On August 1st, middle school students participated in a structured inquiry lab that investigated fermentation in yeast under varying environmental conditions. Through this lab, students developed a foundational understanding of chemical reactions in living organisms and how matter is transformed—not created or destroyed. 

In my 7th grade life science classroom, one concept resurfaces: the cycling of matter. Whether we are exploring photosynthesis, cellular respiration, the phosphorus or nitrogen cycles, or the role of decomposers, my students are constantly encountering examples of how matter moves through ecosystems. Even the simple fact that all living organisms exchange gases with their environment reinforces the law of conservation of matter. This principle—deeply rooted in physics—is foundational to truly understanding biology.

Understanding how scientists live and work connects students to science. Students can envision themselves as scientists when they relate to  similar aspects they share with a scientist. Personal stories of scientists, including where they are from and the possible struggles they faced, humanizes them and allows students to see themselves in their role. 

An engaging, student-guided scientific experiment with minimal materials and space is with marbles, a timer, and a ruler. Students test how different surfaces affect the momentum of a marble. Students roll a marble across three surfaces, such as concrete, carpet, wood, and school floors, and time how fast it moves across a four-foot distance. To draw accurate conclusions, students should repeat the experiment for each surface three times as well as complete trials with a large marble in order to discover trends. A phone video may get more accurate timing and be worth comparing the time to a person physically pushing a timer twice for each trial (at the start and end); the marbles complete the paths in under two seconds.

On a middle-school STEM team, problem-based learning should occur in social studies, language arts, math, and science. Problem-based learning can be a part of your pedagogy for individual lessons. Also, some teachers incorporate mini-PBL units. For example, the language arts teacher on my team had student groups make a podcast; it went so well that our team did another podcast in May, bringing excitement at the end of the school year. Students loved that creative outlet!  It is ideal to incorporate science, technology, engineering, or math in any problem-based learning lesson or unit. Technology has been easier and easier to implement as my district as Adobe Express for students. Any lesson with creativity or art can be morphed into a graphic-design technology product. 

On August 1st, middle school students participated in a structured inquiry lab that investigated fermentation in yeast under varying environmental conditions. Through this lab, students developed a foundational understanding of chemical reactions in living organisms and how matter is transformed—not created or destroyed. 

In my 7th grade life science classroom, one concept resurfaces: the cycling of matter. Whether we are exploring photosynthesis, cellular respiration, the phosphorus or nitrogen cycles, or the role of decomposers, my students are constantly encountering examples of how matter moves through ecosystems. Even the simple fact that all living organisms exchange gases with their environment reinforces the law of conservation of matter. This principle—deeply rooted in physics—is foundational to truly understanding biology.

Understanding how scientists live and work connects students to science. Students can envision themselves as scientists when they relate to  similar aspects they share with a scientist. Personal stories of scientists, including where they are from and the possible struggles they faced, humanizes them and allows students to see themselves in their role. 

An engaging, student-guided scientific experiment with minimal materials and space is with marbles, a timer, and a ruler. Students test how different surfaces affect the momentum of a marble. Students roll a marble across three surfaces, such as concrete, carpet, wood, and school floors, and time how fast it moves across a four-foot distance. To draw accurate conclusions, students should repeat the experiment for each surface three times as well as complete trials with a large marble in order to discover trends. A phone video may get more accurate timing and be worth comparing the time to a person physically pushing a timer twice for each trial (at the start and end); the marbles complete the paths in under two seconds.

On a middle-school STEM team, problem-based learning should occur in social studies, language arts, math, and science. Problem-based learning can be a part of your pedagogy for individual lessons. Also, some teachers incorporate mini-PBL units. For example, the language arts teacher on my team had student groups make a podcast; it went so well that our team did another podcast in May, bringing excitement at the end of the school year. Students loved that creative outlet!  It is ideal to incorporate science, technology, engineering, or math in any problem-based learning lesson or unit. Technology has been easier and easier to implement as my district as Adobe Express for students. Any lesson with creativity or art can be morphed into a graphic-design technology product. 

On August 1st, middle school students participated in a structured inquiry lab that investigated fermentation in yeast under varying environmental conditions. Through this lab, students developed a foundational understanding of chemical reactions in living organisms and how matter is transformed—not created or destroyed. 

In my 7th grade life science classroom, one concept resurfaces: the cycling of matter. Whether we are exploring photosynthesis, cellular respiration, the phosphorus or nitrogen cycles, or the role of decomposers, my students are constantly encountering examples of how matter moves through ecosystems. Even the simple fact that all living organisms exchange gases with their environment reinforces the law of conservation of matter. This principle—deeply rooted in physics—is foundational to truly understanding biology.

Understanding how scientists live and work connects students to science. Students can envision themselves as scientists when they relate to  similar aspects they share with a scientist. Personal stories of scientists, including where they are from and the possible struggles they faced, humanizes them and allows students to see themselves in their role. 

An engaging, student-guided scientific experiment with minimal materials and space is with marbles, a timer, and a ruler. Students test how different surfaces affect the momentum of a marble. Students roll a marble across three surfaces, such as concrete, carpet, wood, and school floors, and time how fast it moves across a four-foot distance. To draw accurate conclusions, students should repeat the experiment for each surface three times as well as complete trials with a large marble in order to discover trends. A phone video may get more accurate timing and be worth comparing the time to a person physically pushing a timer twice for each trial (at the start and end); the marbles complete the paths in under two seconds.

On a middle-school STEM team, problem-based learning should occur in social studies, language arts, math, and science. Problem-based learning can be a part of your pedagogy for individual lessons. Also, some teachers incorporate mini-PBL units. For example, the language arts teacher on my team had student groups make a podcast; it went so well that our team did another podcast in May, bringing excitement at the end of the school year. Students loved that creative outlet!  It is ideal to incorporate science, technology, engineering, or math in any problem-based learning lesson or unit. Technology has been easier and easier to implement as my district as Adobe Express for students. Any lesson with creativity or art can be morphed into a graphic-design technology product.