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MSM Unit 1, Lesson 6: Decoding & Modifying the model

In this lesson students will be modifying the model of the molecular beam experiment to make a collision between different molecules. This time we will use hydrogen peroxide or H2O2 molecules instead of water molecules. Students will decode the model and make changes to the model‘s setup and collision code to model the collision and reaction. They will test the accuracy of the model by checking to see if the proper number and ratio of products were produced.

MSM Unit 1, Lesson 5: Molecular Beam Experiments

In this lesson students explore a model of a molecular beam experiment in which two water molecules collide at high speed and break apart into their component atoms. In analyzing the ratios of hydrogen and oxygen produced by the collision, students notice that there is something wrong. Investigating the code of the model leads to the discovery of a problem that students can fix. Students can test their solution to fixing the model by running the model and seeing if it produces the components in

MSM Unit 1, Lesson 2: Colliding Turtles Playground

In this lesson students engage in creating, modifying and testing collisions and reactions (cause and effect) processes as instructions. Playgrounds are Google Slides with code blocks that students use to arrange and then act out as the computer processing the instructions. The concepts of ratios and examining ratios before and after collisions are made explicit.

MSM Unit 1, Lesson 3: Decoding & Modifying a Collision Model

In this lesson students see a StarLogo Nova model of turtles colliding. Then they look under the hood of the model to see if they recognize any of the code blocks being used. (*Students are often surprised to see that the code they generated in the playground is actually used to run the model!) Students identify where in code the ratio is being produced and what the ratio of turtles is before and after the collision. Finally, students get to pick a ratio they want to produce and modify the mode

MSM Unit 1, Lesson 4: Matter and Properties of Water

In this lesson students learn about matter and properties of matter. Then conduct two experiments (that can be done at home) and develop a mental molecular level understanding of water. This lesson prepares students for the next two lessons in which they will be modeling the breakdown of water into its component atoms.

MSM Unit 3: It’s Getting Hot in Here

summary

MSM Unit 2: Clean Water

This unit spans across 6th grade math and science content.

MSM Unit 1, Lesson 1: Introducing Ratios

In this lesson students will participate in two activities then create their own ratio puzzles. In the first activity, they will learn about parts-to-parts ratios and complete an embedded assessment. In the second activity, they will learn about parts-to-whole ratios and complete another embedded assessment. In the third activity, students will create their own ratio puzzles to share. Throughout the lessons, the language of ratios is reinforced.

Looking at particles with StarLogo Nova

This lesson uses StarLogo Nova to explore how particles move from gas to liquid to solid depending on the setting of the heat slider.

Decoding a Model - Dissolving of NaCl in Water

Start of a lesson on dissolving a solid in water by decoding on a model.

Interview with Hal Scheintaub

Teachers with GUTS interviewed Hal Scheintaub and demo of StarLogo Nova models created by his students on August 2, 2017.

Simulación de un brote de Dengue

Este modelo simula la transmisión del virus del dengue en un barrio de cuatro manzanas durante 180 días. El vector del virus es el mosquito Aedes egyptii. La simulación muestra un gráfico con la evolución del brote (el cambio en la cantidad de personas sanas y de personas infectadas), otro gráfico con la evolución de la población de mosquitos y unos monitores que indican el estado de la población de mosquitos y cuántas personas fueron infectadas.

Dengue outbreak simulation

This model simulates the transmission of the dengue virus in a neighborhood of four blocks during 180 (one hundred and eighty) days. The vector of the virus is the mosquito Aedes egyptii. The simulation shows a chart of the evolution of the outbreak (the change in the number of healthy people and infected people), another graph with the evolution of the mosquito population and some monitors that indicate the state of the mosquito population and how many people were infected.

El Juego de la pesca (La Tragedia de los Comunes)

El Juego de la Pesca utiliza el concepto de Tragedia de los Comunes (Hardin, 1968) para trabajar sobre sustentabilidad. El jugador (pescador) tiene 10 días para atrapar tantos peces como pueda para alimentar a su familia. Cada día, el pescador puede elegir pescar uno, dos o tres peces, o no pescar ninguno. Hay otros dos pescadores que también tratan de capturar tantos peces como puedan. El lago en el que se pesca sólo puede soportar 20 peces (que es la capacidad de carga del lago).

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