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Mindset Mathematics: Visualizing and Investigating Big Ideas, Grade 7
Jo Boaler, Jen Munson, Cathy Williams
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eBook - ePub
Mindset Mathematics: Visualizing and Investigating Big Ideas, Grade 7
Jo Boaler, Jen Munson, Cathy Williams
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Engage students in mathematics using growth mindset techniques
The most challenging parts of teaching mathematics are engaging students and helping them understand the connections between mathematics concepts. In this volume, you'll find a collection of low floor, high ceiling tasks that will help you do just that, by looking at the big ideas at the seventh-grade level through visualization, play, and investigation.
During their work with tens of thousands of teachers, authors Jo Boaler, Jen Munson, and Cathy Williams heard the same message—that they want to incorporate more brain science into their math instruction, but they need guidance in the techniques that work best to get across the concepts they needed to teach. So the authors designed Mindset Mathematics around the principle of active student engagement, with tasks that reflect the latest brain science on learning. Open, creative, and visual math tasks have been shown to improve student test scores, and more importantly change their relationship with mathematics and start believing in their own potential. The tasks in Mindset Mathematics reflect the lessons from brain science that:
- There is no such thing as a math person - anyone can learn mathematics to high levels.
- Mistakes, struggle and challenge are the most important times for brain growth.
- Speed is unimportant in mathematics.
- Mathematics is a visual and beautiful subject, and our brains want to think visually about mathematics.
With engaging questions, open-ended tasks, and four-color visuals that will help kids get excited about mathematics, Mindset Mathematics is organized around nine big ideas which emphasize the connections within the Common Core State Standards (CCSS) and can be used with any current curriculum.
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Información
BIG IDEA 1
Connecting 2D and 3D Worlds
Researchers have recently shown that when we work on a mathematics problem, five areas of the brain are involved, and two of them are visual pathways (Menon, 2015) (as I explained in the introduction to this book). Our brains are helped when we work visually; and when we connect visuals with numbers, important brain connections occur. In addition, other brain areas are involved when we touch, move things, and interact physically with mathematical ideas. The area of research concerning physical touch and movement is known as “embodied cognition,” and researchers in this field point out the importance of students' holding mathematical ideas in the motor and perceptual areas of the brain (Nemirovsky, Rasmussen, Sweeney, & Wawro, 2012), which comes about when they learn mathematical ideas through touch and movement. In this big idea, students are learning about the features of 3D shapes. This is an area that is particularly important to experience physically, as students will not develop a complete understanding of the mathematical features of shapes if they only see them in two-dimensional pictures in textbooks.
When we taught 83 middle school students a few summers ago, we invited them to build larger cubes out of sugar cubes. A year later, one of the students told me that he still remembers the meaning of “1 cubed” by recalling the feel and the features of the small cube he held in his hands. He told me that it was continuing to help him as he learned geometry. The three activities in this big idea give students a physical opportunity to hold objects in their hands and experience their different features.
In the Visualize activity, students are invited to slice 3D objects to make different two-dimensional shapes. Students will enjoy working with clay, and they will learn about the three-dimensional objects they hold in their hands as they touch and feel the dimensions. As they form the shapes and then sketch them, they will be able to make connections between areas of the brain that deal with physical touch and with drawing.
In the Play activity, students will get the opportunity to explore further with the objects they build out of clay. This activity also includes an element we design into tasks wherever possible—giving students choice. This is something that will increase their interest, which, in turn, will increase their learning and achievement.
Our Investigate activity poses questions that we hope will enable students to struggle, as that causes positive brain activity, and to extend their ideas to high levels. The questions have an openness that is rare in textbooks but that is important, as this openness enables students to develop their own ideas and to develop mathematical thinking in response to ill-defined problems of the type they will meet in the world outside school. We pose the following questions:
- How could you slice this solid so that the face that is made has the same area as the base?
- How could you slice it so that the shape has an area bigger than the base?
Both questions will give students opportunities to think deeply, to wonder about relationships, and to connect ideas.
Jo Boaler
References
- Menon, V. (2015). Salience network. In A. W. Toga (Ed.), Brain mapping: An encyclopedic reference (Vol. 2, pp. 597–611). San Diego, CA: Academic Press.
- Nemirovsky, R., Rasmussen, C., Sweeney, G., & Wawro, M. (2012). When the classroom floor becomes the complex plane: Addition and multiplication as ways of bodily navigation. Journal of the Learning Sciences, 21(2), 287–323. doi:10.1080/10508406.2011.611445
Seeing Slices
Snapshot
Students visualize and explore the two-dimensional shapes that can be made by slicing a rectangular solid.
Connection to CCSS
7.G.3
Agenda
| Activity | Time | Description/ Prompt | Materials |
| Launch | 10–15 min | Show students a rectangular solid made of clay, and then slice that solid on an angle. Without separating the pieces, ask student to predict what shape the face of the slice is. Discuss students' predictions, then reveal and discuss the shape of the face. |
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| Explore | 25–30 min | Small groups explore the question, What different two-dimensional shapes can you make by slicing a rectangular prism? Groups create a rectangular solid from clay and a net to match. Then groups use a cutting tool to slice and re-form the solid repeatedly to explore the shapes of the sliced faces. Students sketch the solid, how it was sliced, and the resulting face shape. |
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| Discuss | 15 min | Discuss the two-dimensional shapes students created by slicing their rectangular solids. Discuss patterns for creating rectangles, other quadrilaterals, or triangles. Ask, What shapes cannot be made? Why? | Optional: chart and markers |
To the Teacher
For this activity and the others in this big idea, we want students to have the chance to physically interact with three-dimensional figures and have the opportunity to slice them. To accomplish this, we recommend the use of clay to make the solids and dental floss for cutting. If you have an art department that has wire cutters for clay, those are even better. You may also try plastic knives, if you have those available. We like clay because it is stiff, and if you use a thin cutting tool, clay will maintain the shape of the slice better than play dough or other softer modelin...