Relationship between Science Teaching Practices and Students’ Achievement in Singapore,Chinese Taipei,and the US: An Analysis Using TIMSS 2011 Data

The assumption that inquiry-based instruction is more effective in influencing student science achievement than traditional didactic teaching has been the driving force of science education reform in recent decades and in many countries. However, the empirical relationship between these two kinds of science teaching and student science performance is not soundly established, which is worth a careful examination. Framed through the theoretical perspectives of inquiry-based instruction and culturally relevant pedagogy, using a two-level hierarchical linear modeling (HLM) approach and simultaneous multiple regression, this study examines the above relationship using the Trends in International Mathematics and Science Study (TIMSS) 2011 8th grade dataset from Singapore, Chinese Taipei, and the US. The study found that for the low-performing students, none of the inquiry-based teaching practice items measured had a significant relationship with the science achievements at any performance levels of students in any country/region except for the case of two inquiry-based teaching practice items that were positively related to Chinese Taipei students’ achievements. No didactic teaching practice items were associated with the Singapore students’ science achievement, three of these practice items were found negatively related to Chinese Taipei students’ science achievement, and one traditional didactic teaching practice was negatively related to the science achievement of U.S. students. However, for medium- and high-performing students, none of these inquiry-based or traditional didactic science-teaching practices were found to be positive predictors of science performance in all three countries/regions. However, in the case of Chinese Taipei, one didactic teaching practice item was negatively related with the medium level performing students’ achievement and two didactic teaching practices were found to hinder high-performing students’ science achievements.     

Identifying didactic knowledge: An empirical study of the educationally critical aspects of learning about information systems

This paper backgrounds and illustrates an approach to researching didactic knowledge. Underlying the approach are some of the frameworks developed from the student learning research. Based on these frameworks the experience of learning about a particular phenomenon is theorised as having educationally critical aspects. Without addressing these aspects in learning experiences, students are highly unlikely to achieve the target understanding desired by the teacher. The approach developed to research educationally critical aspects compares scholarly and student experiences of learning about a phenomenon using the analytical framework of a structure of awareness. An application of the approach is reported in the form of a phenomenographic study which researched didactic knowledge about the concept of an information system (IS). Multiple, previously unreported, educationally critical aspects of learning about the concept of an IS were identified. Some implications of this finding for the design of IS undergraduate curricula, textbooks, teaching strategies and learning tasks are proposed. Finally, the research approach is promoted as a means to investigate didactic knowledge about other phenomena.     

Studying--the Realistic Bridge Between Instruction and Learning. An Attempt to a Conceptual Whole of the Teaching-Studying- Learning Process

Examining learning is a wide and open topic. If we pay attention to learning as achieving some aims and goals defined before, we need a broader and more precise context, an instructional process. This consists of interaction between a teacher and the students. It is based on particular relationships between the teacher, the student and the content that is studied in the instructional process. The human relationship between the teacher and the students is a pedagogical relation and it is regulated by the pedagogical context. Fundamental to learning is, however, how the student meets the content to be learnt, the didactic relation. This relation is invisible by nature. To organise this relation belongs to the expertise of the teacher. The student learning is supposed to take place in the didactic relation of the instructional process.     

Development of a student perception inventory

Students learn new or difficult information most effectively when the classroom environment is compatible with their learning style preferences. Determining learning style preferences can be accomplished by administering the Learning Style Inventory (LSI). However, to understand compatibility with the classroom, an instrument that quantifies student perceptions of elements within the environment is essential. This paper describes development and field‐testing of such an instrument‐the Student Perception Inventory (SPI). The SPI was administered to 80 gifted middle school students and was found to provide useful student perception data. Information needed to improve learning environments for gifted learners, especially underachieving gifted students, was found when using the LSI in conjunction with the SPI.     

The Cosmic Ray Observatory Project: Results of a Summer High-School Student, Teacher, University Scientist Partnership Using a Capstone Research Experience

This paper reports results from evaluation of the Cosmic Ray Observatory Project (CROP), a student, teacher, scientist partnership to engage high-school students and teachers in school based cosmic ray research. Specifically, this study examined whether an intensive summer workshop experience could effectively prepare teacher—student teams to engage in cutting edge high-energy physics research. Results showed that teachers and students could acquire enough knowledge about cosmic ray physics and self-efficacy for conducting cosmic ray research during a summer workshop to be full participants in an SSP conducting research in their schools, and a capstone anchoring approach using an authentic research activity was effective for motivating student engagement in didactic classroom learning. CROP demonstrated “proof of concept” that setting up cosmic ray detector arrays in schools run by teachers and students was feasible, but found that set-up and operation in a high-school was technically difficult.     

A blended learning approach to teach fluid mechanics in engineering

This paper presents a case study on the teaching and learning of fluid mechanics at the University of Western Sydney (UWS), Australia, by applying a blended learning approach (BLA). In the adopted BLA, various flexible learning materials have been made available to the students such as online recorded lectures, online recorded tutorials, hand written tutorial solutions, discussion board and online practice quizzes. The lecture and tutorial class times have been primarily utilised to discuss confusing topics and engage students with practical issues in applying the theories learnt in fluid mechanics. Based on the data of over 734 students over a 4-year period, it has been shown that a BLA has improved the learning experience of the fluid mechanics students in UWS. The overall percentage of student satisfaction in this subject has increased by 18% in the BLA case compared with the traditional one.     

Student Experiences of Carrying out a Practical Science Investigation Under Direction

This paper reports on the reality of classroom‐based inquiry learning in science, from the perspectives of high school students and their teachers, under a national curriculum attempting to encourage authentic scientific inquiry (as practiced by scientists). A multiple case study approach was taken, utilising qualitative research methods of unobtrusive observation, semi‐structured interviews and document analysis. The findings showed purposeful and focused learning occurring, but students were acquiring a narrow view of scientific inquiry where the thinking was characteristically rote and low‐level. The nature of this learning was strongly influenced by curriculum decisions made by classroom teachers and science departments in response to the assessment requirements of a high stakes national qualification. As a consequence of these decisions, students experienced structured teaching programmes in which they were exposed to programme content that limited the range of methods that scientists use to fair testing and to pedagogies that were substantially didactic in nature. In addition, the use of planning templates and exemplar assessment schedules tended to reduce student learning about experimental design to an exercise in “following the rules” as they engaged in closed rather than open investigations. Thus, the resulting student learning was mechanistic and superficial rather than creative and critical, counter to the aims of the national curriculum policy that is intent on promoting students’ knowledge and capabilities in authentic scientific inquiry.     

Meeting the needs of teachers and students within the CESAR training system

Computers seem to be an unquestionably useful tool to support the learning process, although positive students' and teachers' attitude towards the system is required to guarantee a successful introduction of new technologies in traditional classrooms. Training or exercises provide the students with the challenge of using their knowledge to solve concrete problems, so that they incite students to participate actively. Training can be adapted to different learning styles in order to strengthen student involvement. Moreover, tools to adapt the didactic material to several educational methods must be provided, in such a way that teachers consider the system a helpful tool rather than a substitute. Taking into account the foregoing, this paper describes a training system to create and use exercises in a hypermedia learning environment for hearing-impaired children called CESAR.     

Use and evaluation of a technology-rich experimental collaborative classroom

In order to pilot a shift towards greater use of collaborative learning in our higher education programs, the University of Hong Kong has invested in the development of a prototype technology-enhanced collaborative learning space. The space was created by retrofitting a vacant studio, turning it into an innovative classroom space in which collaborative learning is promoted and facilitated both through the provision of technology and by the physical layout of the room. We have used the space to pioneer collaborative learning both by holding professional development workshops for faculty in the room and also by helping academic staff to run experimental courses in the learning space. The opportunity to offer professional development and support for academic staff in this environment is particularly valuable as it ensures they do not simply deliver traditional didactic lectures in a space designed to promote interactive student learning and engagement. By using the space as a ‘student’ they are able to consider how they may use collaborative learning environments with their students. This paper describes use of the room for professional development of academic staff and also provides two examples of the use and evaluation of the room by faculty who used the room to teach experimental classes.     

Students’ perceptions of Plickers and crossword puzzles in undergraduate studies

In higher education, there are calls to incorporate active learning experiences that place the student at the center of learning, rather than encouraging students to be passive listeners. For students to have a deeper and more meaningful learning experience, educators can use an active learning approach. This approach attempts to engage students at higher levels of thinking so that they are more interested in, better engaged with, and understand the course material better. The aim of this study was to investigate students’ perceptions of Plickers and crossword puzzles as low‐cost pedagogical tools to foster active learning in an undergraduate course in food science and technology. A mixed‐method survey consisting of a 5‐point Likert scale and open‐ended qualitative questions was administered via Blackboard to elicit student responses. A total of 121 students were enrolled for the course and 70.2% (n = 85) completed the survey. Plickers were found to be easy to use (mean = 4.66), provided opportunities to answer to formative questions anonymously (mean = 4.60), and helped increase participation in class (mean 4.05). The majority of students felt that crossword puzzles required them to think critically (mean = 4.53) and provided them with the opportunity to assess how well they understood the course content (mean = 4.45). Moreover, a statistically positive relationship was found between student collaborative learning and crossword puzzle implementation scores (r = .506, p < .01). The findings demonstrated that when implemented effectively, Plickers and crossword puzzles contributed to greater enhanced student engagement. These pedagogical tools can be applied as formative assessment instruments and offer a low‐cost alternative to the limitations encapsulated by didactic pedagogy.     

Parental involvement in schooling, classroom environment and student outcomes

We investigated relationships between students’ perceptions of parental involvement in schooling, their Spanish classroom environment and student outcomes (attitudes and achievement). Modified Spanish versions of the What Is Happening In this Class?, Test of Spanish-Related Attitudes-L₁, a parental involvement questionnaire and a Spanish achievement test were administered to 223 Hispanic Grade 4–6 students in South Florida. The factor structure and internal consistency reliability of the questionnaires was supported. Strong associations were found for parental involvement with students’ learning environment perceptions and student outcomes, and for Spanish classroom environment with student outcomes. When the unique and common variances in student outcomes explained by the classroom environment and the home environment were examined, the home environment was more influential than the classroom environment in terms of students’ attitudes, but the classroom environment was more influential than the home environment in terms of achievement.     

About cooperative engineering: theory and emblematic examples

In this article we focus on ‘cooperative engineering’, in which teachers and researchers co-design didactic sequences. In the first part of the article, we present cooperative engineering by describing some of the main principles on which it is grounded. The second part is dedicated to a case study, which enables us to illustrate some elements of the collective work in a specific cooperative design in kindergarten. The designed learning game, the ‘Treasure Game’, aimed to assist kindergarten students to build a system of graphical representations, which was implemented in a series of phases in which students were asked to memorise a series of items with increasing levels of difficulty. The game demonstrated the students’ growing competence in recalling items using strategies such as making lists and working collaboratively to collectively recall items through a ‘treasure box’. In the third part of the article, we show how this case study embodies some of the main principles put forward in the first part.     

Impact of multimedia on students’ perceptions of the learning environment in mathematics classrooms

We investigated (1) whether the learning environment perceptions of students in classes frequently exposed to multimedia differed from those of students in classes that were not, (2) whether exposure to multimedia was differentially effective for males and females and (3) relationships between students’ perceptions of the learning environment and student engagement in classes that were exposed to multimedia. The sample involved 365 high-school students in 16 classes, nine that were frequently exposed to multimedia and seven that were not. Two instruments were administered to students: one to assess students’ perceptions of the learning environment and another to assess student engagement. There were statistically significant differences between the two groups for all of the learning environment scales, as well as statistically significant interactions between exposure to multimedia and sex for three learning environment scales (Involvement, Task Orientation and Equity). Finally, the learning environment in mathematics classes that involved multimedia was related to student engagement. These results offer potentially important insights into how student exposure to multimedia could promote more positive learning environments and improve student engagement in mathematics.     

Communicative-based curriculum innovations between theory and practice: implications for EFL curriculum development and student cognitive and affective change

This qualitative study examines the influence of teacher conceptualisations of communicative language teaching on their actual classroom practice and student cognitive and affective change. The qualitative paradigm underpinned this research at the levels of ontology (multiple teacher realities), epistemology (interaction with, rather than detachment from, the respondents), and methodology through using an idiographic strategy (qualitative case study), instruments (qualitative interviews, participant observation and questionnaires), and data analysis technique (explanation-building). The results indicated that teachers who understood CLT and managed to materialise its principles into action significantly improved student language learning (cognitive change) and motivation (affective change). Moreover, traditional, structural and didactic teaching as well as communicative knowledge that was not translated into practice had almost a typical negative impact on student learning and motivation. Recommendations for curriculum development, teacher development, teacher training and future research are made.     

ICT in the classroom: Primary education student teachers’ perceptions of the interactive whiteboard during the teaching practicum

A literature review on perceptions of the interactive whiteboard during the teaching practicum shows that there has been insufficient analysis of student teachers’ perceptions of Information and Communication Technology (ICT). However, these perceptions are highly useful to create a full picture of the effectiveness – and indeed the drawbacks – of using ICT in the classroom. In this study, we examine and analyse evidence from teaching practica to assess the success of ICT – specifically the interactive whiteboard – as a teaching tool, using a qualitative method. The accounts are first-hand, scientific reflections made by student teachers from La Serena, Chile, during their teaching practicum in primary schools; for this reason they are extremely useful in analysing this teaching tool’s effectiveness in the classroom. Among the main results for students’ perceptions of incorporating technology as part of their training, we found a set of variables for good practice when using the interactive whiteboard, including: incorporating technology as an engaging didactic resource; making the most of technology for improving learning; determining when best to use the whiteboard; and identifying any limiting factors together with students’ suggestions for improvement.     

Factors influencing student perceptions of high-school science laboratory environments

Science laboratory learning has been lauded for decades for its role in fostering positive student attitudes about science and developing students’ interest in science and ability to use equipment. An expanding body of research has demonstrated the significant influence of laboratory environment on student learning. Further research has demonstrated differences in student perceptions based on giftedness. To explore the relationship between giftedness and students’ perceptions of their learning environment, we examined students’ perceptions of their laboratory learning environment in biology courses, including courses designated for high-achieving versus regular-achieving students. In addition, to explore the relationship between students’ perceptions and the extent of their experience with laboratory learning in a particular discipline, we examined students’ perceptions of their laboratory learning environment in first-year biology courses versus elective biology courses that require first-year biology as a prerequisite. We found that students in high-achieving courses had a more favourable perception of all aspects of their learning environment when compared with students in regular courses. In addition, student perceptions of their laboratory appeared to be influenced by the extent of their experience in learning science. Perceptions were consistent amongst regular- and high-achieving students regardless of grade level. In addition, perceptions of students in first year and beyond were consistent regardless of grade level. These findings have critical applications in curriculum development as well as in the classroom. Teachers can use student perceptions of their learning environment to emphasize critical pedagogical approaches and modify other areas that enable enhancement of the science laboratory learning environment.     

Course design,teaching method and student epistemology

Previous research into student learning in departments of higher education has shown that links can be established between students' approaches to studying and their perceptions of the academic environment. It has also been found that students with differing study orientations are likely to define effective teaching in ways which reflect those orientations. The study reported here began by identifying different types of student epistemology and then investigated those factors within the academic environment which appeared to influence their incidence. Employing a naturalistic methodology-observations, interviews and case studies - the study was conducted in four departments in one institution of higher education: two arts and two science. Through a process of progressively focusing upon emergent issues, the study evolved through three stages, culminating in a model of the factors appearing to influence the development of student epistemology. It is found that the development of student epistemology is influenced by the interrelated factors of student learning approach, perception of the academic environment and lecturers' theories of teaching, which tends to uphold previous findings. It is also found, however, that students' conceptions of knowledge and their learning approaches are influenced by the ways in which knowledge is structured and presented within departments. Most particularly, a relationship was found between historical and philosophical studies, the methods of teaching them, and the development of student epistemologies.     

The classroom learning environment as perceived by students in Arab elementary schools

In this study, students’ perceptions of the classroom learning environment in Arab elementary schools were investigated. The sample included 261 students from Grades 5 and 6. The questionnaire was developed at an Arab college of teacher education by 16 fourth-year student teachers who were completing their studies toward a BEd degree. Articles on classroom learning environment were distributed to the students, who then wrote items to assess learning environment. The items were evaluated for content validity in relation to the Arab school culture, language, teachers’ teaching, students’ learning styles, teacher–student relations, order and organisation, discipline and behaviours. The Classroom Learning Environment of Elementary Students (CLEES) questionnaire consists of 32 items in four scales: Teacher’s Image, Group Work, Students’ Participation, and Order and Organisation. The CLEES was used in a pilot study in two Grade 5 and 6 classes in order to validate it. The student teachers administered the questionnaire to students in elementary schools. Data were analysed using SPSS (e.g. factor analysis and one-way ANOVA) to validate the CLEES. No significant differences were found between boys and girls in classroom learning environment. However, significant differences in CLEES perceptions were found between students from different grades (Grade 5 vs. Grade 6), age groups and schools. The results are explained in the discussion section in relation to the characteristics of their schools.