In this module, students will practice answering a specific question about how climate change has affected the flowering date in American elm trees. After students learn to manipulate the elm data set, build graphs, and analyze the data with a regression, they can then practice on a species of their own interest. Students can then share their species' information with the class for a larger discussion about what types of species may be affected by climate change.

This activity is a field observation and also an in-class discussion/share. Students share observations made outside and are aware of changes in the natural world.

This classroom activity introduces the yearlong topic of phenology and how to use the Weatherguide calendar.

This resource was created by Sharla Hanzlik, in collaboration with Dawn DeTurk, Hannah Blomstedt, and Julie Albrecht, as part of ESU2's Integrating the Arts project. This project is a four year initiative focused on integrating arts into the core curriculum through teacher education, practice, and coaching.

This lesson is focused on the short-term cycling of carbon and is designed to put the processes of photosynthesis and respiration within a global perspective.

Got oxygen? Got food? Well, then you've got to have photosynthesis! This video will break down photosynthesis into the "photo" part (capturing light energy and storing it) and the "synthesis" part (fixing carbon into carbohydrates). It's all a bit complicated, but take a deep breath and let's find out where that oxygen comes from.

Short Description:
A second semester introductory physics course for life sciences students that looks to deepen students' understanding of biology and chemistry through physics all through the lens of understanding two of the most fundamental particles in the Universe: electrons and photons. The book begins with exploring the quantum mechanical nature of these objects to expand on what students have learned in chemistry and then proceeds to geometric optics (using the human eye as a theme), electrostatics (using membrane potentials), circuits (using the neuron), and finally synthesizing everything in a unit exploring the meaning of "light is an electromagnetic wave."

Long Description:
A second semester introductory physics course for life sciences students that looks to deepen students’ understanding of biology and chemistry through physics all through the lens of understanding two of the most fundamental particles in the Universe: electrons and photons. The book begins with exploring the quantum mechanical nature of these objects to expand on what students have learned in chemistry and then proceeds to geometric optics (using the human eye as a theme), electrostatics (using membrane potentials), circuits (using the neuron), and finally synthesizing everything in a unit exploring the meaning of “light is an electromagnetic wave.”

Word Count: 97595

ISBN: 978-1-945764-07-3

(Note: This resource's metadata has been created automatically by reformatting and/or combining the information that the author initially provided as part of a bulk import process.)

A second semester introductory physics course for life sciences students that looks to deepen students' understanding of biology and chemistry through physics all through the lens of understanding two of the most fundamental particles in the Universe: electrons and photons. The book begins with exploring the quantum mechanical nature of these objects to expand on what students have learned in chemistry and then proceeds to geometric optics (using the human eye as a theme), electrostatics (using membrane potentials), circuits (using the neuron), and finally synthesizing everything in a unit exploring the meaning of "light is an electromagnetic wave."

Students explore the life of pikas, tiny mammals that live in alpine areas, and how they are being impacted by climate change. After a brief introduction which includes a reading, a short video, and a story that includes a mathematical model, students engage in a kinesthetic simulation to gain first-hand experience of life as a pika and how the animals can be impacted by shrinking habitat. Students then create line graphs with data from the simulation and analyze them.

Tissues and cells of root, stem, and leaf anatomy in both dicots and monocots are investigated in this learning activity.

This online article, from Biodiversity Counts, offers insight into how plants interact with arthropods. It has: an explanation of the difference between detrimental and mutually beneficial relationships; some of the chemical and mechanical modifications plants have made to attract helpful arthropods and fend off harmful ones; a detailed overview of pollination, with descriptions of seven common pollination syndromes; a detailed overview of plant defense mechanisms; and a series of questions students can ask when they see an arthropod on a plant in order to learn more about how the two are interacting.

Plant growth regulators, including auxin, gibberellin, cytokinin, abscisic acid, and ethylene, are investigated in this learning activity to demonstrate how these chemicals (hormones) affect plant growth and development.

This activity is a field investigation where students identify native MN plants and record the common name, scientific name, and important information about each.

This learning experience introduces participants to scientific inquiry, hypothesis formation, experimental design, data analysis, and interpretation.

This activity is a first grade life science activity where the students practice inquiry skills by developing questions about seeds, planting them and noting details about how they change as they grow.

This activity is a field investigation of plant succession stages, which students will gather evidence of the areas plant history.

This site helps students see how plants and animals interact to accomplish pollination. Students (Grades 3-8) identify plant and animal parts involved in pollination, connections between pollination and food production, relationships between pollinators and the plants they pollinate, and ways flowers have adapted to encourage pollination.

Students can use the following vocabulary word “cards” to make and justify connections between important terms related to OpenStax Biology - Chapter 5 - Structure and Function of Plasma Membranes. This activity authored by Sara Milillo, Director of Math and Science, Bay Path University.

In this seminar you will use deductive reasoning to sequence steps of transport within the endomembrane system. You will construct a visual image of the endomembrane system using various media to provide practice for your peers.StandardsCompare and contrast the structure and function of carbohydrates, lipids, proteins, and nucleic acids in organisms.BIO.A.4.2.1 Explain how organisms maintain homeostasis (e.g., thermoregulation, water regulation, oxygen regulation).BIO.A.4.1.3 Describe how endoplasmic reticulum, Golgi apparatus, and other membrane-bound cellular organelles facilitate transport of materials within cells.BIO.A.4.1.2 Compare and contrast the mechanisms that transport materials across the plasma membrane (i.e., passive transport -- diffusion, osmosis, facilitated diffusion; active transport -- pumps, endocytosis, exocytosis).BIO.A.4.1.1 Describe how the structure of the plasma membrane allows it to function as a regulatory structure and/or protective barrier for a cell.