Monkeying Around: Examining the Effects of a Community Zoo on the Science Achievement of Third Graders

Kenny, Heather A.

January 2009

No description available.

Education

literacy

science education

elementary

informal learning environments

zoos

The development and validation of a learning environment instrument for CSIRO Science Education Centres

Harington, Darrel G.

January 2001

Past research into defining and measuring the characteristics of learning environments in Science Education Centres and Science Museums (SECSMs) has been based upon low-inference measures, such as observations and interviews. Many searchers feel that the diversity of informal education settings in SECSMs makes it difficult to develop high-inference measures for informal learning environments. This study used the semiformal environment of the CSIRO Science Education Centres as a stepping-stone between formal and informal learning environments. A review of learning environment research identified a possible procedure for the development of, and a format for, a suitable instrument. Research in SECSMs was reviewed to identify learning environment factors that defined the CSIROSEC learning environment. A pilot study was conducted to determine the feasibility of developing a learning environment instrument for CSIROSECs. This led to the more formal process of developing a learning environment instrument for CSIROSECs based upon the five scales of Affect, Social Interaction, Novelty, Independence and Involvement. / A number of cycles of testing of the instrument, statistical analyses, and subsequent refinements resulted in the Learning Environment Instrument for CSIRO Science Education Centres (LEI for CSIROSECs). The instrument measures distinct, if somewhat overlapping, aspects of the learning environment. The LEI for CSIROSECs displays comparable measures for internal consistency (alpha reliability) and discriminant validity to existing learning environment instruments. The sensitivity of the instrument has been demonstrated for the comparison of different classes, comparison of teacher-student perceptions, comparison of primary and secondary classes, and the comparison of CSIROSEC programs. Suggestions have been made for applications of the LEI for CSIROSECs and its further development,as well as its potential use in research.

Communicating Sustainability through Design within Retail Environments

Hendry, Daniel, Silcox, Lawrence, Yokoyama, Nobuko

January 2007

This thesis uses a systematic understanding of sustainability informed by human needs, learning and design theory to explore ways in which small retail environments can effectively communicate sustainability concepts. The envisioned outcome of successfully communicating and implementing sustainability within retail environments is a lasting change in people’s daily behaviors. The methods of literature review, surveys, human needs investigation and professional validation are used to develop a behavioral change model centered on human needs and learning as well as six communication guidelines. The appendix of this thesis contains a user-friendly pocket guidebook titled The Six Guidelines for Sustainable Retail. The guidebook is designed as a quick-reference tool for retailers, designers and employees. It contains principles, visuals and concepts of sustainability for daily communication and comprehension purposes.

Strategic Sustainable Development

Behavioral Change

Retail Learning

Communication Design

Informal Learning Environments

Human Needs

Social Sciences Interdisciplinary

Coding in the Curriculum: Learning Computational Practices and Concepts, Creative Problem Solving Skills, and Academic Content in Ten to Fourteen-Year-Old Children

Donley, Kevin Scott

January 2018

The fundamentals of computer science are increasingly important to consider as critical educational and occupational competencies, as evidenced by the rapid growth of computing capabilities and the proliferation of the Internet in the 21st century, combined with reimagined national education standards. Despite this technological and social transformation, the general education environment has yet to embrace widespread incorporation of computational concepts within traditional curricular content and instruction. Researchers have posited that exercises in computational thinking can result in gains in other academic areas (Baytak & Land, 2011; Olive, 1991), but their studies aimed at identifying any measurable educational benefits of teaching computational concepts to school age children have often lacked both sufficient experimental control and inclusion of psychometrically sound measures of cognitive abilities and academic achievement (Calao, Moreno-León, Correa, & Robles, 2015). The current study attempted to shed new light on the question of whether using a graphically-based computer coding environment and semi-structured curriculum –the Creative Computing Course in the Scratch programming language –can lead to demonstrable and significant changes in problem solving, creative thinking, and knowledge of computer programming concepts. The study introduced 24 youth in a summer educational program in Philadelphia, PA to the Scratch programming environment through structured lessons and open-ended projects for approximately 25 hours over the course of two weeks. A delayed treatment, control trial design was utilized to measure problem solving ability with a modified version of the Woodcock-Johnson Tests of Cognitive Abilities, Fourth Edition (WJ-IV), Concept Formation subtest, and the Kaufman Tests of Educational Achievement, Third Edition (KTEA-3) Math Concepts and Applications subtest. Creative problem solving was measured using a consensual assessment technique (Amabile, 1982). A pre-test and post-test of programming conceptual knowledge was used to understand how participants’ computational thinking skills influenced their learning. In addition, two questionnaires measuring computer use and the Type-T (Thrill) personality characteristic were given to participants to examine the relationship between risk-taking or differences in children’s usage of computing devices and their problem solving ability and creative thinking skills. There were no differences found among experimental and control groups on problem solving or creative thinking, although a substantial number of factors limited and qualified interpretation of the results. There was also no relationship between performance on a pre-test of computational thinking, and a post-test measuring specific computational thinking skills and curricular content. There were, however, significant, moderate to strong correlations among academic achievement as measured by state standardized test scores, the KTEA-3 Math Concepts and Applications subtest, and both the pre and post Creative Problem Solving test developed for the study. Also, higher levels of the Type T, or thrill-seeking, personality characteristic were associated with lower behavioral reinforcement token computer “chips," but there were no significant relationships among computer use and performance on assessments. The results of the current study supported retention of the null hypothesis, but were limited by small sample size, environmental and motivational issues, and problems with the implementation of the curriculum and selected measures. The results should, therefore, not be taken as conclusive evidence to support the notion that computer programming activities have no impact in other areas of cognitive functioning, mathematic conceptual knowledge, or creative thinking. Instead, the results may help future researchers to further refine their techniques to both deliver effective instruction in the Scratch programming environment, and also target assessments to more accurately measure learning. / Educational Psychology

Educational Technology

Computer Science

Educational Psychology

Computational Thinking

Creative Computing Curriculum

Creative Thinking

Informal Learning Environments

Problem Solving

Scratch Programming Environment

Examining University Students’ Use of Mobile Technology, Online Engagement, and Self-Regulation & Metacognitive Tendencies Across Formal and Informal Learning Environments.

Kashou, Hussam H.

January 2016

No description available.

Education

Educational Leadership

Educational Psychology

Educational Technology

Higher Education

Higher Education Administration

Instructional Design

Information Technology

Education Policy

Mobile Technology

Mobile Devices

Online Outlets

Online Engagement

Student Engagement

Self-Regulation

Self-Regulated Learning

Self-efficacy for SRL

Metacognition

Student Success

Teaching

Learning