Authors: Jo Boaler
What's Math Got to Do with It?: How Teachers and Parents Can Transform Mathematics Learning and Inspire Success (29 page)
2
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Realms of Knowledge: Academic Departments in
Secondary Schools
(London: Falmer Press, 1994).
3
. Etienne Wenger,
Communities of Practice: Learning, Meaning, and
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(Cambridge, England: Cambridge University Press, 1998).
4
. Lave,
Cognition in Practice.
4/Taming the Monster: New Forms of Testing That Encourage Learning
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. Alfie Kohn,
The Case Against Standardized Testing: Raising the Scores, Ruining the Schools
(Portsmouth, NH: Heinemann, 2000), 1.
2
. Paul Black and Dylan Wiliam,
Inside the Black Box: Raising Standards through Classroom Assessment
(London: Department of Education and Professional Studies, King’s College, 1998).
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Assessment for Learning: Putting It into Practice
(Berkshire, England: Open University, 2003).
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The SAT Gender Gap: ETS Responds
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42, no. 1 (2003): 51–58.
8
. Kohn,
The Case Against Standardized Testing
, 30.
9
. Jo Boaler and Megan Staples, “Creating Mathematical Futures through an Equitable Teaching Approach: The Case of Railside School,”
Teachers College Record
110, no. 3 (2008): 608–45. Cited in the case of
Parents v. The Seattle Court District
(nos. 05-908 and 05-915). Available for download at www.youcubed.stanford.edu.
10
. Jo Boaler, “When Learning No Longer Matters: Standardized Testing and the Creation of Inequality,”
Phi Delta Kappan
84, no. 7 (2003): 502–06. Available for download at www.youcubed.stanford.edu.
11
. Barbara Y. White and John R. Frederiksen, “Inquiry, Modeling, and Metacognition: Making Science Accessible to All Students,”
Cognition and Instruction
16, no. 1 (1998): 3–118.
12
. Black and Wiliam,
Inside the Black Box
.
13
. Claude M. Steele, “A Threat in the Air: How Stereotypes Shape Intellectual Identity and Performance,”
American Psychologist
52, no. 6 (1997): 613–29.
14
. Diane Reay and Dylan Wiliam, “I’ll Be a Nothing: Structure, Agency and the Construction of Identity Through Assessment,”
British Educational Research Journal
25, no. 3 (1999): 345–46.
15
. Avraham N. Kluger and Angelo DeNisi, “The Effects of Feedback Interventions on Performance: A Historical Review, a Meta-Analysis, and a Preliminary Feedback Intervention Theory,”
Psychological Bulletin
119, no. 2 (1996): 254–84.
16
. M. Deevers,
Linking Classroom Assessment Practices with Student Motivation in Mathematics
, paper presented at annual meeting of the American Educational Research Association held in San Francisco, 2006.
17
. White and Frederiksen, “Inquiry, Modeling, and Metacognition.”
18
. Paul Black, Christine Harrison, Clare Lee, Bethan Marshall, and Dylan Wiliam,
Working Inside the Black Box: Assessment for Learning in the Classroom
(London: Department of Education and Professional Studies, King’s College, 2004).
19
. Maria Elawar and Lyn Corno, “A Factorial Experiment in Teachers’ Written Feedback on Student Homework: Changing Teacher Behavior a Little Rather Than a Lot,”
Journal of Educational Psychology
77, no. 2 (1985): 162–73.
20
. Ruth Butler, “Enhancing and Undermining Intrinsic Motivation: The Effects of Task-Involving and Ego-Involving Evaluation on Interest and Performance,”
British Journal of Educational Psychology
58, no. 1 (1998): 1–14.
21
. Dylan Wiliam, “Keeping Learning on Track: Classroom Assessment and the Regulation of Learning,” in Frank K. Lester Jr., ed.,
Second Handbook of Mathematics Teaching and Learning
(Greenwich, CT: Information Age Publishing, 2007), 1085.
22
. D. Royce Sadler, “Formative Assessment and the Design of Instructional Systems,”
Instructional Science
18 (1989): 119–44.
5/Stuck in the Slow Lane: How American Grouping Systems Perpetuate Low Achievement
1
. James W. Stigler and James Hiebert,
The Teaching Gap: Best Ideas from the World’s Teachers for Improving Education in the Classroom
(New York: Free Press, 1999).
2
. Albert E. Beaton and Laura M. O’Dwyer, “Separating School, Classroom, and Student Variances and Their Relationship to Socioeconomic Status,” in David F. Robitaille and Albert E. Beaton, eds.,
Secondary Analysis of the TIMSS Data
(Dordrecht, Netherlands: Kluwer Academic Publishers, 2002).
3
. Gerald Bracey, “Tracking, by Accident and by Design,”
Phi Delta Kappan
85, no. 4 (2003): 332–33.
4
. Lisa Yiu,
Teaching Goals of Eighth Grade Mathematics Teachers: Case Study of Two Japanese Public Schools
(Stanford, CA: Stanford University, School of Education, 2001).
5
. Carol Burris, Jay Heubert, and Henry Levin, “Accelerating Mathematics Achievement Using Heterogeneous Grouping,”
American Educational Research Journal
43, no. 1 (2006): 103–34.
6
. Andrew C. Porter and Associates,
Reform of High School Mathematics and Science and Opportunity to Learn
(New Brunswick, NJ: Consortium for Policy Research in Education, 1994).
7
. Robert Rosenthal and Lenore Jacobson,
Pygmalion in the Classroom: Teacher Expectation and Pupils’ Intellectual Development
(New York: Holt, Rinehart and Winston, 1968).
8
. Jo Boaler, Dylan Wiliam, and Margaret Brown, “Students’ Experiences of Ability Grouping—Disaffection, Polarisation and the Construction of Failure,”
British Educational Research Journal
26, no. 5 (2000): 631–48.
9
. PISA, Learning from Tomorrow’s World.
10
. Dylan Wiliam and Hannah Bartholomew, “It’s Not Which School but Which Set You’re In That Matters: The Influence of Ability-Grouping Practices on Student Progress in Mathematics,”
British Educational Research Journal
30, no. 2 (2004): 279–93.
11
. Jeannie Oakes,
Keeping Track. How Schools Structure Inequality
(New Haven, CT: Yale University, 2005), 217.
12
. Ibid., 218.
13
. Steve Olson,
Count Down: The Race for Beautiful Solutions at the International Mathematical Olympiad
(New York: Houghton Mifflin, 2005), 48–49.
14
. Jo Boaler, “The ‘Psychological Prison’ from Which They Never Escaped: The Role of Ability Grouping in Reproducing Social Class
Inequalities,”
Forum
47, nos. 2, 3 (2006): 135–44.
15
. Anabelle Dixon, Editorial,
Forum
44, no. 1 (2002): 1.
6/Paying the Price for Sugar and Spice:
How Girls and Women Are Kept Out of Math and Science
1
. Chi-squared = 16.96,
n
=163, 4 d.f.,
p
< 0.001.
2
. Anat Zohar and David Sela, “Her Physics, His Physics: Gender Issues in
Israeli Advanced Placement Physics Classes,”
International Journal of
Science Education
25, no. 2 (2003): 261.
3
. Carol Gilligan,
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Women’s Development
(Cambridge, MA: Harvard University, 1982).
4
. Mary F. Belenky, Blythe M. Clinchy, Nancy R. Goldberger, and Jill M. Tarule,
Women’s Ways of Knowing: The Development of Self, Voice, and Mind
(New York: Basic Books, 1986), 214–29.
5
. Janet S. Hyde, Elizabeth Fennema, and Susan Lamon, “Gender Differences in Mathematics Performance: A Meta-Analysis,”
Psychological Bulletin
107, no. 2, (1990): 139–55.
6
. They recorded an effect size of only +0.15 standard deviations.
7
. Rosser,
SAT Gender Gap
.
8
. The examination was then called the O-level.
9
. In 2003–2004, for example, 51 percent of the A, B, and C grades went to girls.
10
. Joanne R. Becker, “Differential Treatment of Females and Males in Mathematics Class.”
Journal for Research in Mathematics Education
12, no. 1 (1981): 40–53.
11
. Abbe H. Herzig, “Becoming Mathematicians: Women and Students of Color Choosing and Leaving Doctoral Mathematics,”
Review of Educational Research
74, no. 2 (2004): 171–214.
12
. Abbe H. Herzig, “‘Slaughtering This Beautiful Math’: Graduate Women Choosing and Leaving Mathematics,”
Gender and Education
16, no. 3 (2004): 379–95.
13
. Michele Cohen, “A Habit of Healthy Idleness: Boys’ Underachievement in Historical Perspective,” in Debbie Epstein, Jannette Elwood, Valerie Hey, and Janet Maw, eds.,
Failing Boys?: Issues in Gender and Achievement
(Buckingham, England: Open University, 1999), 24.
14
. John Bennett, cited in ibid., 25.
15
. Pat Rogers and Gabriele Kaiser, eds.,
Equity in Mathematics Education:
Influences of Feminism and Culture
(London: Falmer, 1995).
7/Key Strategies and Ways of Working
1
. Eddie Gray and David Tall, “Duality, Ambiguity, and Flexibility: A ‘Proceptual’ View of Simple Arithmetic,”
Journal for Research in Mathematics Education
25, no. 2 (1994): 116–40.
2
. William P. Thurston, “Mathematical Education,”
Notices of the American Mathematical Society
37 (1990): 844–50.
3
. T. A. Beck, “Are There Any Questions? One Teacher’s View of Students and Their Questions in a Fourth-Grade Classroom,”
Teaching and Teacher Education
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4
. Thomas L. Good, Ricky L. Slavings, Kathleen H. Harel, and Hugh Emerson, “Student Passivity: A Study of Question Asking in K–12 Classrooms,”
Sociology of Education
60 (1987), 181–99.
5
. Boaler and Staples, “Creating Mathematical Futures.”
6
. James G. Greeno, “Number Sense as Situated Knowing in a Conceptual Domain,”
Journal for Research in Mathematics Education
22, no. 3 (1991): 170–218.
7
. Jo Boaler and Cathy Humphreys,
Connecting Mathematical Ideas: Middle School Video Cases to Support Teaching and Learning
(Portsmouth, NH: Heinemann, 2005).
8
. D. L. Ball, “With an Eye on the Mathematical Horizon: Dilemmas of Teaching Elementary Mathematics,”
The Elementary School Journal
93, no. 4 (1993): 373–97.
9
. Magdalene Lampert,
Teaching Problems and the Problems of Teaching
(New Haven, CT: Yale University, 2001).
10
. Cathy Humphreys and R. Parker,
Making Number Talks Matter. Developing Mathematical Practices and Deepening Understanding, Grades 4–10
(Portland, ME: Stenhouse, 2015).
11
. Mathematics Education Collaborative, http://www.mec-math.org.
12
. I am grateful to Emily Shahan for her in-depth analysis and descriptions
of Jorge’s experiences.
13
. I am grateful to Tesha Sengupta-Irving for her in-depth analysis and descriptions of Alonzo’s experiences.
8/Giving Children the Best Mathematical Start: Activities and Advice for Parents
1
. Nicholas Fiori,
In Search of Meaningful Mathematics: The Role of Aesthetic Choice
(doctoral dissertation, Stanford University, 2007).
2
. M. Beth Casey, Ronald L. Nuttall, and Elizabeth Pezaris, “Mediators of Gender Differences in Mathematics College Entrance Test Scores: A Comparison of Spatial Skills with Internalized Beliefs and Anxieties,”
Developmental Psychology
33, no. 4 (1997): 669–80.
3
. Eleanor Duckworth,
“The Having of Wonderful Ideas” and Other Essays on Teaching and Learning
(New York: Teachers College, 1996).
4
. Allison M. Ryan and Helen Patrick, “The Classroom Social Environment and Changes in Adolescents’ Motivation and Engagement During Middle School,”
American Educational Research Journal
38, no. 2 (2001): 437–60.
5
. Jacquelynne S. Eccles, Allan Wigfield, Carol Midgley, David Reuman, Douglas Mac Iver, and Harriet Feldlaufer, “Negative Effects of Traditional Middle Schools on Students’ Motivation,”
The Elementary School Journal
93, no. 5 (1993): 553–74.
6
. Deborah Stipek and Kathy Seal,
Motivated Minds: Raising Children to Love Learning
(New York: Henry Holt, 2001).
7
. M. Frank, “Problem Solving and Mathematical Beliefs,”
Arithmetic Teacher
35, no. 5 (1988): 32–34.
8
. Joe Garofalo, “Beliefs and Their Influence on Mathematical Performances,”
Mathematics Teacher
82, no. 7 (1989): 502–5.
9
. Flannery,
In Code
.
10
. Ibid., 8.
11
. Ibid.
12
. Kenschaft,
Math Power
,
50.
13
. Boaler and Humphreys,
Connecting Mathematical Ideas.
14
. Kenschaft,
Math Power,
51.
15
. Jacquelynne S. Eccles and Janis E. Jacobs, “Social Forces Shape Math Attitudes and Performance,”
Signs: Journal of Women in Culture and Society
11, no. 21 (1986): 367–80.
