Susan Buhr Sullivan

Lens on Climate Change: Making Climate Meaningful Through Student-Produced Videos

Learning about climate change is tangible when it addresses impacts that can be observed close to home. In this program, sixty-four diverse middle and high school students produced videos about locally relevant climate change topics. Graduate and undergraduate students provided mentorship. The program engaged students in research and learning about climate change, and sparked their interest in science careers. Evaluation results showed that students were highly motivated by the experience, developed a genuine interest in their science topic, learned about the scientific process, and developed twenty-first century skills. The program provided a unique and authentic approach to science learning and communication.

Undergraduate Climate Education: Motivations, Strategies, Successes, and Support

ABSTRACT Climate literacy is an essential component of a strategy to comprehend and confront the grand challenge of global climate change. However, scientific complexity, societal implications, and political associations make climate change a difficult but important topic to teach. In this paper we report on the results of a survey of undergraduate faculty members on their teaching practices with respect to climate science and the outcomes of a series of undergraduate faculty workshops focused on climate change topics and intended to support faculty members in teaching these topics. Survey results show that undergraduate faculty members place a high priority on teaching climate science because of its relevance to the students with respect to their community, lives, and potential careers. In addition, the survey indicates that climate concepts are taught in a spectrum of undergraduate classes, ranging from geoscience classes to those in the social sciences that address societal impacts and solutions to the problems created by climate change. Results from the survey and workshops indicate there are multiple successful strategies for teaching climate topics, including focusing on solutions, using local contexts, teaching with scientific data, embracing that controversy is an integral part of teaching about climate change, and employing effective communication strategies that can help address controversy and misconceptions. We suggest that undergraduate faculty members need ongoing support in their efforts to effectively teach climate change topics. The Climate Literacy and Energy Awareness Network and On the Cutting Edge projects strive to provide that support through workshops and Web portals that provide access to a variety of educational materials.

Arctic Climate Connections Curriculum: A Model for Bringing Authentic Data Into the Classroom

ABSTRACT Science education can build a bridge between research carried out by scientists and relevant learning opportunities for students. The Broader Impact requirements for scientists by funding agencies facilitate this connection. We propose and test a model curriculum development process in which scientists, curriculum developers, and classroom educators work together to scaffold the use of authentic, unprocessed scientific data for high school students. We outline a three-module curriculum structure that facilitates these goals. This curriculum engages students in the collection, description, visualization, and interpretation of data; develops understanding of the nature of science; includes prompts to develop higher-order thinking skills; builds knowledge of regional relevance of climate change in students; uses active learning techniques; and can be easily integrated with the Next Generation Science Standards. The curriculum was reviewed and tested in the classroom. To shed further light on the curriculum development process, we gathered reflection data from the scientists, curriculum developers, and educators. Scientists appreciated the collaborative process in which they contributed their expertise without requiring a large time commitment or strong expertise in science education. The curriculum developers viewed the modular structure as helpful in breaking complicated scientific concepts into teachable steps. Classroom educators appreciated the detailed description and step-by-step instructions to navigate data analysis tools like Excel or Google Earth. Initial classroom implementation of the curriculum by 11 teachers with over 1,100 students showed high levels of interest in the topic and engagement. Further work is needed to assess efficacy of the curriculum through classroom observations and measures of student learning.

Continuation of the Theme: Outcomes of Climate Literacy Efforts (Part 2)

This issue of the Journal of Geoscience Education includes the second installment of a two-part special theme issue on Outcomes of Climate Literacy Efforts. In the editorial that introduced the first installment (McNeal et al., 2014) we presented a literature review and overview of previous climate literacy efforts, addressed the complex affective, cognitive, and behavioral barriers associated with climate literacy, and introduced the reader to the 19 papers in that installment. Readers may wish to refer to this introduction, as it is pertinent to the work presented within this second installment. In this second part of the theme issue, 11 papers continue to explore the outcomes of climate literacy efforts across the realms of precollege teacher professional development, teacher and student knowledge and alternative conceptions, undergraduate education, climate data use, public perception and innovative tools for student learning. The papers in this two-part theme are testimony to the imagination, commitment, and breadth of the geoscience education community, and to the support provided by institutions and agencies to further knowledge on this topic.