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  • NGSS.HS.LS1.7 - Use a model to illustrate that cellular respiration is a chemical proc...
  • NGSS.HS.LS1.7 - Use a model to illustrate that cellular respiration is a chemical proc...
Cellular Respiration
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Cellular respiration is the process by which our bodies convert glucose from food into energy in the form of ATP (adenosine triphosphate). Start by exploring the ATP molecule in 3D, then use molecular models to take a step-by-step tour of the chemical reactants and products in the complex biological processes of glycolysis, the Krebs cycle, the Electron Transport Chain, and ATP synthesis. Follow atoms as they rearrange and become parts of other molecules and witness the production of high-energy ATP molecules.

Subject:
Life Science
Material Type:
Lecture Notes
Simulation
Provider:
Concord Consortium
Provider Set:
Concord Consortium Collection
Author:
The Concord Consortium
Date Added:
01/13/2012
Energy Drink - Circle of Viewpoints
Conditional Remix & Share Permitted
CC BY-NC
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This activity can be used as an extension for unit over macromolecules or an application of the metabolism unit. The purpose behind this activitity is to really look at the foods and drinks we used to obtain energy and see of they do what they claim to do. The circle of viewpoints activity is built around generating a list of ideas/perspectives about a given topic and then using that information for a prompt to dive deeper into the topic.  This activity is built in in 3 parts Background reading and brainstormingQuestions and Reserch Socratic Circle

Subject:
Educational Technology
Material Type:
Lesson Plan
Author:
Doug Mossengren
Date Added:
06/07/2018
Fuel Cell Car: Use Water for Energy! A lesson in Cell Respiration, Energy Flow, Photosynthesis
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Public Domain
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This lesson will expose Biology students to mechanisms of energy by using a wind turbine demonstration and a fuel cell car student lab.  Fuel Cell kits will need to be purchased for this activity.  

Subject:
Biology
Material Type:
Activity/Lab
Author:
Integrated Nanosystems Development Institute (INDI)
Date Added:
07/13/2021
Ocean Acidification: A Systems Approach to a Global Problem
Conditional Remix & Share Permitted
CC BY-NC
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In this curriculum module, students in high school life science, marine science, and/or chemistry courses act as interdisciplinary scientists and delegates to investigate how the changing carbon cycle will affect the oceans along with their integral populations.

The oceans cover 70 percent of the planet and play a critical role in regulating atmospheric carbon dioxide through the interaction of physical, chemical, and biological processes. As a result of anthropogenic activity, a doubling of the atmospheric CO2 concentration (to 760 ppm) is expected to occur by the end of this century. A quarter of the total CO2 emitted has already been absorbed by the surface oceans, changing the marine carbonate system, resulting in a decrease in pH, a change in carbonate-ion concentrations, and a change in the speciation of macro and micronutrients. The shift in the carbonate system is already drastically affecting biological processes in the oceans and is predicted to have major consequences on carbon export to the deep ocean with reverberating effects on atmospheric CO2. Put in simple terms, ocean acidification is a complex phenomenon with complex consequences. Understanding complexity and the impact of ocean acidification requires systems thinking – both in research and in education. Scientific advancement will help us better understand the problem and devise more effective solutions, but executing these solutions will require widespread public participation to mitigate this global problem.

Through these lessons, students closely model what is occurring in laboratories worldwide and at Institute for Systems Biology (ISB) through Monica Orellana’s research to analyze the effect CO2 has on ocean chemistry, ecosystems and human societies. Students experiment, analyze public data, and prepare for a mock summit to address concerns. Student groups represent key “interest groups” and design two experiments to observe the effects of CO2 on seawater pH, diatom growth, algal blooms, nutrient availability, and/or shell dissolution.

Subject:
Atmospheric Science
Physical Science
Material Type:
Module
Author:
Aisha McKee
Alexis Boleda
Alexis Valauri-Orton
Allison Lee Cusick
Anna Farrell-Sherman
Baliga Lab
Barbara Steffens
Claudia Ludwig
Danny Thomson
Dexter Chapin
Dina Kovarik
Donald Cho
Eric Grewal
Eric Muhs
Helen Ippolito
Holly Kuestner
Institute for Systems Biology
Jeannine Sieler
Jennifer Duncan-Taylor
Jia Hao Xu
JoAnn Chrisman
Jocelyn Lee
Kedus Getaneh
Kevin Baker
Mari Knutson Herbert
Megan DeVault
Meredith Carlson
Michael Walker
Monica V. Orellana
Nitin S. Baliga
Olachi Oleru
Raisah Vestindottir
Steven Do
Systems Education Experiences
William Harvey
Zac Simon
Date Added:
03/09/2023
Patterns Biology
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CC BY-NC-SA
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Patterns Biology is the culminating course in the 3-year high school Patterns Science sequence. Patterns Biology focuses on three-dimensional (3D) learning through culturally responsive, phenomena-based storylines that intertwine the disciplinary core ideas of biology with the scientific and engineering practices and crosscutting concepts as described in the Next Generation Science Standards (NGSS).

The Patterns High School Science Sequence (https://hsscience4all.org/) is a three year course pathway and curriculum aligned to the Next Generation Science Standards (NGSS).

Each course utilizes:
- Common instructional strategies
- Real world phenomena
- Design challenges to engage students and support their learning.

For more information, contact us at info@pdxstem.org.

The curriculum is a combination of teacher-generated and curated open-content materials. The Teacher-generated materials are shared freely under a Attribution-NonCommercial-Sharealike Creative Commons License.

Subject:
Biology
Life Science
Material Type:
Full Course
Provider:
Portland Metro STEM Partnership
Author:
Jamie Rumage
Date Added:
09/03/2020
Spectroscopy
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What happens when an excited atom emits a photon? What can we deduce about that atom based on the photons it can emit? A series of interactive models allows you to examine how the energy levels the electrons of an atom occupy affect the types of photons that can be emitted. Use a digital spectrometer to record which wavelengths certain atoms will emit, and then use this knowledge to compare and identify types of atoms. Students will be abe to:

Subject:
Applied Science
Chemistry
Education
Engineering
Mathematics
Physical Science
Physics
Material Type:
Data Set
Lecture Notes
Provider:
Concord Consortium
Provider Set:
Concord Consortium Collection
Author:
The Concord Consortium
Date Added:
12/13/2011