HomeConcept libraryChemistryRates and EquilibriumRates and Equilibrium

Chemistry Rates and EquilibriumIntroStarter track

Concept module

Reaction Rate / Collision Theory

Keep one chemistry box visible so temperature, concentration, activation threshold, and catalysts can be read as changes in successful collisions instead of chemistry slogans.

Interactive lab

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Featured setups

Crowded but cool

Open the busy box and compare collision attempts with successful collisions.

Catalyzed threshold

Open the lower-barrier setup and see success rise without simply heating the mixture.

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Stable links

Starter track

Step 1 of 20 / 2 complete

Rates and Equilibrium

Next after this: Dynamic Equilibrium / Le Chatelier's Principle.

1. Reaction Rate / Collision Theory2. Dynamic Equilibrium / Le Chatelier's Principle

This concept is the track start.

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Why it behaves this way

Explanation

Reaction rate becomes easier to trust when the collision story stays visible. This module keeps one particle box, one activation threshold, and one live rate readout together so temperature, concentration, and the barrier all stay attached to the same cause-and-effect bench.

The key distinction is that more collisions are not automatically more reaction. Concentration mostly changes how often particles meet, while temperature and barrier changes decide how many of those meetings are energetic enough to succeed.

Key ideas

01Reaction rate depends on successful collisions, not just on how often particles hit each other.

02Raising temperature increases both how often particles collide and how likely those collisions are to clear the barrier.

03A catalyst changes the barrier story without having to make the particles hotter.

Frozen walkthrough

Step through the frozen example

Frozen walkthrough

Use the current chemistry bench instead of a detached worksheet. The same controls drive the particle box, the response graphs, and these substitutions.

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View plans

Frozen valuesUsing frozen parameters

For the current mixture, how do all collisions and successful collisions differ?

T

Temperature

3.1

c

Concentration

1.4

E_{a}

Activation threshold

2.8

1. Read how often the particles collide

At the current temperature and concentration, the box makes about 32.73 collision attempts each second.

2. Read how many of those hits clear the threshold

Only about 37.46% of those collisions clear the effective barrier.

3. Turn that into a reaction rate

That leaves about 12.26 successful collisions each second and about 20.47 unsuccessful ones.

Current successful-collision rate

rate \approx 12.26 successful collisions/s

The box is busy, but most hits still fail the barrier test, so all-collision count and successful-collision rate need to be kept separate.

Common misconception

If concentration increases, then the reaction must speed up because every extra collision is automatically a successful one.

Higher concentration mainly creates more collision attempts.

Whether those attempts become reactions still depends on how many collisions clear the activation threshold.

Mini challenge

Make the reaction noticeably faster without relying on a very crowded box.

Make a prediction before you reveal the next step.

Decide whether you should change the collision frequency, the barrier, or the successful fraction before you try it.

Check your reasoning against the live bench.

You need a setup where a decent share of collisions clears the barrier even though concentration stays moderate.

That is the cleanest way to separate more collisions from more successful collisions. The rate rises because the successful fraction improves, not because the box is simply packed.

Quick test

Misconception check

Question 1 of 3

Answer from the live chemistry story, not from a memorized slogan.

Which statement is the most honest one?

Use the live bench to test the result before moving on.

Accessibility

The simulation shows a particle box with reactants moving inside it, plus visible cues for all collisions, successful collisions, and the barrier-clearing share. Sliders change temperature, concentration, and activation threshold, and a toggle applies a catalyst.

A readout card reports the current temperature, concentration, threshold, successful share, and successful-collision rate so the learner can compare the visual box with the graph response.

Graph summary

One graph compares all collision attempts with successful collisions as temperature changes, a second does the same for concentration, and a third shows the successful fraction against temperature.

Graph hover, compare mode, and the shared overlays all stay tied to the same chemistry bench instead of opening a separate view.

Keep the chemistry branch moving

Keep this idea moving

Open the next concept, route, or track only when you want the current model to widen into a larger branch.

Carry the collision story into a reversible system that re-balancesRates and Equilibrium