Publication Date
| In 2025 | 0 |
| Since 2024 | 0 |
| Since 2021 (last 5 years) | 0 |
| Since 2016 (last 10 years) | 2 |
| Since 2006 (last 20 years) | 3 |
Descriptor
| Models | 3 |
| Protocol Analysis | 3 |
| Chemistry | 2 |
| Problem Solving | 2 |
| Academic Achievement | 1 |
| Biology | 1 |
| Conceptual Tempo | 1 |
| Context Effect | 1 |
| Cues | 1 |
| Difficulty Level | 1 |
| Foreign Countries | 1 |
| More ▼ | |
Source
| International Journal of… | 3 |
Author
| Bennett, Steve | 1 |
| Bernholt, Sascha | 1 |
| Broman, Karolina | 1 |
| Fynewever, Herb | 1 |
| Gotwals, Amelia Wenk | 1 |
| Gulacar, Ozcan | 1 |
| Long, Tammy M. | 1 |
| Parchmann, Ilka | 1 |
Publication Type
| Journal Articles | 3 |
| Reports - Research | 3 |
Education Level
| Higher Education | 2 |
| Postsecondary Education | 1 |
| Secondary Education | 1 |
Audience
Location
| Sweden | 1 |
Laws, Policies, & Programs
Assessments and Surveys
What Works Clearinghouse Rating
Peer reviewed
Direct linkBennett, Steve; Gotwals, Amelia Wenk; Long, Tammy M. – International Journal of Science Education, 2020
In this study, we propose an 'Approach to Modeling' (AtM) framework for examining how undergraduates approach tasks that require modelling scientific phenomena. Our framework is adapted from Approach to Learning (AtL) theories and consists of three observable behavioural constructs: metacognition, generative thinking, and causal reasoning. Twenty…
Descriptors: Undergraduate Students, Biology, Metacognition, Thinking Skills
Broman, Karolina; Bernholt, Sascha; Parchmann, Ilka – International Journal of Science Education, 2018
Context-based learning aims to make learning more meaningful by raising meaningful problems. However, these types of problems often require reflection and thinking processes that are more complex and thus more difficult for students, putting high demands on students' problem-solving capabilities. In this paper, students' approaches when solving…
Descriptors: Models, Scaffolding (Teaching Technique), Problem Solving, Chemistry
Gulacar, Ozcan; Fynewever, Herb – International Journal of Science Education, 2010
We present a quantitative model for predicting the level of difficulty subjects will experience with specific problems. The model explicitly accounts for the number of subproblems a problem can be broken into and the difficultly of each subproblem. Although the model builds on previously published models, it is uniquely suited for blending with…
Descriptors: Stoichiometry, Protocol Analysis, Difficulty Level, Problem Solving
