1. 1 A scientific approach to learning and teaching physics (or any other science or engineering subject) Carl Wieman Department of Physics and School of Education Stanford University Today– how you can learn to solve problems like a scientist/engineer as quickly and effectively as possible 25 years ago— “Why can students do so well in physics course but come into my lab and cannot do physics?”

2. Approaching the teaching and learning of science as a science Doing controlled experiments. Different ways of teaching and measuring learning results. Find what works and why—DATA! Started in physics, now similar research & results from all undergrad sciences and engineering Also bring in research from cognitive psych– how brain thinks & learns

3. Experiment #1: 1)go to lecture, take notes, learn as much as possible (AMAP) 2)go to lecture, don’t take notes, learn AMAP 3)stay home, study instructors notes 1 hour, learn AMAP (good instructor notes) then all get same test on material in lecture. Predict learning: most to least (write down choice, then raise hand to vote) Why? a. 1,2,3 b. 3,2,1 c. 2,1,3 d. 2,3,1, e. 3,1,2

4. Experiment: 1)go to lecture, take notes, learn as much as possible (AMAP) 2)go to lecture, don’t take notes, learn AMAP 3)stay home, study instructors notes 1 hour, learn AMAP then all get same test on material in lecture. correct answer. 3,2,1. Completely understandable. Taking notes just added distraction “cognitive load”, compared to focusing on understanding in class. 2>1 Reading over notes, better pace, organization, more processing (assuming good notes!) 3>2

5. Experiment #2. Learning in the classroom Two nearly identical 250 student sections intro physics— same learning objectives, same class time, same test ( given right after 3 lectures). Experienced highly rated traditional lecturer (good teacher by current university measures) versus Recent Ph.D. in physics, trained in principles and methods of scientific teaching

6. 1. Targeted pre-class readings with quiz 2. Questions to solve, respond with clickers or on worksheets, discuss with neighbors 3. Discussion by instructor follows, not precedes. 4. Activities address prior knowledge. Class design When switch is closed, bulb 2 will a. stay same brightness, b. get brighter c. get dimmer, d. go out. 2 1 3 answer & reasoning

7. 1. Experienced highly rated traditional lecturer (good teacher by current university measures) versus 2. Recent Ph.D. in physics, trained in principles and methods of scientific teaching Agreed upon set of 12 learning objectives. Tested with pop quiz right after the three “lectures”. Predictions on comparison of the two courses?

8. Distribution of test scores ave 41 ± 1 % Entire distribution shifted up. Learning = 16/50 = 1/3 R. G. Science Mag. May 13, ‘11 Deslauriers, Schelew, Wieman

9. Research supports a fundamental principle— Effective learning of sci & eng (and likely most everything else) requires practice of the desired thinking processes, with guiding feedback on how to improve. Learner (you!) completing carefully designed tasks, getting timely and targeted feedback.

10. or ? Expert competence = factual knowledge Mental organizational framework  retrieval and application I. Expertise research* Ability to monitor own thinking and learning ("Do I understand this? How can I check?") New ways of thinking-- everyone requires MANY hours of intense practice to develop. Brain changed *Cambridge Handbook on Expertise and Expert Performance patterns, relationships, scientific concepts historians, scientists, chess players, doctors,...

11. II. Learning expertise*-- Challenging but doable tasks/questions Practicing all the elements of expertise with feedback and reflection. Requires brain “exercise” * “Deliberate Practice”, A. Ericsson research accurate, readable summary in “Talent is over-rated”, by Colvin concepts and mental models + selection criteria recognizing what information is needed to solve, what irrelevant does answer/conclusion make sense- ways to test moving between specialized representations (graphs, equations, physical motions, etc.)... Some components of S & E expertise Knowledge important but only as integrated part with how to use.

12. 12 Things you should do to improve your learning. 1)Study intensively & focused– stretch brain, or not at all. 2)Always look for ways to check your thinking. (analogies, other situations, other students, TAs, instructor) 3) If wrong, DON’T JUST GET RIGHT ANSWER. FIND OUT WHAT IS WRONG IN YOUR THINKING AND HOW TO FIX NEXT TIME. 4) Trying to think of alternative way to do problem. Other possible approximations. Ask “why?” each step. 5) Figure out in own mind how the topics are connected and related. 6) sleep (consolidates learning) does not help you do problems on exams very rapidly – if that is what counts, complain!

13. 13 Things you should do to improve your teaching Don’t passively accept tedious ineffective traditional lectures (pedagogical blood-letting) National Academy of Sciences American Assoc. of Universities & many others calling for change in how science being taught based on research. PNAS metaanalysis- improved learning, reduced failure rates. consistent across all STEM & all levels If do not walk out of every class thinking “here is what I learned today, this was useful” demand better– the data backs you up

14. Good References to learn more: S. Ambrose et. al. “How Learning works” Colvin, “Talent is over-rated” “Reaching Students” NAS Press (free pdf download) cwsei.ubc.ca-- resources, references, effective clicker use booklet and videos Summary of field and a number of good references –Pts I & II in “Microbe” magazine by Wieman and Gilbert (see at cwsei.ubc.ca website under research) A scientific approach to Science (Eng) learning

15. Research on Learning Components of effective teaching/learning 1.Motivation relevant/useful/interesting to learner sense that can master subject 2.Connect with prior thinking 3.Apply what is known about memory short term limitations achieving long term retention 4.Explicit authentic practice of expert thinking interactive engagement focused on developing expert thinking skills (scientific reasoning, sense-making, ….) 5.Timely & specific feedback From: Professor, TAs, fellow students, homework, tests, …

16. 9 instructors, 8 terms, 40 students/section. Same instructors, changed teaching methods  changed learning! Am. J. Physics May ‘11 Apply concepts of force & motion like physicist to make predictions in real-world context? average, traditional Cal Poly instruction 1 st year physics Learning gain from entire course

17. 17 Getting involved in my research- Using “CCK blackbox” to study inquiry/discovery skills ~impossible to measure & teach with traditional media ( Shima Salehi, Eric Kuo, Engin Bumbacher, CW) When do not know the answer: What strategies for figuring out? What questions do they ask? How do they interpret and act upon results? Consistent differences over large range of expertise– nonsci intro students to Stanford Physics Profs Next– finding effective ways to teach “Use any circuit elements and measurement tools to figure out the hidden circuit”

18. 18 What is happening in these classes? 2 1 3 When switch is closed, bulb 2 will a. stay same brightness, b. get brighter c. get dimmer, d. go out. “Answer individually with clicker, then discuss with students around you. Come up with reasons for right answer and why the others are wrong. Revote with clicker.” Students are solving tasks Instructor is circulating, listening in, coaching, then leads follow-up discussion.