How Science Teachers can collaborate with their students using Peer Instruction

This article explores peer instruction in the science classroom. The authors use research in science education to illustrate, practically, how teachers can work with their students to increase learning using peer instruction.

‘Learning is least useful when it is private and hidden. It is most powerful when it becomes public and communal’. — Lee Shulman

‘The facts of science and, à fortiori, its laws are the artificial work of the scientist; science therefore can teach us nothing of the truth; it can only serve us as rule of action’. — Henri Poincaré 
 
Teachers often forget that science is social and rhetorical in nature. Group consensus and peer review, not political discourse, define scientific facts. Therefore, scientific instruction should embrace the push-and-pull and back-and-forth of scientific dialogue and argumentation. When instructors speak of the scientific method in school, they focus on generating hypotheses and conducting experiments, but often fail to present the whole process as what it really is — a way of crafting a convincing argument. In other words, science is a way of harnessing facts, logic, and evidence in order to convince others that a particular idea is likely to be correct. 
 
With this in mind, we present a way to introduce meaningful scientific discussion in the classroom using the most valuable classroom resource — the students themselves. This technique, called Peer Instruction, wrests control from the teacher and gives it to students. According to a recent paper by Dr. Trisha Vickrey, a Professor of Chemistry at the Brevard College, North Carolina, United States, and four of her co-authors, it is one form of researchbased instructional reform that has been widely adopted by instructors in science, technology, engineering, and math1.
 
Peer Instruction allows students time to talk, debate, and teach each other during instruction. Students can serve as tutors, models, and sounding boards for their peers. In fact, research shows that much learning occurs during these peer-to-peer interactions. According to John A.C. Hattie, a renowned professor of education, “If you want to increase student academic achievement, give each student a friend.” Social interaction, he asserts, drives students to become their own teachers. It is this social interaction that Peer Instruction seeks to provoke.
 
Additionally, Peer Instruction replicates something that is fundamental in the scientific process — convincing others of the ‘truth value’ of one’s approach. This is a process of argumentation — or systematically marshalling data and logic to explain one’s point of view. This rhetorical turn is crucial, forcing students to not only come up with the right answer, but also to explain how and why and convince others of the same. A student with a different explanation would approach their partner’s statements with a questioning attitude — and, also, an openmindedness to being wrong. What is interesting is that such conversations do not necessarily mean that the student with the right answer necessarily believes their own logic. A situation could arise where a student with an incorrect understanding manages to convince their partner (who may have had the right explanation) of its correctness. In fact, this situation may reveal weaknesses in the understanding of even those students who are able to come up with the right answer. Essentially, Peer Instruction stresses conceptual understanding and the logic of the argument, over merely getting the correct answer. 
 
What does the research say?
 
Eric Mazur, a Professor of Physics at Harvard, was interested in the practice of interactive voting. According to Drs. Eugene Judson and Daiyo Sawada of Arizona State University and the University of Alberta respectively, this practice has been used in science classrooms since the 1960s but has become popular on some campuses since the mid-1990s2. A teacher using interactive voting solicits student responses to a question through a class vote or poll, often with flashcards or ‘clicker’ systems. In some cases, the question may be intended to increase student curiosity; while in others, it may be designed to check for student understanding. Mazur discovered that in certain circumstances, students learned more if they discussed their answers with their peers after voting3. He coined the phrase Peer Instruction to describe this observation, and outlined a specific model for implementing it:
  1. Pose a question
  2. Give students time to think
  3. Have students record their individual answers
  4. Have students convince their neighbors (peer discussion)
  5. Have students record their revised answers
  6. Calculate the results
  7. Explain the correct answer
Fig. 1. Learning is least useful when it is private and hidden. It is most powerful when it becomes public and communal.
Credits: Quote by Lee Shulman. Illustration by Punya Mishra. License CC-BY-NC.
 
Mazur’s findings and his model for Peer Instruction inspired a generation of follow-up research. A ten-year study by Mazur and Catherine Crouch, his colleague at Harvard University, looked for differences in performance of students in an introductory Physics course taught by traditional lecture method versus those that used some element of Peer Instruction. They measured student performance by giving students conceptual Physics tests before and after class. Through this study, Mazur and Crouch showed that students who took the course with Peer Instruction consistently and significantly outperformed those who took a course without it. Often, learning gains of students in classes using Peer Instruction were twice as high as those in classes without it. Other studies showed that Peer Instruction improved learning in classes on geoscience, computer science, and calculus4, 5. This suggested that Peer Instruction may be suitable as a general teaching strategy, not confined to Physics.
 
Though Peer Instruction appears straightforward, each step contains subtle considerations for effective implementation. The following sections will unpack each step and give examples of best practices. 
 
How can teachers support Peer Instruction in their classrooms?
 
Guide 1: Choose the right question
 
Teachers know that questions differ in their degree of challenge. Questions that fit well with Peer Instruction represent a conceptual challenge for the students. A test question like, “Name the phases of mitosis in order,” provides students with the opportunity to recall information. A test question like, “How does alternation of generations represent an effective evolutionary turn for the survival of some plant species?” requires students to think through several concepts and link them together. 
 
Recall questions do not require Peer Instruction; simply providing the correct answer allows students to understand how their own answer was incorrect. Providing the correct answer for a conceptually challenging question does not allow students to understand how their answer was not correct. For such questions, merely providing answers without explanation honors the answer above the explanation. Without access to and practice with explanation of phenomena, students cannot truly develop an in-depth understanding of either scientific concepts or the central nature of argumentation in science.
 
Fig. 2. A diagram of the seven steps in the peer-instruction process.
Credits: Illustration by Punya Mishra. License CC-BY-NC.
 
Regarding the central nature of argumentation in science, Peer Instruction strengthens the conceptual fluency of students with correct answers. Such students may or may not fully understand all of the concepts behind the correct answer. Peer Instruction provides these students with a chance to talk through their thinking, particularly when a peer asks questions. As a result, it helps them think through their response and articulate it so that another student can understand it. Challenging questions require a deeper level of understanding, and Peer Instruction allows students to work through that deeper level of understanding together, regardless of their initial answer. Essentially, Peer Instruction emphasizes understanding over merely getting the right answer, while allowing students to participate in the authentic practice of argumentation in science. 
 
How to Implement: Think of Peer Instruction as a perfectly timed learning opportunity for your students. Will any old question do? Clearly, factual questions with answers that can be looked up do not work well. The trick, research shows, is to choose questions that focus on concepts, not on facts6. Also choose questions that incite curiosity — questions that may divide the class. Often, questions based on common misconceptions (e.g., “in a frictionless world, which falls faster: a bowling ball or a tennis ball?” ) drive rich peer discussion. 
 
Guide 2: Elicit individual responses
 
It seems counter-intuitive that individual responses are necessary for a technique called Peer Instruction, but research shows that Peer Instruction does not work without this crucial step. It is important for students to think initially through the question because it lights the fire of curiosity in the student. They make a decision and commit to it. When students do not engage in this step, peer discussion lacks robust peer critique. In these cases, less confident students often just go along with more confident students without deep discussion. Individual responses allow students time to engage with the question thoughtfully once without the influence of a peer. This initial commitment produces a deeper discussion between peers. 
 
How to Implement: Ask the question and allow students to share their individual answers in class. Introduce white boards, flash cards, paddles with ‘yes’ or ‘no’ written on each side, (or, if you have access, technology like iClickers or free online tools like Braincandy.org) for them to brainstorm and note their answers. Give them time and space to form an individual response and commit to it. This creates more engagement in the peer discussion to follow. Students report that taking the initial responsibility to answer the question individually forces them to think more deeply about the question and the answer. 
 
Fig. 3. How peer instruction works. Credits: Illustrations by Punya Mishra. License CC-BY-NC.
 
Guide 3: Peer discussion
 
Implementing peer discussion may be the single most important part of the whole Peer Instruction process. However, not every question posed to the class requires peer discussion. Research shows that when a question is too easy (over 70% of students get the correct answer on the first vote), teachers should just skip peer discussion because learning gains are negligible. If the question is too hard (under 35% of students get the correct answer on the first vote), teachers should provide more explanation or hints before discussion.
 
Additionally, teachers should prompt students to discuss not only their answers, but the reasons behind their answers. This is key because the focus of learning should be on conceptual understanding rather than getting the right answer. Research shows that when teachers prompt ‘reason-centered’ discussions instead of ‘answer-centered’ discussions, learning gains increase.
 
How to Implement: Observe students carefully during the first round of voting to see if the question is too easy or too difficult for peer discussion. If the question lies in the sweet spot between the two, then encourage students to turn to their neighbor and explain why they chose their individual answer. Give the students time to discuss; trust that they are acting as their own teachers. 
 
Guide 4: Explaining the answer
 
Peer Instruction is incomplete without a final explanation by the teacher after voting, discussing, and re-voting. Studies indicate that combining peer discussion with instructor explanation outperforms other similar pedagogical approaches. Presumably, this is because students are now primed and motivated to hear the instructor’s explanation. Which of their answers was correct — the first one (i.e., their individual answer), or the new one co-created with a peer? After the first steps of the Peer Instruction cycle, students are ready to hear their instructor’s point of view. 
 
How to Implement: Once student revotes are collected, identify and explain the correct answer. Try to draw on some of the popular answers, explaining why a certain answer reflects a common misconception or why a certain answer is correct. 
 
Conclusion
 
Peer Instruction empowers students to create their own ideas, defend their own thoughts and in the process bring clarity to their own thinking, and construct meaning with their peers. It motivates students, incites curiosity, and allows students to experience the collaborative aspect of finding answers. Peer Instruction works in a variety of disciplines and with students at different levels of engagement. And, if implemented correctly, it seems to improve not just factual knowledge but also conceptual  knowledge. Peer Instruction belongs in the tool-box of every educator precisely because it is empowering and effective.
 
References
  1. Vickrey T., Rosploch K., Rahmanian R., Pilarz M. & Stains M. (2015). Research-Based Implementation of Peer Instruction: A Literature Review. CBE-Life Sciences Education, 14(1).
  2. Judson E. & Sawada D. (2002). Learning from past and present: Electronic response systems in college lecture halls. Journal of Computers in Mathematics and Science Teaching, 21(2), 167-181.
  3. Mazur E. (1997). Peer Instruction: A User’s Manual. Upper Saddle River, NJ: Prentice Hall.
  4. McConnell D. A. et al. (2006). Using concepts to assess and improve student conceptual understanding in introductory geoscience courses. Journal of Geoscience Education, 54(1), 61-68.
  5. Miller K., Lasry N., Lukoff B., Schell J. & Mazur E. (2014). Conceptual question response times in peer instruction classrooms. Physical Review Special Topics- Physics Education Research, 10(2), 020113.
  6. Rao S. P., & DiCarlo S. E. (2000). Peer instruction improves performance on quizzes. Advances in Physiology Education, 24(1), 51-55.

Kevin Close is a doctoral student in Learning, Literacies, and Technologies at Arizona State University. He researches culturally-sensitive standardized tests, measuring complex learning, and classroom formative assessments. He can be contacted at kevin.close@asu.edu.
 
Nicole Bowers is a doctoral student in Learning, Literacies, and Technologies at Arizona State University. Her research interests include trajectories that people follow to become scientists and organizations that support student-centered learning. She can be contacted at nbowers1@asu.edu.
 
Rohit Mehta is an Assistant Professor in Curriculum and Instruction at California State University, Fresno. His research is on scientific literacy and inclusion in the new media age. He can be contacted at mehta@csufresno.edu.
 
Punya Mishra is Associate Dean of Scholarship and Innovation, and Professor at Arizona State University. He can be contacted at punya.mishra@asu.edu.
 
J. Bryan Henderson is an Assistant Professor in Learning Sciences at Arizona State University. He is interested in the utilization of educational technology and evidence-based argumentation to facilitate peer-to-peer science learning via formative assessment techniques. He can be contacted at jbryanh@asu.edu.
 
 

 

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