Inquiry‐based ecology laboratory courses improve student confidence and scientific reasoning skills

Beck, Christopher W.; Blumer, Lawrence S.

doi:10.1890/es12-00280.1

Cited by 43 publications

(45 citation statements)

References 12 publications

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“…There are multiple learning gains that students can develop in HE, which are linked to the learning outcomes or learning goals of the course: development of the conceptual understanding of the topic [13]; scientific reasoning and confidence in reasoning skills [14]; scientific writing and reading [15]; critical thinking [16]; problem solving, creativity, analytical ability, technical skills and communication [17]; moral reasoning [18]; leadership [19]; interest in political and social environment [20]; well-being [21]; and motivation [22]. Measuring such a variety of learning gains is a challenge in itself and a number of methodologies have been used to assess them.…”

Section: Introductionmentioning

confidence: 99%

Assessing Learning Gains

Rogaten

Rienties

Whitelock

2017

Technology Enhanced Assessment

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Abstract. Over the last 30 years a range of assessment strategies have been developed aiming to effectively capture students' learning in Higher Education and one such strategy is measuring students' learning gains. The main goal of this study was to examine whether academic performance within modules is a valid proxy for estimating students' learning gains. A total of 17,700 Science and Social Science students in 111 modules at the Open University UK were included in our three-level linear growth-curve model. Results indicated that for students studying in Science disciplines modules, module accounted for 33% of variance in students' initial achievements, and 26% of variance in subsequent learning gains, whereas for students studying in Social Science disciplines modules, module accounted for 6% of variance in initial achievements, and 19% or variance in subsequent learning gains. The importance of the nature of the consistent, high quality assessments in predicting learning gains is discussed.

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Section: Introductionmentioning

confidence: 99%

Assessing Learning Gains

Rogaten

Rienties

Whitelock

2017

Technology Enhanced Assessment

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“…The above principles place a strong emphasis on active student-centered learning. For decades, active learning has been promoted as a resolution for poor outcomes in STEM, including ecology, and as a method to bridge the gap between content and application (Allen et al 1996, Duch 1996a, NRC 1996, 1999, Duch et al 2001, D'Avanzo 2003, Tessier 2004, Herreid 2005, Villamagna and Karpanty 2009, AAAS 2010, Beck and Blumer 2012, Freeman et al 2014, Lewinsohn et al 2015. Use of active learning has increased; however, progress is slow, and in 2014, 50.6% of undergraduate instructors reported heavily relying on lecture (Tobias 1992, National Research Council 1999, Seymour 2002, Eagan et al 2014.…”

Section: From Principles To Practicementioning

confidence: 99%

“…While other articles promote active learning for STEM instruction, including in ecological classrooms (D'Avanzo 2003, Tessier 2004, Herreid 2005, Villamagna and Karpanty 2009, American Association for the Advancement of Science 2010, Beck and Blumer 2012, Freeman et al 2014, Lewinsohn et al 2015, even specifically endorsing problem-based learning (Allen et al 1996, Tessier 2004, Beck and Blumer 2012, few combine a comprehensive methodological overview and practical advice on implementation (but see Allen 1997). This article aimed to assist ecology instructors venturing into problem-based learning by reviewing the theory, highlighting successful applications, and presenting selected resources.…”

Section: From Principles To Practicementioning

confidence: 99%

“…More empirical research linking problem-based learning to instructional outcomes in STEM classrooms is needed; however, early evidence supports its efficacy. Many educators in independent programs and courses report significant increases in student learning, skills, and meta-cognitive ability (Duch 1996a, Pelaez 2002, Armbruster et al 2009, Downing et al 2009, Beck and Blumer 2012, Loyens et al 2015. Further, instructors often describe gains in soft skills, such as teamwork, leadership, and social interaction, which can be important for students beyond the classroom (Duch 1996a, Tessier 2004, Williams et al 2010.…”

Section: The Problem-based Modelmentioning

confidence: 99%

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Teaching Introductory Ecology with Problem‐Based Learning

Burrow

2018

Bulletin Ecologic Soc America

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The popularity of ecology and historic trends toward larger class sizes have led to an increasing reliance on lecture and content‐driven learning; over‐reliance on these methods is associated with student difficulties in applying knowledge to solve complex environmental problems. Active learning is often cited as a remedy for poor student outcomes. Problem‐based learning, an active‐learning model, emphasizes student‐centered learning through problem‐solving activities driven by the search for problem solutions. This learning model develops critical thinking and problem‐solving skills while simultaneously advancing content knowledge. Problem‐based learning can enhance student knowledge and skill gains in introductory ecology courses; however, this method is rarely implemented in these courses. Adoption of active‐learning models is on the rise; however, instructors unfamiliar with educational theory and active‐learning methods may need support in understanding the efficacy of active learning and selecting a method from the multitude of instructional strategies available. To familiarize ecology instructors with one active‐learning model, problem‐based learning, the theoretical base, and evidence for its efficacy are reviewed. In addition, to assist instructors venturing into problem‐based learning, successful applications are highlighted and selected resources are provided for getting started.

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“…For decades, there have been calls to provide undergraduate students with authentic research experiences—creative explorations in which the answers are unknown and experimental design is student‐driven (Novak 1964, Germann 1991, Haury 1993, Lopatto 2004, Seymour et al 2004, Hunter et al 2007, Casotti et al 2008, Sadler et al 2010). Numerous studies show benefits to undergraduates who are explicitly taught research skills (Dirks and Cunningham 2006, Coil et al 2010, Beck and Blumer 2012). However, teaching undergraduates the skills they need to engage in authentic research—question formulation, experimental design, problem solving, data interpretation, scientific writing and communication, collaboration, critical analysis of the literature—is a tall order for faculty.…”

Section: Introductionmentioning

confidence: 99%

A Practical Guide for Mentoring Scientific Inquiry

Symes¹,

Serrell

Ayres³

2015

Bulletin Ecologic Soc America

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Science is a process of acquiring understanding, not just a collection of facts. The literature on teaching science emphasizes the importance of student research—teaching students to develop new knowledge, rather than solely assimilating facts. As student research becomes more widely integrated into curricula, there is an ongoing opportunity to develop and refine explicit techniques and tactics for facilitating authentic research by students. Here, we draw on our experience as instructors in the tropical biology field course at Dartmouth College to provide specific strategies and approaches that we have used to help students conceive and conduct original research projects. We organize our suggestions around the stages of the research process, from generating and refining questions, optimizing methods, and interpreting data, through presenting findings and placing research in a broader context. Although research skills often develop organically through immersion in research environments, it is our experience that explicit instruction can expedite the development of these critical skills.

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Inquiry‐based ecology laboratory courses improve student confidence and scientific reasoning skills

Cited by 43 publications

References 12 publications

Assessing Learning Gains

Assessing Learning Gains

Teaching Introductory Ecology with Problem‐Based Learning

A Practical Guide for Mentoring Scientific Inquiry

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