This study focused on two areas under the overarching theme of the effects of
domain-general and domain-specific scaffolds with different levels of support,
continuous or faded. First, the study investigated the effects of scaffolds on learning of
scientific content and problem-solving outcomes. Second, the study examined whether
students’ prior knowledge and meta cognitive skills predict their success in problem
solving across different scaffolding conditions.
A total of nineteen classes were randomly assigned to one of the four scaffolding
conditions: domain-general continuous (DG-C), domain-general faded (DG-F), domain specific
continuous (DS-C), and domain-specific faded (DS-F). Each class had access to
different worksheets depending on the scaffolding condition they had been assigned. All
students engaged in four problem-solving activities for thirteen class periods. Students’
scores on a multiple-choice pretest, post test, inventory of meta cognitive self-regulation,
and four recommendation forms were analyzed. Results of the study revealed that students’ content knowledge in all conditions
significantly increased over the thirteen class periods. However, the continuous domain specific
condition outperformed the other conditions on the post test. Although domain general
scaffolds were not as effective as domain-specific scaffolds on learning of
scientific content and problem representation, they helped students develop solutions,
make strong justifications, and monitor their learning. Unlike domain-specific scaffolds,
domain-general scaffolds helped students transfer problem-solving skills even when they
were faded. In terms of individual differences, results indicated that while students with
lower prior knowledge and lower meta cognitive skills benefited from the domain general
continuous condition, students with lower regulation of cognition benefited from
the domain-general faded condition. Moreover, while students with lower prior
knowledge, lower knowledge of cognition, and lower problem representation benefited
from the domain-specific continuous condition, students with lower problem
representation benefited from the domain-specific faded condition. In contrast, results of
the study suggested that scaffolds did not substantially benefit the students with higher
prior knowledge and higher meta cognitive skills. Several suggestions are discussed for
making further improvements in the design of scaffolds in order to facilitate ill-structured
problem solving in hypermedia learning environments.
Identifer | oai:union.ndltd.org:tamu.edu/oai:repository.tamu.edu:1969.1/ETD-TAMU-2739 |
Date | 2008 May 1900 |
Creators | Bulu, Saniye Tugba |
Contributors | Pedersen, Susan J. |
Source Sets | Texas A and M University |
Language | en_US |
Detected Language | English |
Type | thesis, text |
Format | electronic, application/pdf, born digital |
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