1. Mathematics Across the Curriculum A strategy for Quantitative Literacy: Session 2 Åsa Bradley & Beverly Vredevelt Spokane Falls Community College asab@spokanefalls.edu beverlyv@spokanefalls.eduwww.mac3.amatyc.org

2. Whose Responsibility? “Quantitative literacy is more about habits of mind than specific mathematical content. Therefore, the responsibility for developing quantitative literacy, like writing across the curriculum, is shared by the entire college faculty. However, mathematics faculty should lead the quantitative literacy movement by helping to establish a set of outcomes expected of students in each program.” - AMATYC Beyond Crossroads

3. What Can MAC 3 Look Like? Successful Models: Smaller Scale: Shared/Linked assignments Learning modules Mini lectures/Guest lectures Thematic Projects Larger Scale: Learning Communities (Linked or fully co-taught) Campus wide initiative Integrated courses Service Learning Component

4. Learning Communities: A Case Study Fusion: The Unlikely Union of Physics and English Comp (A coordinated class: two instructors in the classroom at the same time) Original Idea Lori teach English (English 101 and 201) Åsa teach Physics (Physics 100) Students write about Physics After a MAC 3 Conference One central theme or concept. What are the BIG IDEAS we want the students to take with them? What skills should they retain after our class?

5. Assessing Fusion Combined Grade for Both Disciplines Major Essays (Research, Outline, Revise) Shorter In-Class Writing Prompts Learning Log Field Trips & Guest Speakers Activities In-Class Group Physics Activities (Problem Solving, ILD’s) Physics Homework Weekly Physics Lab with Write-up Final Group Research Project (Research, Present, Write Report)

6. Dividing Class Time Planned a quarter long tentative schedule for each discipline, but met weekly to plan following week. Kept it loose, often switched days depending on where students were. Usually had full English days and full Physics days.

7. MAC 3 Survey Constructs (Pre & Post) The students read 21 statements and rated them on a scale of 5 (strongly agree) to 1 (strongly disagree). Distributed to ten classes during the fall quarter/semester of 2006. Five constructs were extracted: Confidence in doing mathematics (I am good at math, I enjoy math.) Interest in mathematics (I want to learn more math.) Awareness of the role of mathematics in society (Many things I use were designed using math) Concept of Math (Estimating is part of math) Interdisciplinary Learning (Doing math in another subject makes the subject easier to learn)

8. Change in Students’ Math Attitudes (Based on 30 matched pre-post surveys from SFCC students)

9. Post Survey Self Evaluation of Math Skills Students were asked to evaluate their gains in the following areas on a scale from 1 (not at all) to 5 (a great deal): Understanding the relationship among concepts Ability to think through a problem Ability to solve problems Ability to communicate mathematical ideas Confidence in your ability to do mathematics Feeling comfortable with complex ideas Enthusiasm for mathematics

10. Post Survey Self Evaluation of Math Skills Highest gains (between “somewhat” and “a lot”) were in analytical categories: Understanding relationships among concepts Thinking through and solving problems Feeling comfortable with complex ideas All categories showed gain, but some where slightly below the “some what” mark: Ability to communicate mathematical ideas Confidence in ability to do math Enthusiasm for mathematics

11. Specific Learning Gains As a result of your work in this class, how well do you think you now understand the following: How to interpret a graph? How to use mathematical information in expository writing? How to evaluate the credibility of science writing? What kind of data to gather in order to answer a question? (The option “learned elsewhere” was included and students who marked this were excluded from the analysis.)

12. Specific Learning Gains (Based on 30 matched post surveys from SFCC students) Åsa M. Bradley MS SFCC Physics

13. Student Comments Please tell us the most important thing you learned in this class 23 offered comments 9 (nearly 40%) mentioned physics

14. Student Comments On Physics Physics can be fun! I learned about atoms. It’s hard to store energy. You can’t store energy. I learned a lot about energy. Åsa M. Bradley MS SFCC Physics

15. Student Comments On math/science and English How to perform better research on scientific subjects and how to put that information into an understandable flow How to write essays using the math parts of science. How to write a better academic paper and citing sources. Åsa M. Bradley MS SFCC Physics

16. Student Comments On group work How to interact with others. Working in groups is more rewarding if everyone participates. Working in groups and getting help from other students is important and helpful. Math and other people don’t mix well with me. Åsa M. Bradley MS SFCC Physics

17. Student Comments Big ideas Everything! How much more I have to learn about the universe. The importance of sustaining life and the consequences of pollution. Math is involved in everything, so is physics. Åsa M. Bradley MS SFCC Physics

18. Survey Conclusions Åsa M. Bradley MS SFCC Physics Overall, students in these ten (n=181) interdisciplinary courses left with a more positive assessment of mathematics, their interest in it and their ability to do it. The constructs measuring student’s mathematical confidence, interest, awareness of math in their lives, and appreciation of interdisciplinary learning changed in the desired direction. Integrating mathematics into other disciplines seem to lead to improved student attitudes about mathematics and enhance the learning of math content.

19. Lessons Learned Better integrated schedule More closely integrated assignments Students actually asked for more quizzes and tests! More progress reports for final project Keep writing group and science group the same On field trips, drive together in school van Students’ evaluations of each other bigger part of project grade More theme based approach closer integrated with big ideas Syllabus, Assignments, Projects and more are available at: http://faculty.spokanefalls.edu/AutoWebs/Default.asp?ID=2712&VLD=2712 www.spokanefalls.eduhttp://faculty.spokanefalls.edu/AutoWebs/Default.asp?ID=2712&VLD=2712 www.spokanefalls.edu → current students → online syllabus → Bradley, Asa - LC Resources for Instructors (password: instructor) Åsa M. Bradley MS SFCC Physics

20. Collaboration Session—Big Ideas 1.Get into groups of 2 or 3 participants. 2.What are the five main things you want your students’ to learn or be able to do by taking your class? (most important outcomes) 3.Write each of them on a post-it note. 4.Compare your big ideas with those of your colleagues. 5.Consolidate your big ideas with those of your colleagues and come up with a “main” set of outcomes? 6.Think of a theme that could be used for an integrated class or assignment that would address all or one of these outcomes. (Example: Teaching an integrated Composition and Physics class focused on Conservation of Energy.)

21. Collaboration Session—Big Ideas Report Back!

22. Another Collaboration Session Designing Theme Based & Integrative Learning Worksheet

23. Another Collaboration Session Report Back!

24. What To Do Next GPC Faculty Follow-up meeting? When? Where? Lots and lots of web resources…

25. Some Web Resources MAC 3 Projects and Courses (A list of QL integrated outcomes and assignments from a variety of disciplines) http://www.mac3.amatyc.org/projects.htm Dartmouth College Electronic Bookshelf (More QL integrated classroom examples) http://www.math.dartmouth.edu/~mqed/index.html Statistical Literacy (A website dedicated to develop SL as an interdisciplinary curriculum in the liberal arts.) http://www.statlit.org/ Social Science Data Analysis Network (Similar to above, but this one has examples for the Social Sciences.) http://www.ssdan.net/chip/exercises.shtml Mathematical Association of America’s QL site http://www.maa.org/Ql/ AMATYC’s QL site (Includes books, articles, and professional development opportunities.) http://www.beyondcrossroads.com/QLindex.html

26. More Web Resources The National Numeracy Network ( A network of individuals, institutions, and corporations united by the common goal of quantitative literacy for all citizens. Includes great teaching resources.) http://serc.carleton.edu/nnn/ Numeracy (Online Journal for QL) http://services.bepress.com/numeracy/ SIGMAA on QL (Special Interest group of the MAA focusing on QL includes teaching, textbooks, and job resources) http://pc88092.math.cwu.edu/~montgomery/sigmaaql/ Colby-Sawyer's QL website (They have a NSF grant for increasing QL scores): http://www.colby-sawyer.edu/academics/experience/quantitative/index.html More classroom and web resources at: http://faculty.spokanefalls.edu/AutoWebs/Default.asp?ID=2712&VLD=2712 www.spokanefalls.edu → current students → online syllabus → Bradley, Asa - LC Resources for Instructors (password: instructor)http://faculty.spokanefalls.edu/AutoWebs/Default.asp?ID=2712&VLD=2712 www.spokanefalls.edu

27. Thank You! Feel free to contact us with any questions Åsa Bradley & Beverly Vredevelt Spokane Falls Community College asab@spokanefalls.edu beverlyv@spokanefalls.edu