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Browsing Editable
The following are all of the editable activities, from all categories and modules, in alphabetical order.
The models are not sequentially numbered;
gaps in numbering do not indicate missing models but
rather reflect the creation process.
135 activities total.
Displaying activities 1 through 135.
Activity List- A Comparison of Liquid and Gas States (A 1-page study for advanced students)
- A Reverse Micelle
(a 1-page model exploration for advanced students)
- Activation Energy (1-page introduction)
- Active Filters (demo)
- Air Filtration (1-page introduction)
- Alignment of Polar Molecules with/without an External Field (1-page activity)
- Amino Acids and Water: 20 Alanine Model (4 connected model pages)
- Amplification of Biochemical Signals: the ELISA Test (an 8-page activity for technical students)
- Atomic Layer Deposition (A 1-page experiment)
- Atomic Mass and Melting Point (1-page exploration)
- Atomic Structure (SAM)
(9-page, 2-day activity)
- Atoms and Conservation of Energy (SAM)
(9-page activity)
- Brownian Motion
(a 4 pp activity)
- Catalysis: Three conditions
(One of three interlinked model pages on the role of catalysis)
- Charge-Dipole Interaction
(A 1-page exploration)
- Chemical Equilibrium (1-page activity)
- Chemical Equilibrium and Le Chatelier's Principle
(a 4 pp, one-day activity)
- Chemical Potential Energy and Phase Change
(a 3 pp exploration)
- Chemical Reaction Kinetics: Dissociation and Recombination of Diatomic Molecules (a 1-page exploration)
- Chemical Reactions (interactive essay by Charles Xie)
- Chemical Reactions and Stoichiometry (SAM)
(a 2-day activity)
- Counting Reactants and Products
(a one-page interactive model)
- Crystals: Closely Packed Metals (a 1 page model in 3D)
- Density and Buoyancy with Centrifugation
(a 3 pp activity with technical application)
- Designer Proteins
(A 5-page activity)
- Diffusion Assessment (test)
- Diffusion, Osmosis, and Active Transport (SAM)
(a 2-day activity)
- Diffusion, Osmosis, and Dialysis
(a 5pp activity)
- Dissolving Salt in Water (template model)
- Dissolving Salt in Water: Teacher-contributed variant
- Distillation and the Role of Weak Forces
(a 4 pp activity)
- DNA Hybridization (Plain Model)
- DNA Hybridization with Southern Blot
(a 5 pp activity for biotechnology students)
- DNA to Protein Synthesis
(a 6 pp introduction)
- DNA to Proteins (SAM)
(a 2-day activity; 11 pp)
- Docking: Binding of Complementary Surfaces
(a 2 pp introduction to surfaces)
- Effect of Charges on Folding: A Strongly Polar Conformation
- Effect of Charges on Folding: An Alternately Charged Conformation
- Effusion of Gas Molecules
(a 1 page demonstration model)
- Elastic Collision between Two Particles
(a 1-page demonstration model)
- Electric Current (SAM)
(a 2-day, 10 pp activity)
- Electrical Generators
(a one page demonstration)
- Electrostatic Self-Assembly (demo)
- Electrostatics (SAM)
(a 7 pp activity for 1-2 class periods)
- Energy Conservation in Chemical Reactions
(A 1-page demonstration)
- Energy Games: Energy and Force Among Atoms
(10 pp of energy exercises)
- Equilibrium Position of Chemical Reactions
(a one-page interactive model)
- Excited States and Photons (SAM)
(12 pp for 2 days)
- Experiment on an All-Hydrophilic Polypeptide
(an interrelated set of 4 models)
- Explosion
(5 interlinked models)
- Fields: The movement of a Charged Particle in Three Fields
A 1-page model exploration by Charles Xie)
- Fluorescence: Molecular Tagging
(a 6 pp activity for biotechnology students)
- Formation of Water Shells around Ions
(a 1-page highly interactive model)
- Four Levels of Protein Structure (SAM)
(a 9-page 1-2 day activity)
- Free Radicals: Their Role in Chemical Reactions
(a 1 page comparison study)
- From DNA to Proteins and Protein Folding (MIT Museum Exhibit)
- From Monomers to Polymers (Three-activity module)
- Gas Effusion in a Two-Compartment Container
(1 page interactive model)
- Gas Laws (SAM)
(an 8 pp 1 or 2 day activity)
- Gas Molecules in a Box (3D dynamics)
- Graphite: Chemical Bond Network
(a single model with some interactivity)
- Heat and Temperature (SAM)
A 2-day activity
- Heat and Temperature (Windows only)
- Heat Flow (Monday's Lesson)
(a 4-page activity)
- Heat of Vaporization (with Latent Heat)
(1 page in 3-page activity on Exploring Potential Energy in Phase Changes)
- Heat Propagation
(a 1-page exploration)
- Heat Propagation/Transfer 2
(A 1-page model exploration)
- Hemoglobin (ROVER)
(an advanced activity in 3D)
- Hemoglobin Tour
(a 2-page interactive exploration)
- HIV Virus (demo model)
- How a Protein Gets Its Shape: The Role of Charge
- How Do Mass and Inertia Affect Molecular Motion?
- Hydrophilicity (demo - set of linked models)
- Hydrophobia (demo - set of linked models)
- Hydrophobic Collapse (PROBLEM/Delete?)
- Intermolecular Forces (SAM)
(a 2-class activity)
- Introduction to Crystals
(an 8-page, 1-2 class activity)
- Introduction to Modeling (SAM)
(a 7 page activity)
- Introduction to Molecular Dynamics Models
(7-page original Introduction to MW)
- Ion Transport in an Electric Field
(interactive demo)
- Ionic Bonds and Their Effect on Molecular Structure
(interactive 1-page model)
- Kinetic Energy Equipartition
(1-page demo model)
- Latent Heat
(Single model with graph. Model and scripts by Prof. Arie Aziman and Carlos Cardena, modified from an original model by Dan Damelin)
- Light and Matter Interactions (An 8-page activity originally by Concord MW team, modified by Ed O'Sullivan, Parkland College)
- Light-Matter Interaction Part I: Photons (Template)
- Lipids and Carbohydrates (SAM)
A 2-day 11-page activity
- Liquid Crystals: the Mesophase between Solids and Liquids
(a 1-p model exploration by Charles Xie)
- Mass and Molecular Motion
(A 2-model 1-page exploration)
- Maxwell Speed and Velocity Distributions
(3-interconnected 1-page models)
- Melittin Protein
(a sample protein model)
- Mission Immunity
(a 3D, 5-page activity, from the Rover project)
- Molecular Crystals
(7-page activity)
- Molecular Dynamics Simulation of Sodium Chloride (1 page interactive model in 3D)
- Molecular Geometry: (SAM) 11-page, 2-day activity
- Molecular Sieve (1-page model)
- Molecules with Aromatic Rings (1-page model with temperature control)
- Mutations: Changing the Genetic Code
(a 7-page activity)
- Nanomachines
(a 5-page activity)
- Newton's Laws at the Atomic Level (SAM)
(a 2-day, 9-page activity)
- Observing Newton's 3rd Law in a Molecular Dynamics Simulation (a 1-page model)
- Osmosis and Osmotic Pressure
(a simple model in 1-page with interactivity)
- Phase Change
(2-day, 9-page activity from the SAM project)
- Phase Separation
(a single interactive model)
- Piezoelectric Effect
(a single model for advanced students)
- Point Defects in Crystals (2-page activity)
- Polymerization (7 pp activity for advanced students)
- Polymerization: Step Growth (model only)
- Potential Energy Curves and Activation Energy
(5-page activity)
- Potential Energy in Covalent Bond Formation
(a 5-page activity)
- Protein Conservation: A View into Proteomics
(a 6-page activity)
- Protein Folding (8-page activity; a "Stepping Stone" of MoLo project)
- Protein Substrate Docking (3-interlinked pages of related demonstration models)
- Protein Synthesis (Template Model)
- Proteins and Nucleic Acids (SAM)
(a 12-page, 2-day activity from the SAM project)
- Reaction Rate and Concentration
(a 3-day activity)
- Reaction Rates, Catalysis, and Pasteurization
(8-page activity)
- Self-alignment of dipole moments and alignment in external field
(a 1-page model exploration)
- Self-Assembly (Demo model)
- Self-Assembly and Orientation
(a 4-page set of models for comparison)
- Self-Assembly with Nanomanufacturing
(a 9-page activity)
- Simulating Primitive Life: Nanoworms
(a 1-page demonstration model)
- Solvation of Polar Molecules
(a 1-page model for exploration)
- Spectroscopy (SAM)
(an 8-page, 1-2 day activity)
- States of Matter Basics:
Interatomic interactions: Towards state of matter (I) and (II)
- States of Matter Basics: Comparison of liquid and solid
- Strong Chemical Bonds (SAM)
(a 2-day, 10-page activity)
- Structure of Proteins: Insulin
(a 7-page activity)
- Superballs are Like Atoms
(8-page activity)
- The Effect of Structures and Subforces on Protein Conformation
- The Relationship Between Interaction Strength and Melting Point
- The Tree of Life's Macromolecules
(multi-page interlinked activity)
- Visualizing Beginning Molecular Ideas (a TEST)
- Water Molecules (a 1-page model)
- X-ray Crystallography (a 13-page activity for advanced students)
- Zoom It - A Sense of Scale (a powers-of-ten tool)
View Complete Activity List
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