Student must synthesize the data that go into the construction and operation …
Student must synthesize the data that go into the construction and operation of a large hydroelectric dam. Students must strive to develop a design that minimizes or mitigates the impacts of the dam on the existing watershed. Students divide the analysis and frequently present to each other their findings. These findings are then synthesized into independent reports produced by each student. Designed for a geomorphology course Uses online and/or real-time data Uses geomorphology to solve problems in other fields Addresses student misconceptions
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The dark reactions of photosynthesis (Calvin Cycle) are presented in this learning …
The dark reactions of photosynthesis (Calvin Cycle) are presented in this learning experience to show where these processes take place in the plant as well as the specific reactions involved.
Students choose one of four short articles to read about mineral mining, …
Students choose one of four short articles to read about mineral mining, including the impacts of mining on the Native American community in the region. Each article highlights a specific example where the Indigenous community's interests are in conflict with the mining company's interests. After reading one of the articles, students post a short reflection to a discussion board, then respond to at least one classmate's reflection.
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To prepare for this assignment, the students read the Chapter 17 "Galapagos …
To prepare for this assignment, the students read the Chapter 17 "Galapagos Archipelago" from The Voyage of the Beagle. In class we have discussed Darwin's theory of evolution as outlined in the first edition of the Origin of Species. The students need to examine Chapter 17 to find those observations that Darwin made in 1835 that support the his theory of evolution that was published 24 years later in 1859.
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In Jigsaw format, groups of 3 students divide up and each collects …
In Jigsaw format, groups of 3 students divide up and each collects topographic data for a small landform using a different technique (tape and level; handheld GPS; Total Station). When they re-group they compare data quantity and quality using spreadsheets and a mapping program. They write a group report comparing the strengths and weaknesses of the three methods. Designed for a geomorphology course Addresses student fear of quantitative aspect and/or inadequate quantitative skills Addresses student misconceptions
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Data Carpentry lesson from Ecology curriculum to learn how to analyse and …
Data Carpentry lesson from Ecology curriculum to learn how to analyse and visualise ecological data in R. Data Carpentry’s aim is to teach researchers basic concepts, skills, and tools for working with data so that they can get more done in less time, and with less pain. The lessons below were designed for those interested in working with ecology data in R. This is an introduction to R designed for participants with no programming experience. These lessons can be taught in a day (~ 6 hours). They start with some basic information about R syntax, the RStudio interface, and move through how to import CSV files, the structure of data frames, how to deal with factors, how to add/remove rows and columns, how to calculate summary statistics from a data frame, and a brief introduction to plotting. The last lesson demonstrates how to work with databases directly from R.
The Biology Semester-long Course was developed and piloted at the University of …
The Biology Semester-long Course was developed and piloted at the University of Florida in Fall 2015. Course materials include readings, lectures, exercises, and assignments that expand on the material presented at workshops focusing on SQL and R.
This lab utilizes the computer program, Excel. In this exercise students will …
This lab utilizes the computer program, Excel. In this exercise students will generate synthetic data sets based on a simplified model of daily high temperatures in Boone, NC and apply several filtering techniques to the data. A key to this lab is that the students must use Excel in an efficient manner; otherwise, this exercise may take a long time to complete. Thus, the synthetic data sets are intentionally large in size. The overarching purpose of this lab is two-fold: 1) Perform some quantitative data processing and determine the effectiveness of several types of simple mathematical noise filters, and 2) Make a professional interpretation and recommendation based on quantitative results.
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Data Carpentry lesson to learn how to use command-line tools to perform …
Data Carpentry lesson to learn how to use command-line tools to perform quality control, align reads to a reference genome, and identify and visualize between-sample variation. A lot of genomics analysis is done using command-line tools for three reasons: 1) you will often be working with a large number of files, and working through the command-line rather than through a graphical user interface (GUI) allows you to automate repetitive tasks, 2) you will often need more compute power than is available on your personal computer, and connecting to and interacting with remote computers requires a command-line interface, and 3) you will often need to customize your analyses, and command-line tools often enable more customization than the corresponding GUI tools (if in fact a GUI tool even exists). In a previous lesson, you learned how to use the bash shell to interact with your computer through a command line interface. In this lesson, you will be applying this new knowledge to carry out a common genomics workflow - identifying variants among sequencing samples taken from multiple individuals within a population. We will be starting with a set of sequenced reads (.fastq files), performing some quality control steps, aligning those reads to a reference genome, and ending by identifying and visualizing variations among these samples. As you progress through this lesson, keep in mind that, even if you aren’t going to be doing this same workflow in your research, you will be learning some very important lessons about using command-line bioinformatic tools. What you learn here will enable you to use a variety of bioinformatic tools with confidence and greatly enhance your research efficiency and productivity.
In this lab, students are introduced to the difference between relative and …
In this lab, students are introduced to the difference between relative and absolute dating, using the students themselves as the material to be ordered. Initially, the students are asked to develop physical clues to put themselves in order from youngest to oldest (exposing the inferences we make unconsciously about people's ages), and this will be refined/modified using a list of current events from an appropriate historical period that more and more of the students will remember, depending on their age (among other variables). Absolute age is introduced by having the students order themselves by birth decade, year, month, and day, and comparing the absolute age order to the order worked out in the relative-dating exercise, with a discussion of dating precision and accuracy.
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A Day Without Agriculture. This is the Lesson 1 Exposure Activity, from …
A Day Without Agriculture. This is the Lesson 1 Exposure Activity, from Unit 1 Introduction to Agriculture, from the DIGS (Developing Individuals, Growing Stewards) AmeriCorps Curriculum from CSU. The curriculum focuses on introducing students in grades 3-5 to Colorado agriculture, industry and environmental issues. The curriculum is matched to State Standards 2021. The curriculum upon request. Visit: https://engagement.colostate.edu/programs-old/developing-individuals-growing-stewards/
This three-act film tells the story of the detective work that solved …
This three-act film tells the story of the detective work that solved the mystery of what caused the disappearance of the dinosaurs at the end of the Cretaceous period. Shot on location in Italy, Spain, Texas, Colorado, and North Dakota, the film traces the uncovering of key clues that led to the discovery that an asteroid struck the Earth 66 million years ago, triggering a mass extinction of animals, plants, and microorganisms. Science practices in geology, physics, biology, chemistry and paleontology all contributed to the solution to this compelling mystery. Lesson plans are included that have students identify evidence and construct an explanation to tie it together. Summary questions are included at the end and a class discussion is recommended. (This activity will be the only one evaluated in this review.) Another resource is Finding the Crater where students visit different K-T boundary sites. There are also lessons where students analyze various characteristics of the asteroid such as its size and energy, chemical data about the asteroid, and the iridium fallout from an asteroid impact. A hands-on activity where students study the differences in foraminifera fossils below and above the K-T boundary is also included as well as an article that outlines more details about each of the discoveries covered in the film. You can view the film on the website or HHMI will send you a free DVD. Lesson plans including teacher notes and a student handout can be found at http://www.hhmi.org/biointeractive/following-trail-evidence.
Students compare mineral structures shown in ball-and-stick, space filling, and polyhedral diagrams. …
Students compare mineral structures shown in ball-and-stick, space filling, and polyhedral diagrams.
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Copper is an element that is essential to our technology and to …
Copper is an element that is essential to our technology and to our standard of living. Commonly, the copper is extracted from a variety of copper-bearing minerals that occur in veins. These fossilized fluid pathways record a complex set of geologic processes with non-linear couplings that are the products of hydrothermal activity associated with igneous intrusions (e.g. heat transport, mechanical fracture, mineral precipitation, permeability changes). By carefully examining a rock slab and its mineralogy, one can decipher the series of interrelated processes and their resultant impact on the final product.
Students set about to determine the relative age of veins by visual examination of the rock slab provided. Several generations of veins are recorded by different colors representing different minerals. Using cross-cutting relationships, they list the veins from oldest to youngest. Based on their color, they determine the sequence of minerals that fill veins. This provides an opportunity to review why color can be used to identify some minerals but not others. Once minerals are identified, their ideal chemical formula allows the percent copper in the mineral to be determined as well as the additional elements that must be present to form the mineral. The consequent change in mineral chemistry can be linked to the alterations in fluids flowing through the fractures by analysis of fluid-mineral equilibria on activity-activity (a-a) diagrams. For the more advanced classes, relevant thermodynamic data can be provided and students can write hydrolysis reactions and calculate the (a-a) diagram themselves.
Interpretation of the geologic history begins with the matrix and initial conditions and follows through rock fracture, fluid flow, mineral precipitation, evolving fluid composition, fracture sealing, pore-fluid pressure buildup, fracture, precipitation, etc. in a series of feedbacks. A feedback diagram can be provided and used as a base-map for interpretation not only of the sequence but changes to each reservoir, or students can be asked to draw the series of events and their reservoirs with the mechanisms of change. In the end, students understand the complex series of geologic processes that must come together in space and time to produce an ore-deposit that can be mined for our use. They also wrestle with the complications of reading the rock record and with the ambiguity of interpreting the interaction of various mechanisms that control the final product.
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Spreadsheets Across the Curriculum/Geology of National Parks module. Students calculate the haze …
Spreadsheets Across the Curriculum/Geology of National Parks module. Students calculate the haze index and standard visual range from concentrations of particulate matter.
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In this activity, students investigate the fascinating and complex process of decomposition …
In this activity, students investigate the fascinating and complex process of decomposition and lay the foundation for deeper understanding of concepts related to matter and energy transfer in ecosystems. Through exploration and discussion, students go beyond simple definitions. Instead, students discover key characteristics of decomposition as they struggle with creating a sequence for decomposing wood and leaves. They learn the difference between physical decomposition and chemical decomposition and that many things contribute to decomposition, but certain organisms are classified as decomposers. They also search for and discuss evidence of decomposers, make model diagrams to further develop their ideas about the process of decomposition, and discuss decomposition and its role in the cycling of matter. Finally, students are challenged to recognize the evidence and impact of decomposition in the ecosystems they explore.
This activity will help students to explore characteristics of microbes that live …
This activity will help students to explore characteristics of microbes that live in the deep sea. This activity can be conducted as a jigsaw or research project, and can be used with face-to-face, remote, and hybrid students.
Provenance: Beverly Owens, Cleveland Early College High School Reuse: This item is offered under a Creative Commons Attribution-NonCommercial-ShareAlike license http://creativecommons.org/licenses/by-nc-sa/3.0/ You may reuse this item for non-commercial purposes as long as you provide attribution and offer any derivative works under a similar license.
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This activity is a Google Slide playlist that will introduce students to …
This activity is a Google Slide playlist that will introduce students to microbes that can be found in deep sea sediments, and what roles they play in their environment. This playlist is suitable for use in remote, hybrid, or in-person instruction and can easily be added to a Learning Management System.
Provenance: Molly Ludwick, Kings Mountain Middle School Reuse: This item is offered under a Creative Commons Attribution-NonCommercial-ShareAlike license http://creativecommons.org/licenses/by-nc-sa/3.0/ You may reuse this item for non-commercial purposes as long as you provide attribution and offer any derivative works under a similar license.
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Developed for second grade. Students will: use their sense of touch and …
Developed for second grade. Students will: use their sense of touch and sight to discover differences between several types of seeds; discuss why seeds come in different shapes and sizes; make connections between art and science; discuss the growth process of a seed; discuss how different seeds are used in different products.Biology In Elementary Schools is a Saint Michael's College student project. The teaching ideas on this page have been found, refined, and developed by students in a college-level course on the teaching of biology at the elementary level. Unless otherwise noted, the lesson plans have been tried at least once by students from our partner schools. This wiki has been established to share ideas about teaching biology in elementary schools. The motivation behind the creation of this page is twofold: 1. to provide an outlet for the teaching ideas of a group of college educators participating in a workshop-style course; 2. to provide a space where anyone else interested in this topic can place their ideas.
Appreciating the depth of time is a bit like trying to understand …
Appreciating the depth of time is a bit like trying to understand the national debt -- it is easy to rattle off the number, but more difficult to appreciate what it means. Several popular writers have tried to convey the depth of time by incoporating one major (and important!) signpost in their scales: the first historical records of humans on the planet. Mark Twain famously referred to human history as the "skin of paint" at the summit of the Eiffel Tower, and John McPhee the "stroke of a medium-grained nail file" on the middle nail of an outstretched arm.
Eiffel Tower
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Vitruvian man
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I would like for you to evaluate these two metaphors for accuracy. How close were Twain and McPhee to appropriately contexualizing human existence in geological time? Use the pdf's of Twain's and McPhee's prose and what you know from class lectures to accomplish the following goals.
(1) Evaluate whether McPhee's and Twain's metaphors are appropriately scaled -- i.e., do their metaphors correctly depict the age of the earth relative to human history? How about if we incorporate the fossil record of humans?
(2) Create your own appropriately scaled metaphor. Add in at least three other "signposts", either biological or geological, into your metaphor and explain why you chose them.
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