment, students’ attitudes and conceptual development. A sample of 661 students from 22 classrooms in four inner city schools completed modified forms of the Constructivist Learning Environment Survey (CLES), What Is Happening In this Class? (WIHIC) questionnaire and Test of Mathematics Related Attitudes (TOMRA). Data analyses supported the factor structure, internal consistency reliability, discriminant validity and the ability to distinguish between different classes for these questionnaires when used with middle-school mathematics students in California. The effectiveness of the innovative instructional strategy was evaluated in terms of classroom environment and attitudes to mathematics for the whole sample, as well as for mathematics achievement for a subgroup of 101 students. A comparison of an experimental group which experienced the innovative strategy with a control group supported the efficacy of the innovative teaching methods in terms of learning environment, attitudes and mathematics concept development. Also associations were found between perceptions of classroom learning environment and students’ attitudes to mathematics and conceptual development.     

Teacher change in beliefs and practices in science and literacy instruction with English language learners

This study examined patterns of change in beliefs and practices as elementary teachers learned to establish instructional congruence, a process of mediating academic disciplines with linguistic and cultural experiences of diverse student groups. The study focused on six bilingual Hispanic teachers working with fourth‐grade, mostly Hispanic students. The results indicated that teacher learning and change occurred in different ways in the areas of science instruction, students' language and culture, English language and literacy instruction, and integration of these areas in establishing instructional congruence. The results also indicated that establishing instructional congruence was a gradual and demanding process requiring teacher reflection and insight, formal training, and extensive support and sharing. Implications for further research in promoting achievement for all students are discussed. © 2003 Wiley Periodicals, Inc. J Res Sci Teach 41: 65–93, 2004     

Teaching with technology in higher education: understanding conceptual change and development in practice

Research indicates that teachers’ conceptions of and approaches to teaching with technology are central for the successful imple-mentation of educational technologies in higher education. This study advances this premise. We present a 10-year longitudinal study examining teachers’ conceptions of and approaches to teaching and learning with technology. Nine teachers on an online Bachelor of Science in Pharmacy and a Master of Pharmacy programme at a Swedish university were studied using a phenomenographic approach. Results showed clear differences between novice and experienced teachers. Although novice teachers initially held more teacher-focused conceptions, they demonstrated greater and more rapid change than experienced colleagues. Experienced teachers tended to exhibit little to no change in conceptions. Supporting conceptual change should, therefore, be a central component of professional development activities if a more effective use of educational technology is to be achieved.     

Supporting emotion regulation in individuals with ASD,ADHD and bipolar disorder through trauma-informed instruction and self-regulation strategies

Since the beginning of the COVID-19 pandemic, students have endured drastic changes in educational routines. Such disruptions can be especially challenging for students who struggle with executive functioning, self-regulation and emotion regulation, such as students with autism spectrum disorder (ASD), attention deficit hyperactivity disorder (ADHD) and bipolar disorder. Using a framework of trauma-informed instruction, the authors supported classroom teachers in implementing sensory spaces for students with ASD, ADHD and bipolar disorder. The project included professional development and funding for teachers to develop, procure and offer sensory tools and strategies to assist students in recognising and managing emotions. The authors collected data on the effectiveness of the sensory supports, combining teacher surveys and student behaviour data. Results indicated increased teacher knowledge on trauma-informed instruction and use of sensory supports to promote executive functioning and self-regulation and decreased target behaviours in students based on structured observation and anecdotal teacher feedback.     

Behavior change in a student with a dual diagnosis of deafness and pervasive developmental disorder: a case study

The broad term pervasive developmental disorder (PPD) describes a set of symptoms that occur along a continuum of severity; these symptoms are often referred to as autism spectrum disorders (ASDs). Little is known about the incidence and prevalence of ASDs among students who are deaf or hard of hearing (DHH). Teachers of DHH students, who must work with individuals with dual diagnoses, are at a loss for guidance from the literature. The authors review the literature on ASDs (also referred to as PDD) within the DHH population, provide results of a single-subject study to reduce PDD-type behaviors in a child with hearing loss, and argue that teachers of students who are DHH must learn about practices associated with applied behavior analysis as an tool for intervening therapeutically with children with dual diagnoses of hearing loss plus an ASD.     

A case for adapting and applying continuance theory to education: understanding the role of student feedback in motivating teachers to persist with including digital technologies in learning

In New Zealand schools, the adoption and persistent use of digital tools to aid learning is a growing but uneven, trend, often linked to the practices of early adopters and/or robust wifi infrastructure. The Technology Adoption Model is used internationally to gauge levels of uptake of technological tools, particularly in commerce and also in education. However, this model is inadequate when it is used to attribute reasons for teachers adopting technologies for learning. This article offers an alternative view to understanding why teachers continue using digital technologies for learning. It focuses on the role of student voice and teachers’ pedagogical purposes as motivators, even when teachers have technological hurdles to overcome. The article engages with continuance theory as a lens for understanding these motivations via a qualitative thematic analysis of Moodle postings made by a 2012 cohort of initial teacher education students. The intention is to signpost ideas that might better explain teachers’ continued use of digital technologies in classrooms even if conditions for use are not optimal.