This is an interactive, high school biology Nearpod lesson tied to SEEd standard BIO.4.4. It guides students through information and activities about changes in environmental conditions that may cause increases in the number of individuals of some species, the emergence of new species over time, and/or the extinction of other species.
This resource is a student-ready, three-dimensional SEEd science lesson you can add to your Nearpod library. Many of the phenomena, text, and images come from UEN OER textbooks, Seedstorylines.org, ck12.org, and pixabay.com. Most videos are from youtube.com or pbslearningmedia.org. Many of the simulations were found at phet.colorado.edu, ck12.org, and pbslearningmedia.org. This lesson is unique to Nebo School District but was built with the help of many amazing ideas from teachers throughout Utah.

This is an interactive, high school biology Nearpod lesson tied to SEEd standard BIO.4.5. It guides students through information and activities about solving a real-world problem caused by natural selection and adaptation of populations.
This resource is a student-ready, three-dimensional SEEd science lesson you can add to your Nearpod library. Many of the phenomena, text, and images come from UEN OER textbooks, Seedstorylines.org, ck12.org, and pixabay.com. Most videos are from youtube.com or pbslearningmedia.org. Many of the simulations were found at phet.colorado.edu, ck12.org, and pbslearningmedia.org. This lesson is unique to Nebo School District but was built with the help of many amazing ideas from teachers throughout Utah.

The purpose of this lesson is to teach students about blood and its components while instilling an appreciation of its importance for survival. The lesson takes a step-by-step approach to determining the recipe for blood while introducing students to important laboratory techniques like centrifugation and microscopy, as well as some diseases of cell types found in blood. It also highlights the importance of donating blood by explaining basic physiological concepts and the blood donation procedure.

This video will help students, particularly those not in AP-level classes, have a practical application for knowing about the major divisions between plants, particularly about the details of plant anatomy and reproduction. Students will be able to :Identify the major evolutionary innovations that separate plant divisions, and classify plants as belonging to one of those divisions based on phenotypic differences in plants. Classify plants by their pollen dispersal methods using pollen dispersal mapping, and justify the location of a _„ƒcrime scene_„Ž using map analysis. Analyze and present their analysis of banding patterns from DNA fingerprinting done using plants in a forensic context.

Make a whole rainbow by mixing red, green, and blue light. Change the wavelength of a monochromatic beam or filter white light. View the light as a solid beam, or see the individual photons.

Mix two gases to explore diffusion! Experiment with concentration, temperature, mass, and radius and determine how these factors affect the rate of diffusion.

In this video module, students learn how scientists use genetic information from dogs to find out which gene (out of all 20,000 dog genes) is associated with any specific trait or disease of interest. This method involves comparing hundreds of dogs with the trait to hundreds of dogs not displaying the trait, and examining which position on the dog DNA is correlated with the trait (i.e. has one DNA sequence in dogs with the trait but another DNA sequence in dogs not displaying the trait). Students will also learn something about the history of dog breeds and how this history helps us find genes.

Scientists who are working to discover new medicines often use robots to prepare samples of cells, allowing them to test chemicals to identify those that might be used to treat diseases. Students will meet a scientist who works to identify new medicines. She created free software that ''looks'' at images of cells and determines which images show cells that have responded to the potential medicines. Students will learn about how this technology is currently enabling research to identify new antibiotics to treat tuberculosis. Students will complete hands-on activities that demonstrate how new medicines can be discovered using robots and computer software, starring the student as ''the computer.'' In the process, the students learn about experimental design, including positive and negative controls.

This is an interactive Nearpod lesson tied to SEEd standard ESS.3.2. It guides students through information and activities about different climates at the same latitude.
This resource is a student-ready, three-dimensional SEEd science lesson you can add to your Nearpod library. Many of the phenomena, text, and images come from UEN OER textbooks, Seedstorylines.org, ck12.org, and pixabay.com. Most videos are from youtube.com or pbslearningmedia.org. Many of the simulations were found at phet.colorado.edu, ck12.org, and pbslearningmedia.org. This lesson is unique to Nebo School District but was built with the help of many amazing ideas from teachers throughout Utah.

This is an interactive Nearpod lesson tied to SEEd standard ESS.3.3. It guides students through information and activities about wind patterns.
This resource is a student-ready, three-dimensional SEEd science lesson you can add to your Nearpod library. Many of the phenomena, text, and images come from UEN OER textbooks, Seedstorylines.org, ck12.org, and pixabay.com. Most videos are from youtube.com or pbslearningmedia.org. Many of the simulations were found at phet.colorado.edu, ck12.org, and pbslearningmedia.org. This lesson is unique to Nebo School District but was built with the help of many amazing ideas from teachers throughout Utah.

This lesson is about the flow of energy in ecosystems. The setting is Plimoth Plantation, a living history museum in Plymouth, Massachusetts, USA, where students will learn about the first Thanksgiving meal in America, celebrated in 1621 by early American settlers and Wampanoag Indians. By examining this meal and comparing it to a modern day Thanksgiving celebration, students will be able to explore the way in which food energy moves and is transformed in an ecosystem. The learning goals focus on the movement of energy from one feeding level to the next within a food web, the way in which energy changes form, and the inefficiency of energy transfer, which in turn affects the availability of food energy for organisms at the highest feeding level. The lesson is directed at high school level biology students. Students should be familiar already with food webs, food chains, and trophic (feeding) levels. They should also be familiar with the general equations for photosynthesis (CO2 + H2O => C6H12O6) and cell respiration (C6H12O6 => CO2 + H2O), and understand the basic purpose of these processes in nature. This lesson can be completed during one long classroom period, or can be divided over two or more class meetings. The duration of the lesson will depend on prior knowledge of the students and on the amount of time allotted for student discussion. There are no supplies required for this lesson other than the downloadable worksheets (accessed on this BLOSSOMS site), paper and some glue or tape.

In this lesson students will see the different types of evidence scientists use to understand evolutionary relationships among organisms. They will first practice by using shared physical characteristics to predict relationships among members of the cat family and then use this approach to predict primate relationships. They will compare their predictions to evidence provided by analyzing amino acid sequences and build a phylogenetic tree based on these sequences. Finally, they will look at the tree in the context of time in order to see divergence times.

This resource includes posters and images from the Modern Water Cycle collection by BYU and the USGS. The resources are visual definitions of common water cycle terms. The water cycle introduces a lot of new terms for young students. Many teachers focus tightly on these phrases and what they mean physically for the water (e.g. Evaporation: liquid water to water vapor). We also include a variety of places where those changes occur.

The Science Core Guides are created to provide guidance for developing effective instruction aligned to the Utah Science with Engineering Education (SEEd) Standards. They are intended to support teachers, administrators, science specialists, instructional coaches, parents, and other stakeholders as they plan instruction at a local level.

The Core Guides are not intended to be read from cover to cover. They are meant as a resource document to be used, when needed, to support teacher professional learning and curriculum decisions. They are not meant to be used by students, and therefore they may not be written in student-friendly language. The Core Guides are meant to inform teachers and leaders as they make science curriculum decisions.

The Science Core Guides are created to provide guidance for developing effective instruction aligned to the Utah Science with Engineering Education (SEEd) Standards. They are intended to support teachers, administrators, science specialists, instructional coaches, parents, and other stakeholders as they plan instruction at a local level.

Understanding Biodiversity presents an overview of biodiversity, its importance and relevance to humans, all living things, and the Earth. It includes species pages and a template to engage and involve students in real-life data collection.

Biology SEEd textbook for the 2022-2023 school year. This textbook was developed to align to the Utah Science with Engineering Education (SEEd) Standards. (Added: June 8, 2022)