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Physics+C — Kinematics I: Car on a Ramp

This unit reviews concepts related to kinematics and the motion of a car on a ramp. It provides students with the opportunity to gain a deeper understanding of concepts used to describe motion, including displacement, velocity, and acceleration.

Chemistry+C — Kinetics: Rate of Reactions

This unit reviews concepts of kinetics and rates of reaction. It provides students with the opportunity to gain a deeper understanding of processes involved in changing the reaction speed and how it can be represented and demonstrated using computer models.

Chemistry+C — Titration: Acid-base Neutralization

This unit reviews concepts related to acid-base chemistry. It provides students with the opportunity to gain a deeper understanding of processes involved in chemical reactions and how they can be represented and demonstrated using computer models.

Physics+C — Electricity: Series Circuits

This unit reviews concepts in electricity, including Ohm’s law and series circuit design. The model allows students to explore the relationship between voltage, current, and resistance and the connection between current and the average velocity of electrons in a circuit.

Chemistry+C — Redox: Electrolysis within a Battery

This unit reviews concepts of oxidation and reduction through electrolysis. It provides students with the opportunity to gain a deeper understanding of processes involved in influencing the equilibrium of charges within a battery and how it can be represented and demonstrated using computer models.

Chemistry+C — Matter: Physical Change of Salt in Water

This unit reviews concepts related to matter. Students will gain a deeper understanding of processes involved in the physical change of an ionic compound dissolving in water and how it can be represented and demonstrated using computer models.

Chemistry+C — Periodic Trends: Ionic Compound Interactions

This unit reviews concepts in atomic structure and then provides students with the opportunity to gain a deeper understanding of the size of an atom as the number of valence electrons increases and the interactions with other atoms.

Chemistry+C — Chemical Reactions: Photosynthesis and Cellular Respiration

This unit reviews concepts of a commonly known chemical reaction concept (conservation of matter) and then provides students with the opportunity to gain a deeper understanding of processes involved in the energy transfer during a chemical reaction and how it can be represented and demonstrated using computer models.

Physics+C — Simple Harmonic Motion: Mass on a Spring

This unit reviews simple harmonic motion through experiments with a NetLogo model that simulates a horizontal mass-spring system. The model allows students to displace a mass that is attached to a horizontal spring and observe the motion of the mass.

Physics+C — Kinematics II: Motion of a Ball

This unit reviews concepts related to kinematics and the motion of a ball near the Earth’s surface. It provides students with the opportunity to gain a deeper understanding of 1-dimensional motion (a ball falling and accelerating due to gravity, a ball rolling on a horizontal frictionless surface) and/or 2-dimensional motion (projectile motion) and how it can be represented and demonstrated using computer models.

Physics+C — Mechanical Waves: Sound through Different Media

This unit reviews mechanical waves through experiments with a NetLogo model that simulates a sound wave traveling through a medium.

Physics+C — Nuclear Physics: Rutherford's Gold Foil Experiment

This unit reviews the structure of the atom through experiments with a NetLogo model that simulates Rutherford’s gold foil experiment. The model allows students to shoot alpha particles at a gold foil and observe any changes in the path of the alpha particles.

What's Represented?

These exercises ask the learner to identify abstractions in the computer model as compared to a diagram or image of a natural phenomenon.

My Robotic Friends (cups activity)

This is the cups activity by Thinkersmith (later part of Code.org)

Decoding a Model - Dissolving of NaCl in Water

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

Bloques de código para modelo de cambio climático

Es una hoja de referencia con los bloques de código necesarios para el modelo de cambio climático. Se explica bloque por bloque qué función cumple cada estructura en cada pestaña de la programación con StarLogo NOVA.

Introducción al modelado del clima

Documento base como introducción al modelado del clima. Habla sobre el sistema climático global como un sistema dinámico complejo; la diferencia entre tiempo y clima; los ciclos de retroalimentación en el sistema climático global, etc.
Fue extraído de “Mathematics of Climate Change: A new discipline for an uncertain century” una publicación del Instituto de Investigación en Ciencias Matemáticas. Berkeley, CA 2007 y traducido al español.

Toss-Up

As a virus spreads through a community, epidemiologists might study how far a disease has spread, how quickly it spreads and how infectious it can be as well a numerous other pieces of data in order to understand the disease and its potential impact on a community. In this activity, students will simulate the spread of a virus such as the flu. Students will work in pairs to accumulate data using graph paper, a data chart, and a die. Before starting, groups will need to decide on three variables.

prisoner's dilemma score box by https://www.open.lib.umn.edu

Prisoner's Dilemma (Tit for Tat)

A participatory simulation where partners examine strategies of cooperation versus individual gain. Based on the game theory activity of Prisoner's Dilemma, this activity introduces students to the contrast between theories of "Tragedy of the Commons" (individuals maximizing their own gain will result in collapse of the resources) and classic economic theory (maximum individual gain will lead to greatest efficiency).

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.

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