Journal of Urban Mathematics Education 

December 2016, Vol. 9, No. 2, pp. 122–152 

©JUME. http://education.gsu.edu/JUME 

 

 

MARY CANDACE RAYGOZA is a Ph.D. Candidate in Urban Schooling and Collegium of Uni-

versity Teaching Fellow at the University of California, Los Angeles, 1320 Moore Hall, Los An-

geles, CA 90095, USA; email: mary.candace.raygoza@ucla.edu. Her research interests include 

mathematics learning, teaching, and teacher education; equity and social justice in mathematics 

education; critical and culturally relevant/sustaining mathematics pedagogy; and transformative 

school change. 

Striving Toward Transformational  

Resistance: Youth Participatory Action  

Research in the Mathematics Classroom 
 

Mary Candace Raygoza 

University of California, Los Angeles 

 
In this article, the author contributes to the growing body of scholarship on critical 

mathematics pedagogy. In particular, the author advances this scholarship by out-

lining how critical pedagogy in the mathematics classroom can support students to 

engage in transformational resistance. Using a critical practitioner research ap-

proach, the author retells (some of) her experiences as a high school mathematics 

teacher of ninth-grade Latin@ students in an Algebra I classroom. Beginning the 

course with activities to build a beloved community and connecting mathematics 

with social justice issues, the author strived to facilitate a learning space that sup-

ported transformational resistance. Through a culminating youth participatory ac-

tion research project, students developed a critique of societal oppression, a moti-

vation for social justice, and critical mathematical literacy. 

 

KEYWORDS: critical pedagogy, teaching mathematics for social justice, transforma-

tional resistance, youth participatory action research  

 

he sun beamed through our East Los Angeles classroom windows as my 23 

Algebra I students excitedly entered data from a school-wide student survey on 

school food (in)justice issues which they had designed and conducted the weeks 

prior. Students were still learning how to use data software on the classroom lap-

tops, when one student noticed that a column for data entry was missing. I showed 

her how to insert a new column. She titled it, paused, and then said, “This column is 

a variable, right? Yeah, yeah, that’s a variable.” Her tone was as if something spin-

ning around in her mind for a while, or perhaps since she first took Algebra I the 

year prior as an eighth grader (and “failed”), just settled into place. This moment 

encouraged me to conclude class that day with a discussion of the meaning of a var-

iable, something that the students, instead of only saying “a letter that represents a 

number,” now attached real-world significance to as they were defining, measuring, 

representing, and making claims about variables related to a social justice issue in 

their lives. As a teacher, I sought to develop a critical pedagogy to support students 

to understand and transform the world (Freire, 1970/2007). Witnessing students’ 

T 

http://education.gsu.edu/JUME
mailto:mary.candace.raygoza@ucla.edu


 

 

 

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Journal of Urban Mathematics Education Vol. 9, No. 2                                        123 

excitement as they came to understand the meaning of a foundational component of 

mathematical knowledge in the context of conducting their own research and activ-

ism related to school food (in)justice, affirmed for me the promise of teaching 

mathematics for social justice (see, e.g., Gutstein, 2003) and integrating mathemati-

cal investigation in youth participatory action research (Terry, 2011; Yang, 2009). 

My aim with this article is to contribute to the growing body of scholarship on 

critical mathematics pedagogy (see, e.g., Bacon, 2012; Bartell, 2013; Brantlinger, 

2013; González, 2009; Gregson, 2013; Gutstein, 2003, 2006; Gutstein & Peterson, 

2013; Terry, 2011; Wager & Stinson, 2012; Yang, 2009). In particular, I advance 

this body of work by outlining how critical pedagogy in the mathematics classroom 

can support students to engage in transformational resistance (cf., Solórzano & 

Delgado Bernal, 2001). Using a critical practitioner research approach, I retell 

(some of) my experiences as a high school mathematics teacher of ninth-grade Lat-

in@ students’ in our Algebra I classroom in East Los Angeles. Beginning the 

course with activities to build a beloved community (King, 2010) and facilitating 

lessons throughout the course that connected mathematics with social justice issues 

(Gutstein & Peterson, 2013), I strived to foster the classroom as a space where de-

veloping transformational resistance was possible. Through a culminating course 

youth participatory action research (YPAR) project, students conducted a quantita-

tive study on school food (in)justice. Students developed a critique of societal op-

pression, a motivation for social justice (Solórzano & Delgado Bernal, 2001), and 

critical mathematical literacy (Gutstein, 2006). I argue that YPAR involving quanti-

tative investigation can support students to develop positive mathematical and re-

searcher identities and contribute to change for social justice. 

 
Conceptual Framework 

 

Teaching Mathematics for Social Justice 
 

Striving to teach mathematics for social justice involves engaging students in 

critical quantitative thinking around issues of social (in)justice that are relevant to 

their lives and daily experiences (see, e.g., Frankenstein, 1983; Gutstein, 2006; 

Skovsmose, 1994). Freire (1970/2007) argues, “the great humanistic and historical 

task of the oppressed” is “to liberate themselves and their oppressors as well” (p. 

44). Students of color and economically marginalized students bring valuable life 

expertise from their own experiences and backgrounds into the classroom, and can 

develop critical literacies to examine the unjust world around them so that they may 

both understand it and change it. Freire posits that a problem-posing pedagogy in 

which students pose problems and develop solutions as they co-create knowledge is 

necessary for the liberation of all peoples. Both teachers and students engage in cy-



 

 

 

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Journal of Urban Mathematics Education Vol. 9, No. 2                                        124 

cles of praxis, or the continuous process of “reflection and action upon the world in 

order to transform it” (Freire, 1970/2007, p. 51). 

Powell (2012) outlines the historical development of critical perspectives on 

mathematics education. Teaching mathematics for social justice, also referred to as 

critical mathematics or criticalmathematics education in different regions and time 

periods—and also deeply intertwined with ethnomathematics—has origins from 

long ago, as national and global struggles for social justice and struggles for math-

ematics education have always been intertwined. Conferences convened by organi-

zations such as the African Mathematical Union and talks such as D’Ambrosio’s 

1986 plenary address introducing ethnomathematics were turning points in the 

mathematics education field. A number of conferences beginning in the late 1980s 

called for a sociopolitical look at mathematics and the teaching of mathematics, in-

cluding the Mathematics and Society Special Programme of the International Con-

gress on Mathematical Education in 1998, the Political Dimensions of Mathematics 

Education: Action and Critique conference in 1990, and the Critical Mathematics 

Education: Toward a Plan for Cultural Power and Social Change conference in 

1990, which gave rise to the Criticalmathematics Educators Group (CmEG). 

In a 1990 CmEG newsletter, Frankenstein, Volmink, and Powell offer a defi-

nition of a criticalmathematics educator, offering insight into how those who strive 

to be a criticalmathematics educator may think about commitments as a mathemati-

cian, as a teacher, and as a concerned active citizen. Criticalmathematics educators, 

as re-printed by Powell (2012)—  

  
view the discipline as one way of understanding and learning about the world … as 

knowledge constructed by humans … as one vehicle to eradicate the alienating, Euro-

centric model of knowledge … listen well (as opposed to telling) and recognize and re-

spect the intellectual activity of students … and have a relatively coherent set of com-

mitments and assumptions from which they teach, including an awareness of the ef-

fects of, and interconnections among racism, sexism, ageism, heterosexism, monopoly 

capitalism, imperialism, and other alienating totalitarian institutional structures and atti-

tudes. (pp. 26–27) 

 

Drawing on Frankenstein’s (1983) argument about the importance of mathe-

matical literacy for gaining power in society over economic, political, and social 

structures and Tate’s (1995) argument for culturally relevant pedagogy in mathe-

matics, which includes the study of issues relevant to students’ lives, as well as oth-

er mathematics education scholars committed to education and change, Gutstein 

(2006) argues that social justice mathematics prepares students “to investigate and 

critique injustice, and to challenge in words and actions, oppressive structures and 

acts” (p. 4). Merging mathematics and social issues is not primarily for the purpose 

of understanding mathematical concepts but for using mathematics to create a more 

just world (Frankenstein, 2010). 



 

 

 

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Journal of Urban Mathematics Education Vol. 9, No. 2                                        125 

Stinson and Wager (2012) define teaching mathematics for social justice as 

“the underlying belief that mathematics can and should be taught in a way that sup-

ports students in using mathematics to challenge injustices of the status quo as they 

learn to read and rewrite their world” (p. 6). They also define teaching with social 

justice as implementing equitable pedagogical practices, and teaching mathematics 

about social justice as teaching lessons with critical (and often controversial) social 

issue contexts. Examples of social issue contexts that connect with mathematics 

detailed in Rethinking Mathematics: Teaching Social Justice by the Numbers 

(Gutstein & Peterson, 2013) include: racial profiling, how the unemployment rate is 

determined, global poverty, school evaluation, and media and body image. Scholars 

argue that students may benefit from teaching mathematics about, with, and for so-

cial justice in the following ways: 

 

    Developing a positive mathematics identity – students overcome fears in 
mathematics by building a positive mathematical disposition rooted in 

their culture and community (Gutiérrez, 2012). Gutiérrez contends: 

 
Black and Latino/a adolescents, like all young people, reap the benefits of pro-

grams that attend to their academic
 and their social/emotional needs. Learners 
show more confidence and are better able to find an answer—and they can re-

flect on how reasonable that answer may be when they have opportunities 

to…use mathematics to analyze social injustices. (p. 35) 

 

    Reading and writing the world with mathematics – students consume and 
produce texts from a critical standpoint, making sense of data and the so-

cial context behind numbers, and developing social agency (Gutstein, 

2006; Yang, 2009). Gutstein describes students’ critical questioning as he 

quotes one student, Marisol, reflecting on a racial profiling unit: “I think I 

am better able to understand the world now using math…as soon as I fin-

ished the reading I already knew there was a problem there” (p. 67). Yang 

describes how students produced their own version of a school accounta-

bility report card with measures that the students themselves felt best 

evaluated their school. 

 

    Building mathematical power – students understand mathematical con-
cepts, engage in complex mathematical tasks, and communicate ideas in 

ways that allow students to access spaces in which “dominant mathemat-

ics” is used, such as high school and university courses as well as in sci-

ence, technology, engineering, and mathematics professions (Gutiérrez, 

2012; Gutstein, 2006). 

 

 



 

 

 

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Journal of Urban Mathematics Education Vol. 9, No. 2                                        126 

While critical mathematics education scholars emphasize the possibilities and 

promise of teaching and investigating connections between mathematics and social 

change, there are also “limitations of the knowledge we gain from mathematical 

analyses of our world” (Frankenstein, 1994, p. 56). Brelias (2015) found that as 

high school students who were engaged in social justice mathematics lessons re-

flected back on mathematics as a tool for social inquiry, while they argued for its 

transformative power, they also argued mathematics can be “reductive and imper-

sonal,” “irrelevant for moral arguments,” “inaccessible to the general public,” and 

can provide “inadequate explanations for problems” (p. 7). The students demon-

strate a “reflective knowing,” as Skovsmose (1994) describes, evaluating the use of 

mathematics. 

Scholars have laid the groundwork in theorizing teaching mathematics for so-

cial justice and translating critical theory to practice mathematics in schools, but 

this body of work must be further informed by more accounts of the affordances 

and challenges of integrating critical social justice issues in the mathematics class-

room (Gutstein, 2006). Duncan-Andrade and Morrell (2008) note: 

 
Very little empirical work has been done that theorizes the possible translation of prin-

ciples of critical pedagogy into practices, and even less work has been done that evalu-

ates the outcomes of these practices in pushing forward the development of grounded 

theories of practice. (p. 105) 

 

Youth Participatory Action Research and Transformational Resistance 
 

As with critical pedagogy, conceptualizations of participatory action research 

(PAR) are influenced by critical theory developed in the Frankfurt School. McTag-

gart (1991), drawing on Carr and Kemmis (1986/2004), asserts that PAR is “moti-

vated by a quest to improve and understand the world by changing it and learning 

how to improve it from the effects of the changes made”; it “treats people as auton-

omous, responsible agents who participate actively in making their own histories 

and conditions of life” (p. 181). Freire (1973) writes, “critical understanding leads 

to critical action” (p. 44). PAR can be understood as a cyclical process: those in op-

pressed conditions are engaged in research to understand a critical issue that they 

themselves identify as key to their freedom; they develop a plan for social action to 

challenge the inequity presented in that issue; and finally, they implement a plan for 

social change that they themselves developed. PAR methodology recognizes people 

as experts of their own knowledge and lived experiences. Those experiencing op-

pression, therefore, must be leaders of the research-action to understand and chal-

lenge it. 

Educators throughout the nation are bringing PAR into schools or doing PAR 

with youth outside of schools, adding a “Y” in front, to explore how this action-

research can be done specifically with youth (Cammarota & Fine, 2008). YPAR 



 

 

 

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Journal of Urban Mathematics Education Vol. 9, No. 2                                        127 

engages youth as researchers on societal or school (in)justice and supports youth to 

take action connected to their findings. YPAR is a problem-posing approach to ed-

ucation that challenges inequity by viewing youth as experts of their lived experi-

ences and places power in their hands. Cammarota and Fine (2008) argue, “YPAR 

teaches young people that conditions of injustice are produced, not natural; are de-

signed to privilege and oppress; but are ultimately challengeable and thus changea-

ble” (p. 2). They define YPAR as a process in which “young people resist the nor-

malization of systemic oppression by undertaking their own engaged praxis—

critical and collective inquiry, reflection and action focused on ‘reading’ and speak-

ing back to the reality of the world, their world” (p. 2). Duncan-Andrade and Mor-

rell (2008) put forth the argument that students in urban schools are the ones best 

equipped to be agents of change for equity and justice in urban education: 

 
As educators and as advocates for educational justice, we must understand that youth 

are much-needed collaborators with valuable experiences and energy to add to our 

movements. We firmly believe that youth participatory action research can ultimately 

develop the academic capabilities of students and, equally important, that youth-

initiated research can help adult researchers and advocates to better confront the seem-

ingly intractable problems of urban education. (p. 106)  

 

In this way, YPAR challenges the notion of research as an objective endeavor and 

challenges traditional conceptions of who can become a researcher. Additionally, 

YPAR offers opportunities for young people to think about and partake in the ways 

in which research can be connected to resistance against oppression. 

YPAR fosters students to resist injustice in a transformative way (Cammarota 

& Fine, 2008). Transformational resistance, as defined by Solórzano and Delgado 

Bernal (2001), encompasses a motivation for social justice and a critique of societal 

oppression. Solórzano and Delgado Bernal provide the 1968 East Los Angeles stu-

dent walkouts and the 1993 University of California, Los Angeles student strike for 

Chicana/o Studies as examples of transformational resistance, as secondary students 

and college students alike in each of these historic periods held critiques of oppres-

sive societal conditions and were motivated to make change for greater social jus-

tice. Cammarota and Fine call for further documentation of how young people en-

gage in transformational resistance—in and out of classrooms and related to various 

social injustices—and how educational processes can foster resistance. 

Supporting students to bring a social justice motivation to their mathematical 

coursework and to critique societal oppression through mathematics is under-

theorized and further examples of such praxis are needed. Terry (2011) and Yang 

(2009) each present theoretical arguments and empirical evidence to assert that 

young people can foster critical mathematical literacy and move that literacy to ac-

tion as they engage in YPAR. Terry (2011) argues that YPAR in mathematics can 

support students to engage in mathematical counterstory-telling, as he shares the 



 

 

 

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Journal of Urban Mathematics Education Vol. 9, No. 2                                        128 

ways in which Black male youth identified and contradicted a dominant narrative 

and framed access to freedom, in the context of an after-school program in South 

Los Angeles. Constructing mathematical counterstories can support students to self-

identify as doers of mathematics and ultimately involve “more transformative forms 

of resistance” (p. 43). 

Yang (2009) addresses the quantitative aspect of a multiyear YPAR study in 

which he and collaborators supported 30 high school youth to create their own 

School Accountability Report Card. Instead of accepting measures the state selected 

for school accountability, the youth decided what should be measured, including 

attributes like culturally relevant teaching. They conducted survey and interview 

research to discover if the school was meeting students’ needs and then reported 

that work to the student body and school leaders. Students “critically consumed” 

and “critically produced” texts, thus engaging in the process of reading and writing 

the world with mathematics. However, “math education has not realized its full po-

tential in developing youth researchers capable of producing critical texts at the lev-

el of public intellectuals” (p. 102).  

The study presented here further explores the possibility of quantitative ac-

tion-research projects, examining the implementation of YPAR within the context 

of an Algebra I classroom. Overall, I sought to provide students with the opportuni-

ty to engage in YPAR in our mathematics course, after we had laid a foundation for 

transformational resistance by building community and completing units connected 

to social (in)justice issues. I wondered: How can teaching students to be critical 

quantitative scholar-activists be included as a meaningful part of teaching a mathe-

matics course? 

 
Methods 

 

The voices of teachers in national conversation and research are essential for 

advancing change for educational equity and justice (Cochran-Smith & Lytle, 1999; 

Oakes & Rogers, 2006). Practitioner research is a “promising way to conceptualize 

the critical role of teachers’ knowledge and actions in student learning, school 

change, and educational reform” (Cochran-Smith & Lytle, 2009, p. 5). Critical, 

qualitative methodologies (Kincheloe & McLaren, 2002; Steinberg & Cannella, 

2012) shaped the design of this practitioner research investigation. In particular, this 

study is informed by practitioner research that emphasizes “equity, engagement, 

and agency,” as Cochran-Smith and Lytle (2009) identify as a more recent turn in 

practitioner research, pointing to books on YPAR and critical pedagogy such as 

Duncan-Andrade and Morrell’s The Art of Critical Pedagogy (2008) and Cam-

marota and Fine’s Revolutionizing Education: Youth Participatory Action Research 

in Motion (2008). They argue that such critical practitioner research has potential to 

question the goals of schooling, raise questions about power and whose voices are 



 

 

 

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Journal of Urban Mathematics Education Vol. 9, No. 2                                        129 

heard, bring meaning to equity in local contexts, and link teacher and student in-

quiry as interconnected. 

 

Research Questions 
 

The research questions that guided this investigation were: 

 

1.    How can a mathematics classroom develop as a beloved community lay a 
foundation for transformational resistance? 

 

2.    How can YPAR in a mathematics classroom support students to engage in 
transformational resistance as they build critical mathematical literacy?  

 

These questions serve as the focus of this article because integrating YPAR in the 

teaching of mathematics for social justice within mathematics courses is understud-

ied. Teachers’ stories that shed light on possibility and challenges of teaching math-

ematics for social justice are necessary to advance understandings of how social 

justice may come to fruition in a multitude of ways in the mathematics classroom 

(Bullock, 2014). I do not assert that the questions I pose can be fully addressed 

within this practitioner research examination, but I hope that striving to share an in-

depth, critical practitioner research study can join in dialogue with other accounts of 

mathematics teaching (such as Bacon, 2012; Brantlinger, 2013; Gutstein, 2003; 

Terry, 2011; Yang, 2009) and offer implications for future work. 

 

Teacher and Researcher Positionality 
 

Like all educational research, mathematics education research is political and 

non-neutral (D’Ambrosio et al., 2013; Gutstein, 2003). My experiences reflect the 

political nature of mathematics education research in my choice to be a part of so-

cial justice mathematics communities of educators, my belief that educational re-

search can and should contribute to a more socially just world, and my choice to 

follow in the footsteps of scholars who examine their own positionality as research-

ers. 

I entered teaching with an understanding that being a continual learner is an 

essential aspect of critical pedagogy and teaching mathematics for social justice. I 

believe it important for teachers—and for myself as a White female teacher and a 

teacher of STEM (science, technology, engineering, and mathematics)—to con-

stantly work to become more aware and knowledgeable about the historical and 

present day intersections of oppression based on race, ethnicity, class, gender, sexu-

al orientation, religion, age, special need, legal status, language, and so on. As a 

mathematics teacher, I strive to understand the ways in which STEM education 

perpetuates yet can intervene to challenge oppression. I also believe it important to 



 

 

 

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Journal of Urban Mathematics Education Vol. 9, No. 2                                        130 

build with other educators, both new and veteran, to learn from and alongside each 

other. As a White woman, I came into this research with the same consciousness 

that I attempted to bring into my classroom teaching: an understanding that White 

women are the most represented demographic group in the teaching profession. 

Voices from this group, therefore, are often centered and privileged in (and out of) 

schools. Moreover, the teaching profession is looked down on as “women’s work”; 

a devaluating I often felt as a teacher and experienced the seeds of growing up as a 

young woman. Interrogating my own positionality and pedagogy is a complex, life-

long process that can never be completed.  

Amidon’s (2013) argument on teaching mathematics with agape (a Koine 

Greek word, often translated to “unconditional love”), pushes me to think about the 

following questions, which I adapted from his work: What can I do from a position 

of power and privilege to interrupt oppression and be a part of supporting students 

to have the opportunity and expectation of success in mathematics and life? How 

can I learn from and alongside teachers from similar and different backgrounds who 

are working to support students to succeed in mathematics (according to traditional 

and critical ways of thinking about success)? In my teaching of mathematics to Lat-

in@ students in an economically marginalized community, I sought to interrupt 

power, privilege, and oppression (Amidon, 2013); develop a “critical care praxis,” 

challenging a colorblind approach of caring for students (Rolón-Dow, 2005); and 

express to students a political and radicalized love (Darder, 2002). Below I detail 

the ways in which I attempted to bring these ideas to life in my pedagogy, while 

acknowledging my continuous need for critical self-reflection. 

 

Classroom and Study Context 
 

The public school in which I taught was one fought for and created by com-

munity teachers and organizations in East Los Angeles, including the organization 

InnerCity Struggle (see http://innercitystruggle.org). It was one of the first public 

high schools built in the larger community in 80 years, after community organizing 

pushed for new schools due to over-crowding. This activism was by no means new 

in East Los Angeles. Home of the 1968 East Los Angeles School Walkouts (Solór-

zano & Delgado Bernal, 2001), the community’s historical and present-day strug-

gles for educational justice laid a significant and meaningful historical and cultural 

foundation for the new school. I had hoped to teach in a public school at a time 

when few jobs were available in public schools, so I felt fortunate for the opportuni-

ty to teach in this school, fought for by Latin@ students, families, and community 

organizations. I believed that our mathematics classroom community could attempt 

to learn from and draw on the historical legacy of social justice efforts by and for 

the community. 

The Algebra I class I chose to study for this investigation consisted of stu-

dents who took and had previously “failed” (or were failed by) the course the prior 

http://innercitystruggle.org/


 

 

 

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Journal of Urban Mathematics Education Vol. 9, No. 2                                        131 

year as eighth graders in middle school, and mostly students who were not tracked 

into algebra in eighth grade at all—the highest track in the feeder middle schools 

being geometry for eighth graders. Because of this “low” placement, the students in 

this class were positioned as the least knowledgeable/capable students in the school. 

The textbooks in the feeder middle schools as well as the textbooks at the high 

school where I taught, like many traditional texts from large textbook publishing 

companies, marched through mathematics procedures and included a long list of 

problems for which students were expected to apply procedures, with a couple 

“critical thinking” word problems at the end of each section. The textbooks did not 

arrange the mathematics from an integrated mathematics perspective but rather as 

separated subjects: Algebra I, Geometry, Algebra II, Trigonometry/Pre-Calculus, 

and Calculus. The books did not include relevant, real-world, current or historicized 

issues. The content area covered in the Algebra I textbook, the same as the content 

covered on the high-stakes state exams, amounted to: properties of real numbers; 

solving, graphing, and writing linear equations and linear inequalities; systems of 

equations and inequalities; exponents and exponential functions; quadratics; poly-

nomials; and rational equations and functions. 

I believed this class was a good fit to practice YPAR because I hoped to pro-

vide the space for students to get excited about mathematics, which, for most stu-

dents, had already become a despised school subject. For most students, this course 

was the first time they had access to Algebra I, which tends to be a gate-keeping 

course. While I hoped to integrate YPAR into multiple class periods in the same 

school, I recognized as I began to plan the introduction of the unit that I did not feel 

prepared to facilitate multiple different action-research projects at once, so I chose 

one class period of Algebra I. 

  

Data Collection and Analysis 
 

Data sources included: 

 

 My teaching journals, in which I reflected on my pedagogical choices 
and took note of student leadership, participation, presentations, and 

specific contributions students made in the class (I put student state-

ments I remembered verbatim in quotation marks); 

 Pre- and post-questionnaire (see Figure 1) with students on their beliefs 
about what it means to do research; 

 Math autobiographies students wrote at the beginning of the course as 
well as an end-of-course reflection on mathematics; and 

 Student artifacts, including a final paper the class collectively wrote on 
their YPAR study and a video based on their quantitative data analysis 

and a collection of photos of the school food. 



 

 

 

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Journal of Urban Mathematics Education Vol. 9, No. 2                                        132 

To analyze the data, I developed (and triangulated) a coding schema across 

the data sources. I took note of reoccurring themes as I taught throughout the school 

year, using the constant comparative method for data analysis (Bogdan & Biklen, 

1982). In this article, I discuss my pedagogical decisions and reflections on those 

decisions, incorporating some of the ways in which students engaged in the course 

and in the culminating YPAR project. 
 

 

 

Figure 1. Pre- and post-questionnaire about research. 

 
Developing Foundations for Transformational Resistance 

 

Beginning the Algebra I Course 
 

Joining other mathematics educators across the nation, I attempted to create a 

social justice mathematics class to provide the space for students to feel empowered 

to read and write the world with mathematics (Freire, 1970/2007; Gutstein, 2006). 

From the first day of school, I sought to lay the foundations to critique societal op-

pression and explore possibilities for social justice within my classroom. The social 

issue-related units and ultimately the YPAR project I facilitated in the classroom 

did not occur in a vacuum, but rather surfaced out of practices I had used and activi-

ties students had engaged in at the beginning of the school year. 

Just prior to asking students to share more detailed information about them-

selves to me in a student information sheet (see Appendix A), I briefly introduced 

myself and my history, opening up to students as a person. First, I told them about 

my name, Mary Candace. Mary is my grandmother’s name and Candace was her 

 

Name:     Date:     Period:______________ 

 
Research Questionnaire – Explain all your answers 
 

1. What is research? Give your own definition! 
 

2. Give an example of research. 
 

3. What are the different steps of research? (Make a guess if you’re not sure! Come up with at 
least four steps.) 

 
4. Who does research in our society? 

 
5. What skills do you think a researcher needs? Do you have any of those skills? 

 
6. Do you think research is important for society? Why or why not? 

 



 

 

 

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Journal of Urban Mathematics Education Vol. 9, No. 2                                        133 

sister’s, or my great aunt’s name. I go by “Ms. Candace” with students because of 

the kind of person my great aunt was. She suffered a heart condition and passed at a 

young age. Throughout her life, she devoted herself to the happiness of others and 

to supporting people with what they needed. For example, she always remembered 

everyone’s birthdays and made elaborate cakes. After being diagnosed with her 

heart condition, she started a chapter of an organization in Buffalo, New York 

called Mended Hearts (see http://mendedhearts.org), which brought together pa-

tients who had previously undergone heart surgery and patients who were about to 

go through it. The goal was to have conversations that may ease fear before experi-

encing the surgery. I told students that I hoped to bring my great aunt’s spirit with 

me to guide me in my teaching, and that I will always remember and celebrate each 

of their birthdays in honor of her. 

I told students a story of taking Algebra I at a Title I middle school in eighth 

grade and getting As, but when my parents transferred me to a high school out of 

our neighborhood, I got an 11% on the “how much of Algebra do you remember?” 

test on the first day of school. I remained in Geometry and did well, ultimately 

making it to Calculus, but doubted myself and had always felt inferior to the other 

students at school because of that initial test. I told another story of intending to ma-

jor in statistics in college but barely passing the first upper-division course because 

I was intimidated by what I perceived as the cut-throat, competitive nature of the 

class. I also felt I was at a disadvantage because I was one of only a few women 

enrolled in the course. I shared with the students that my experiences do not mean 

that I understand their experiences—acknowledging that the students have a wide 

variety of experiences with mathematics. I also recognized that although I, as a 

White person from a middle class background, have benefited from many privileg-

es, I could, to certain extents, relate to feeling disempowered in mathematics as well 

as empowered. I asserted that to push back on disempowerment in mathematics, we 

must co-create a space in which we collaborate to build a beloved community. 

In “Letter from a Birmingham Jail,” Dr. Martin Luther King, Jr. (1963) wrote: 

“Injustice anywhere is a threat to justice everywhere. We are caught in an inescapa-

ble network of mutuality, tied in a single garment of destiny. Whatever affects one 

directly, affects all indirectly” (p. 2). I first learned of Dr. King’s concept of the be-

loved community as applied to the classroom when I was an undergraduate at the 

University of California, Berkeley and took a course entitled “June Jordan’s Poetry 

for the People” in which we read and wrote poetry on systemic oppression, re-

sistance, humanization, and liberation. I understood building a beloved community 

in the classroom to mean developing a space in which both the students and the 

teacher see the humanity in one another as they work toward a more socially just 

world. I told my students that each of them is each other’s greatest asset for learn-

ing, for making it to graduation and beyond, and for changing the world—that they 

are connected to and dependent on each other. 

http://mendedhearts.org/


 

 

 

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During the first week of class, I facilitated class dialogues in which students 

declared their rights in the mathematics classroom, the demands they have of them-

selves and each other, and the demands they have of me as their teacher (see Ap-

pendix B). I told students that I am a teacher because I believe they will be the ones 

to change the world. I also told students that I would try to make the class center 

around their own self-improvement and building confidence in mathematics as we 

use mathematics to understand and change the world. 

I then provided the syllabus to the class—the title of the course matched what 

I told students it would be about: “Viewing and Changing the World Through 

Mathematics.” Underneath the title, I placed a picture of a mural in the housing pro-

jects of East Los Angeles,1 as Gutstein (2006) writes about teaching about after he 

read an article of Marilyn Frankenstein’s (1997) that included a photo of the mural. 

Some of the students in our classroom lived in this housing project, so I felt it was 

especially relevant. Alongside Che Guevara is the message: “We are not a minori-

ty!!” I then facilitated a scaffolded class discussion, where students shared how 

they, as People of Color, are not minorities—according to the mathematical defini-

tion and because they are not “less than” other people. I also began with a Math 

Autobiography writing assignment (cf., Peterson, 2013), asking students to write 

me a letter telling me their stories (see Appendix C). I structured the assignment 

with many questions about their past experiences with school in general and math-

ematics specifically, and why they feel mathematics is important to learn. The most 

common response to the latter question: “We need math to count change at the gro-

cery store.” Their responses motivated me to want to expose the students to how 

powerful a tool mathematics can be for understanding racial, social, and economic 

injustice in education, health, incarceration, and so on, and for constructing argu-

ments to fight for justice through mathematics. I explained that certainly mathemat-

ics is important and essential for everyday calculations, but that I firmly believe 

students have the power to use mathematics in ways that connect more deeply to 

their lives. My role was to provide them the support and context for this learning. 

One of the first activities I implemented with students was an “ICEbreaker” 

similar to one from my teacher education program. Students wrote down on an in-

dex card three “variables” about themselves: I = an interest they have, C = a charac-

teristic or personality trait about themselves, and E = a unique event or story from 

their past. The whole class stood up as I began to read aloud a card. Students re-

mained standing until I read all three statements, and they guessed, from the group 

who was left standing, the person to whom the card belonged. Students were excit-

ed to learn about each other’s “variables.” This activity built community by getting 

to know each other. 

                                                 
1 See http://www.muralconservancy.org/murals/we-are-not-minority. 

http://www.muralconservancy.org/murals/we-are-not-minority


 

 

 

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As a pre-service teacher, I dreamed of creating an Algebra I course that con-

sisted only of social issue-related and other real-world units. As I entered the class-

room, I began to more fully understand the pressures on teachers to teach all of the 

content standards that Bacon (2012) and Gregson (2013) detail in case studies of 

social justice mathematics teaching. For Algebra I, this includes a long list of many 

fundamental concepts necessary to accessing the “rest” of mathematics. These pres-

sures come from a multitude of directions and, in my case, included:  

 

 “value-added” measures imposed by the school district that rate teachers 
based on student test score improvement,  

 standardized tests such as the high school exit exam, and  

 administrators that put pressure on teachers for students to perform “or else” 
(see Gutiérrez, 2013 for many other examples). 

  

I realized that, while I would not compromise my plan to teach social-issue related 

units, I would have to create them in a way that was strategic, so that the activities I 

designed addressed a variety of content standards in a rigorous enough way to ad-

dress these demands. I believed that covering content standards and teaching social 

justice mathematics did not have to be mutually exclusive; however, I had not yet 

conceived how I could tie much of the mathematical content to real-world contexts. 

Across all mathematics lessons, I sought to draw on culturally relevant ap-

proaches, which I knew would require me to change the culture of my classroom to 

be different than how mathematics classes looked like for me as a student. A daily 

pattern of whole class instruction where students follow along passively, copying 

problems the teacher solves, and then working on a set of similar problems alone 

following the lecture does not call on students to communicate almost at all orally 

or build on each other’s ideas (Tate, 1995). In my classroom, I worked toward sup-

porting students to discover concepts in mathematics (as opposed to teaching pro-

cedures) and having students work in groups collaboratively to validate and build 

on the knowledge of one another (including seating the students in small circle 

groups). This classroom set up assisted me in providing the space to meaningfully 

connect mathematics and social justice issues whenever possible. 

 

Teaching Mathematics about, with, and for Social Justice 
 

One of the first tasks in Algebra I is to review computation and the order of 

operations. Students are expected to have mastered fractions prior to taking the 

course, and this often can be students’ least favorite element of a mathematics prob-

lem. I thought about how I could re-introduce fractions and start off my class with 

real-world connections that would show students how important fractions can be. I 



 

 

 

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Journal of Urban Mathematics Education Vol. 9, No. 2                                        136 

designed a lesson using the video If the World Were 100 People2 (see Appendix D), 

which students and I viewed together. In the video, statistics report that if the world 

was shrunk down to 100 people, for example, 12 people would have a computer 

and 21 would live on less than $1.25 per day. Before watching the video, I asked 

the students to guess what they thought the numbers would be for all of the statis-

tics, and, while watching the video, they then recorded the data. Some students 

were shocked at the differences between their guesses and the actually reported sta-

tistical data. 

Following this activity, I asked students to write the data as fractions out of 

100 (e.g., 12/100), then reduce the fraction, if possible, write it as a decimal, and 

write it as a percent. We discussed the importance of being able to do so when mak-

ing arguments in different contexts; that it can be powerful to express parts of a 

whole in different ways.3 For homework that night, I gave students a chart entitled 

“If East L.A. Were 100 People,” with data I had taken from the census (we 

acknowledged and problematized that it often does not include people who are un-

documented), and their task was to find the fraction, decimal, and percent equiva-

lents and then write concluding observation sentences about what they noticed. My 

goal was for students to gain confidence in mathematics as they read the mathemat-

ical world around them. Some students, accustomed to more traditional courses and 

skeptical of change, wondered out loud, “Why are we talking about community in 

math class?” 

Early in the Algebra I course, it is typical to study inequalities, and I seized 

the opportunity to plan a unit that connected the way we discuss inequalities in 

mathematics with inequalities (or inequities) in society (see Appendix E). To get a 

stronger sense of what issues students were feeling particularly interested in, I pre-

sented them with several graphs relating to topics such as race and incarceration, 

incomes of people with and without disabilities, child poverty before and after eco-

nomic recessions, and health vs. wealth. In teams, students chose a graph to study 

as the starting point in their Inequality Project. They answered several questions 

about the graph (e.g., questions designed to invite a range of participation from all 

group members, such as what stands out to them the most) and wrote out mathe-

matical statements of inequality, using less than, greater than, less than or equal to, 

and greater than or equal to—using variables and numbers—in ways that were 

meaningful to them. Following this activity, students did additional background re-

search on that inequality, created a poster, and presented findings to the class, in-

                                                 
2 See http://www.miniature-earth.com; the video is based on the book If the World Were a Village: A 

Book about the World’s People (Smith, 2011). 

 
3 This was a brief moment in the lesson that I could have elaborated on more, by, for example, call-

ing on students to identify instances of how parts of a whole have been communicated in the media 

and speculating together why they were communicated in such a manner. 

http://www.miniature-earth.com/


 

 

 

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Journal of Urban Mathematics Education Vol. 9, No. 2                                        137 

cluding questions that arose as they explored the topic. One of the students, Rob-

erto, who was having challenges in most classes because of issues outside of 

school, spoke during this presentation. At the moment that he began to break down 

the importance of looking at percent difference as opposed to numerical difference 

in the context of racial underrepresentation and racial overrepresentation in prisons, 

the principal walked in to our classroom. She asked him a question, then another, 

and another. This ninth grader, whom she had only seen in her office for misbehav-

ior, confidently addressed all her questions related to this inequality and why it was 

an important one to understand. Following his presentation, he expressed that he 

felt validated as an intellectual; that he had something to say about social issues and 

mathematics. 

My last example of a social justice mathematics lesson is on the topic of 

slope. Often, textbooks and traditional curricular materials introduce slope as being 

equal to (y2 – y1) / (x2 – x1). This formula can be challenging for students to under-

stand, especially if not introduced to the conceptual meaning of slope. I do not ar-

gue that students should never be introduced to such a formula. But rather, when 

they are, it should come after interacting with slope in more meaningful and con-

ceptual ways so that students can understand that slope captures how much one var-

iable changes with respect to another. Without mentioning the word “slope” in 

class, I presented two graphs to students of data with almost linear relationships, the 

first being a graph of asthma rates over time in a California city and the other fami-

ly income vs. student SAT math scores. We discussed the first graph together as a 

class and the students studied the second graph together in groups. I asked students 

to share everything they noticed about the graphs. Then, I asked students to focus 

on the x-variable (horizontal axis) and then on the y-variable (vertical axis), for each 

identifying how much that variable changes from one point to another point. Next, I 

asked students to write this ratio out as a sentence (e.g., For every $20,000 more a 

family makes, the average student’s SAT math score is higher by 14 points). After 

students identified this relationship, I said that we call this relationship “slope.” For 

many students who had already taken Algebra I in eighth grade and “failed” (or 

were failed) they responded with statements, such as: “Oh! Why didn’t they just tell 

us that before?!” or “That’s it!? Man I just couldn’t remember those formulas!” Af-

ter students saw real-world context examples of slope, in subsequent exercises the 

majority of students excelled at finding and interpreting Δy/Δx as they discussed 

the meaning of a graph’s slope. I saw ways in which I believed students were striv-

ing to “read the world” with mathematics in my classroom. In addition to sharing 

their (our) learning on social issues, how could I support them to further “write the 

world” with mathematics? 

 

 



 

 

 

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Journal of Urban Mathematics Education Vol. 9, No. 2                                        138 

Developing Transformational Resistance and Critical Mathematical 

Literacy through Youth Participatory Action Research 
 

Thinking of how to introduce the YPAR unit, I returned to an article I had in-

troduced to students earlier that year: Solórzano and Delgado Bernal’s 2001 germi-

nal article on transformational resistance. I had used the article earlier to introduce 

the Cartesian coordinate plane (see Figure 2). Students are often introduced to the 

coordinate plane as an abstraction, and plotting points becomes a mechanical pro-

cedure without meaning (e.g., 5 over and 2 down). I had remembered that Solórza-

no and Delgado Bernal’s article contained a quadrant showing four types of re-

sistance, each quadrant representing the presence or absence of a variable, x – moti-

vation by social justice, and y – critique of societal oppression. I put blue painters’ 

tape on the floor of the classroom to make a coordinate plane, asking students to 

move about it representing the presence or absence of two variables (first starting 

with variables such as their preferences on two different sports rivalries, and then 

moving to examples of high school student resistance that students could relate to, 

mapping them out on the coordinate plane according to Solórzano and Delgado 

Bernal’s conceptualization of resistance). 

  

 

 

 

 

 

 

 

 

 

 

 

 

 

 

Figure 2. Defining the concept of resistance. 
 

From “Examining Transformational Resistance Through a Critical Race and LatCrit Theory Frame-

work: Chicana and Chicano Students in an Urban Context,” by D. Solórzano and D. Delgado Bernal, 

Urban Education, 36(3), p. 318. Copyright © 2001 by Corwin Press, Inc. Reprinted by permission of 

SAGE Publications, Inc. 

 

To kick off the YPAR project, I invited Professor Solórzano to come to my 

classroom and speak to the students about transformational resistance (my contact 

 



 

 

 

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Journal of Urban Mathematics Education Vol. 9, No. 2                                        139 

with him and his class visit are recounted in Solórzano, 2013). Professor Solórzano 

shared with the class examples of transformational resistance and specifically spoke 

about the ethnic studies ban in Arizona and upcoming film Precious Knowledge 

(McGinnis & Palos, 2011). The students were energized following his presentation 

and excited to engage in action-research themselves. 

The students chose to study school food injustice, as health injustice related to 

race and class. They were passionate about this topic following the inequalities pro-

ject. Before we dove into designing the study, we watched the film Unnatural 

Causes (Adelman, 2008), which weaves together biology, public health, sociolo-

gy—and even mathematics, with data and graphs throughout—to understand how 

wealth disparities lead to poorer health. Students chose to look at school food be-

cause: (a) it affects them every day, and the district had recently changed the food 

in such a that they were unpleased; and (b) after intense class debates about how to 

make change and what it means to be a leader, students felt that they had a realistic 

chance of making some concrete changes on this issue. 

As we embarked on the study design, students piloted survey questions with 

peers in other classes before refining a survey protocol, asking their peers to talk 

through how they understood each question and what should be modified for clarity 

or added. Additionally, during lunchtime in the first couple weeks of the project, 

students talked with their peers and took pictures of school food to deepen their un-

derstandings of the student body’s greatest concerns. They also shared stories in 

class of their own experiences with school food. While I guided students toward a 

school-wide survey so that we might analyze large-scale quantitative data, we dis-

cussed strengths and weaknesses of quantitative and qualitative research. The in-

formal conversations students led with their peers and the photo element of the in-

vestigation gave them a sense of various research methods (e.g. interviews, photo 

voice) and how the stories behind numbers are necessary to uncover what they want 

to know. That said, I acknowledge that in the spirit of YPAR it is problematic to 

point youth in particular directions, but I chose to make the exception of guiding 

them toward quantitative investigation, while still highlighting the limits of doing 

so, because of my desire to integrate YPAR in the mathematics class. 

The class then designed and implemented a school-wide survey with closed-

ended and open-ended questions on the school food as well as demographic infor-

mation, which they administered to over 400 of their peers. Students analyzed the 

survey data and created graphs using Microsoft Excel, which they had not used be-

fore, and presented their findings to school food officials. In each phase of the ac-

tion research, different student facilitators led the class (after I had a planning meet-

ing with them on facilitating for that particular class segment). 

In summary, the class had five findings: (a) students overwhelmingly gave the 

school food the lowest rating; (b) the predominant reason students reported eating 

the school food was because they were hungry and did not have other options; (c) 



 

 

 

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Journal of Urban Mathematics Education Vol. 9, No. 2                                        140 

students had a desire for all components of the school lunch to be tastier, healthier, 

and in larger portions; (d) students wanted to exercise more choice in their meal 

options; (e) and all but eight students surveyed said they received “lunch tickets,” 

meaning they qualified for free lunch. One of the biggest shifts with respect to 

mathematics I observed was students’ use of mathematical discourse as they com-

municated with one another (and me) while entering, analyzing, and displaying 

their data. For example, students were regularly using the terms such as variables 

(as described in the anecdote in the introduction of this article), relationship, corre-

lation, x-axis, y-axis, coordinate, data point, pattern, outliers, respondents, bar 

graphs, pie graphs, frequency, intervals, best-fit line, mode, mean, range. Prior to 

the YPAR unit, we covered linear equations beginning with the investigation of 

slope (as previously discussed). I had hoped that more students would apply the al-

gebraic concepts behind linear equations as they engaged in this research, but few 

did, due to, I believe, a lack of support on my behalf. I would have liked to have 

done more, and at the same time I made the choice not to push certain aspects of the 

mathematics, assessing that students were gaining non-algebraic, statistical skills 

and ways of thinking and confidence in their participation as students in mathemat-

ics class. 

Following analysis and writing a summary research report as a class, the stu-

dents called for a meeting with the cafeteria manager to share their research find-

ings and ask about the school lunch program. They concluded with recommenda-

tions to have daily comment cards available for all students so as to quickly give 

feedback on the food (and for these comments to make their way to those who pre-

pare the food); to “change our menu into food that helps us be healthy—food that 

does not have an exaggerated amount of grease, fat, sugar, etc. so we can adapt to 

the habitat [sic] of being able to eat healthy”; to offer larger portions; to include 

more fruit and vegetable options; to offer water and fewer sugary drinks; to distrib-

ute a monthly menu; and to eliminate the lunch tickets given that almost the entire 

student body qualified for them. 

As other practitioner researchers striving to teach mathematics for social jus-

tice have observed, I believed that students were demonstrating more positive 

mathematical identities as they began to engage in the process of reading and writ-

ing the world with mathematics, solving rigorous problems, and building mathe-

matical literacy. In their math autobiographies at the end of the year, students’ 

views on the importance of mathematics and why we must learn it shifted from be-

ing important in specific situations and because it will be useful in the future to an 

understanding of mathematics being an important tool for viewing and changing the 

world around them. Most students wrote that they began to feel this way about 

mathematics as they came to believe they have the capacity to study and change 

their school, using mathematics.  



 

 

 

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Journal of Urban Mathematics Education Vol. 9, No. 2                                        141 

Returning to the story at the beginning of this article, students often made 

meaning with mathematics that they previously had not experienced. As students 

were creating representations of their data, another student, recognizing how data 

representations could help tell a powerful story, said: “Once they see our data, they 

will have to listen.” This statement demonstrates her perception of the power of 

critical mathematical literacy. Reflecting on her statement and similar statements by 

other students, I am glad that the students held firm beliefs in the power of their 

work to tell a story and demand attention and action. But I wish I had done more to 

create space to address the complexity of speaking their truth to systems of power, 

the struggle of working toward social justice for the long haul, and community or-

ganizing tactics for making change. Exploring such topics in the mathematics class-

room, highlighting the role of mathematics, statistics, and numeracy in organizing 

for change, would have been powerful. Students did begin to uncover the challeng-

es behind making change toward greater social justice after meeting with the 

school’s cafeteria manager and learning that decisions about school food were not 

local school decisions but rather large district-wide ones, and after meeting with the 

Healthy School Food Coalition4 and learning of persistent efforts by that organiza-

tion over time, in solidarity with students, to win actionable issues.  

Students also demonstrated a significant shift in their interpretation of the 

meaning of research. Before they engaged in YPAR, most students defined research 

as looking up a topic of choice online and did not view research as a process they 

could conduct by posing original questions and collecting data on a topic about 

which they were passionate. (Figure 3 provides students’ statements after the 

YPAR project.)  

Prior to the YPAR project, I hoped to lay a foundation in the classroom where 

our work would be motivated by social justice issues and to critique societal op-

pression. I do not believe working toward these goals in the YPAR project would 

have been possible had we not taken time to build community and participate in 

social justice lessons throughout the course. I observed that a motivation for social 

justice and a critique of societal oppression were built over time, especially when 

fostered within a subject like mathematics where the connections are not often 

made. Relating to the other forms of resistance Solórzano and Delgado Bernal 

(2001) discuss, too often students in mathematics class express “reactionary behav-

ior,” acting out against teachers and classmates without a critique of social, histori-

cal, or political factors influencing their behavior; or they engage in “self-defeating 

resistance,” understandably questioning the relevance of mathematics to their lives; 

or in “conformist resistance,” doing their work knowing that it will help them ac-

cess college but not challenging the abstract, procedural, or context-void teachings 

of mathematics. Critical pedagogy in mathematics can support more students to re-

                                                 
4  See http://www.oxy.edu/urban-environmental-policy-institute/programs/food/healthy-school-food-

coalition. 

http://www.oxy.edu/urban-environmental-policy-institute/programs/food/healthy-school-food-coalition
http://www.oxy.edu/urban-environmental-policy-institute/programs/food/healthy-school-food-coalition


 

 

 

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Journal of Urban Mathematics Education Vol. 9, No. 2                                        142 

sist in mathematics in transformative ways. During the YPAR project, students re-

sisted with both a motivation for social justice—to get tastier and healthier food for 

all at their school—and with a critique of societal oppression—that people of color 

and people living in poverty are often denied access to healthy food and many other 

benefits to overall health, and that school food should not exacerbate that inequity 

but rather fight against it. 

 

 

Figure 3. Student statements on the meaning of research after the YPAR project. 

 

After representations from the Healthy School Food Coalition visited our 

class, students wrote thank you notes to them. One student included the phrase 

“Victory will be ours!” on the cover of his note. Earlier in the project, this same 

student had been skeptical, questioning how students could really be school leaders 

who fight for change. Another student’s note read: 

 
I am so glad and I feel so supported by a group of adults that actually care about what 

we care about, which is the school food. I feel motivated to want to learn more about 

this and make a change knowing that no one else would do it, but the ones that care. I 

feel like we can really make a change as long as we keep on trying.  Thank you so 

much for hearing us out and listening to our thoughts and opinions. I really hope our 

work pays off in the end. I hope to stay in touch so that together we can also make a 

difference once we’ve done it at our school with the cafeteria manager first! 

 

 

 I have learned about research that when we do research it’s not only “copy, paste, and print,” we 
have to read it and understand it and do it. Research is to find the information you want on your 
own. 
 

 Research is to take time to look for information about something that you’re looking to uncover, to 
find facts and explanations about it. Anyone can do it as long as you know what you’re looking for. I 
learned that creating and giving surveys you can really collect a lot of information and different opin-
ions of many students. You get to learn what they think and feel on what you’re asking them. 

 
 There are explanations and steps to do research. Research means to find out something but more 

detailed, like getting to the bottom of it. 
 
 It is very hard to come up with a simple survey. It takes a lot of patience. First we came into teams 

to construct each category. Anyone can make a survey, just takes patience and research about the 
topic of the survey. What I learned is that you could get a lot of info in a couple simple questions, 
and we worked days on a survey and people finish it in minutes. 
 

 We can use research to find out patterns of info for the surveys. 
  
 To find out all of the information and put the information together and analyze and understand it. 



 

 

 

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Journal of Urban Mathematics Education Vol. 9, No. 2                                        143 

Discussion 
 

In this article, I aimed to contribute to scholarship that imagines, builds, and 

investigates spaces where critical mathematical literacy and social action are inter-

twined from the perspective that the work of engaging in critical praxis is a lifelong 

process. As Sleeter (2015) and Ladson-Billings (2015) contend, scholar-activism 

not only conceptualizes possibilities of teaching for social justice within inequitable 

schooling contexts but also works to alter such contexts. Questions that arose for 

me in reflecting on this YPAR practitioner research are: How can schools and 

teacher education be altered to foster social justice mathematics? How can social 

justice mathematics itself be a part of pushing for change to challenge structural 

inequities that persist within and outside of mathematics education? What role does 

or can critical mathematical literacy have in developing “justice-oriented citizens” 

(Westheimer & Kahne, 2004) who engage in transformational resistance as they 

envision and lead social movement? 

This investigation sheds light on the promise of YPAR in the mathematics 

classroom to open up spaces for students to develop as subjects of transformation as 

one avenue of teaching mathematics about, with, and for social justice (cf. Stinson 

& Wager, 2012). School change efforts and research can further explore the expan-

sion of YPAR as a normalized part of students’ learning experience at school and 

the multiple critical literacies students can build as they engage in research and cre-

ate change. Westheimer and Kahne (2004) argue that one way schools can teach for 

democracy is to develop students as community activists who analyze root causes 

of societal inequities and explore how human rights and social justice can be 

achieved as a result of collective action. Critical pedagogy can be supplemented 

with “strategies used by community and education organizers” (Anyon, 2005, p. 

179). Critical mathematics teachers and their students who engage in YPAR can be 

positioned as mentors to pre-service teachers and, in teacher education, teachers can 

learn how to form educational justice-oriented groups with other teachers, such as 

critical inquiry groups (Nieto, Gordon, & Yearwood, 2010) and Nepantla circles 

(Gutiérrez, 2012). 

While YPAR in the mathematics classroom has the potential to open up space 

for students to write the world (the action in action-research can be thought of as 

writing the world), there are a multitude of ways in which young people can write 

the world with mathematics that can occur within or outside the context of YPAR 

(e.g., [re]defining what it means to do mathematics such as bringing in cultural 

practice to mathematics, creating texts and media, sharing work with family and 

peers), and YPAR itself does not demand particular actions. Future research can 

capture a variety of ways in which young people can develop transformative re-

sistance through or drawing on mathematics and continue to question the possibili-

ties for and extent to which YPAR and transformational resistance can be fostered 



 

 

 

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Journal of Urban Mathematics Education Vol. 9, No. 2                                        144 

within the classroom walls—within school, district, and larger social-political con-

strains that often run counter to the spirit of YPAR. Because I guided students to-

ward quantitative investigation, placed a time limit on the project, and did not cover 

some of the “dominant mathematics” concepts I was supposed to address according 

to the content standards (polynomials and rational equations and functions), I need 

to complicate my own claims about YPAR and transformational resistance in the 

mathematics classroom. These are all areas I would strive to improve on, think 

harder about, and talk with others about before future implementations. 

As studies by Terry (2011) and Yang (2009) do, future research can also in-

clude in-depth examinations of how students demonstrate their learning of mathe-

matics in the context of YPAR and following their engagement with YPAR, as well 

as the connection between students’ mathematics learning and mathematical identi-

ties. I do not link students’ mathematical identities to their mathematical perfor-

mance in terms of performance on tests or success with future mathematics access. 

In one sense, I believe this is a limitation of the study. At the same time, I argue that 

placing high value on and focusing in on how students perceive mathematics and 

how students perceive research in the context of participating in YPAR are just as 

important areas of focus for research as other conceptions of what it means for stu-

dents to “perform” mathematically in the context of YPAR or social issue-related 

learning. 

Pushing for change in schools and teacher education can foster environments 

where social justice mathematics can grow and, in turn, YPAR connected to quanti-

tative inquiry can work toward creating change itself. As Stinson (2014) asserts, in 

times of great societal injustices and large-scale organizing against such injustices 

(e.g., the Black Lives Matter and Occupy Wall Street movements), we can call on 

mathematics education to contribute in greater ways to understanding and changing 

our society. 

 
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Appendix A 

Student Information Sheet 
 

 

Student Information Sheet  

 
My full name is:     I prefer to be called / nickname: 

 

My birthday is (Month Date, Year):  Gender pronouns: 

 

Do you need to sit near the front of the room to hear or see better?  

   

My home phone number is:      

 

Family member’s name and their relationship to you (mom, tío, etc.): 

           

The music I like to listen to is:  

 

The foods I like to eat are: 

 

The language(s) I speak at home is/are: 

 

I am talented at: 

 

I am from: 

 

I am: 

 

I would like to get better at: 

 

I come to school because: 

 

In the future, I would like to: 

 

In the past, I have had good experiences in school when: 

 

I have had bad experiences in school when: 

 

Something that gets on my nerves is: 

 

Something I would like Ms. Candace to know about me is: 

 

I would like to change the world by: 

 

The questions I have about this class are: 

 

Thank you for filling this out! I look forward to  
getting to know more about you! 

 



 

 

 

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Journal of Urban Mathematics Education Vol. 9, No. 2                                        149 

Appendix B 

Declared Students’ Rights 

 
 



 

 

 

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Journal of Urban Mathematics Education Vol. 9, No. 2                                        150 

Appendix C 

Mathematics Autobiography 
 

 

 

 

 
 

Use the following guidelines to write a six-paragraph letter to me explaining your her/history and 

experience with mathematics. This letter is an opportunity for you to explore your identity as a math 

student (and growing mathematician!). Please neatly write or type your final letter. Stick to the letter 

format as shown below, and indent for every paragraph. 

 

August   ,   

 

Dear Ms. Candace: 

 

Paragraph 1: My name is    .  I am    years-old, and I am a  

 th grader at [our school name]. Add a few more sentences about yourself here! 

 

Paragraph 2:  What are your strengths and weaknesses as a student? For example, strengths 

are things you’re good at, part of your personality that you are proud of, things people compliment 

you on, and so on. Weaknesses are areas where you want to learn more, get stronger, places where 

you struggle as a student, and so on. 

 

Paragraph 3:  What do you think about math? Do you like/love/enjoy math? Why or why 

not? Explain. 

 

Paragraph 4:  What have your math classes been like in the past? How did the last school 

year of math go for you? Do not only write about your grades but your experiences learning and with 

your teacher. 

 

Paragraph 5:  Why do you think math is important for you to learn? Think of all the reasons 

you can. Do you believe that math can be used to understand and change the world? Why or why 

not? 

 

Paragraph 6:  What are your goals for math class this school year? List all of them and ex-

plain why you are reaching for those goals. Explain who will help you to reach your goals. 

 

Include anything else at the end of the letter that you would like to include. 

 

Sincerely / Peace / Your student (pick one!), 

 

     

(Your signature)  

 

 

 



 

 

 

Raygoza                                              Transformational Resistance in Mathematics  

 

 

 

Journal of Urban Mathematics Education Vol. 9, No. 2                                        151 

Appendix D 

Work Sheet – If The World Were 100 People  

 
 

NAME:      DATE:    PERIOD:   

 

If we could turn the population of the earth into a small community of 100 people, keeping the same 

proportions we have today, the village would look something like this …   

 

# of people who … 
Your 

Guess 

The 

Data 

Fraction 

(out of 

100) 

Reduce  

Fraction 

(If you 

can) 

Decimal Percent 

are Asian  61 61/100 61/100 0.61 61% 

are European  12 12/100 3/25 0.12 12% 

are North American  8     

are South American/Caribbean  5     

are African  13     

are Oceanian  1     

are women  50     

are men  50     

live in urban areas  47     

are disabled  12     

are Christians  33     

are Muslims  21     

are Hindus  13     

are Buddhists  6     

are Sikhs  1     

are Jews  1     

are non-religious  11     

practice other religions  11     

are Atheists  3     

live without basic sanitation  43     

live without an improved water source  18     

own 75% of the entire world income  20     

are hungry or malnourished  14     

can’t read  12     

have a computer  12     

have an internet connection  8     

lives with HIV/AIDS  1     

live on less than $1.25 per day  21     

 

 

 

 

 

 

 

 



 

 

 

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Journal of Urban Mathematics Education Vol. 9, No. 2                                        152 

Appendix E 

Inequalities in Society