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Concept module

Atomic Spectra

Link discrete emission and absorption lines to allowed energy-level gaps with one compact ladder-and-spectrum bench that keeps transitions, wavelengths, and mode changes tied together.

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Starter track

Step 2 of 50 / 5 complete

Modern Physics

Earlier steps still set up Atomic Spectra.

1. Photoelectric Effect2. Atomic Spectra3. de Broglie Matter Waves4. Bohr Model+1 more steps

Previous step: Photoelectric Effect.

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Why it behaves this way

Explanation

Atomic spectra are the bounded modern-physics case where light does not come out in every color. When an atom changes between allowed energy levels, it can emit or absorb only photons whose energy matches one of those level gaps, so the spectrum breaks into discrete lines instead of a smooth rainbow.

This module keeps one energy ladder, one observed spectrum strip, one wavelength graph, and one shared set of readouts. The same gaps drive the stage, overlays, worked examples, challenge checks, compare mode, quick test, and read-next cues, so the learner keeps one honest link between energy changes and spectral lines instead of drifting into a detached derivation page.

Key ideas

01Each spectral line comes from one allowed energy difference, not from any arbitrary wavelength.

02Larger energy gaps make shorter-wavelength photons, while smaller gaps make longer-wavelength photons.

03Emission and absorption use the same allowed wavelengths because they come from the same level differences.

04This compact ladder is a bounded precursor to later Bohr-style level models: it emphasizes line positions and energy differences without claiming full atomic structure.

Frozen walkthrough

Step through the frozen example

Frozen walkthrough

Use the current ladder and spectrum state directly from the live bench. The same gaps and mode setting drive the stage, the spectrum graph, the overlays, and the worked result.

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Frozen valuesUsing frozen parameters

With gaps 1.9 eV, 2.6 eV, and 2.7 eV, which visible lines should the current ladder produce?

Δ E_{2 \to 1}

Level 2 to 1 gap

1.9 eV eV

Δ E_{3 \to 2}

Level 3 to 2 gap

2.6 eV eV

Δ E_{4 \to 3}

Level 4 to 3 gap

2.7 eV eV

1. Convert the 2 -> 1 gap to a wavelength

For the current ladder,

Δ E_{2 \to 1} = 1.9 e V

, so the 2 -> 1 line sits near 652.55 nm.

2. Convert another allowed gap

The 3 -> 2 gap is 2.6 eV, so that line lands near 476.86 nm.

3. Read the visible pattern honestly

On the live spectrum, the current gap set gives 3 visible lines between 459.2 nm and 652.55 nm.

Current visible pattern

λ_{2 \to 1} = 652.55 nm, λ_{3 \to 2} = 476.86 nm, 3 v i s ib l e l in es

The current lower-level gaps create at least two visible lines, and the smaller gap 1.9 eV lands at the longer visible wavelength 652.55 nm.

Line-pattern checkpoint

A spectrum shows only a few narrow lines instead of every visible color. What is the strongest bounded explanation on this page?

Make a prediction before you reveal the next step.

Answer from the allowed energy gaps, not from the color labels alone.

Check your reasoning against the live bench.

The atom can change only between allowed energy levels, so it can emit or absorb only the photon energies that match those level differences.

Discrete level gaps create discrete photon energies. The page stays bounded by showing only that line-pattern logic, without claiming a full atom-by-atom derivation.

Common misconception

Emission lines and absorption lines should appear at different wavelengths because one process sends light out and the other takes light in.

The same allowed level gaps set both processes, so the allowed wavelengths match.

What changes is the appearance of the spectrum: emission gives bright lines, while absorption removes those same wavelengths from a background continuum.

Quick test

Reasoning

Question 1 of 4

Answer from the live line-spectrum logic, not from disconnected labels.

Why does this bounded atomic-spectrum page show discrete lines instead of a smooth visible rainbow?

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

Accessibility

The simulation shows a four-level energy ladder on the left and a compact observed-spectrum strip on the right. Colored arrows mark allowed level changes, and the active transition is linked to a matching wavelength in the spectrum strip.

Optional overlays can label each line, lock emission and absorption to the same wavelengths, and call out why only a few wavelengths appear. The readout card summarizes the current mode, active level pair, photon energy, wavelength, visible-line count, visible-band edges, and minimum visible spacing.

Graph summary

The spectrum graph plots relative intensity against wavelength from ultraviolet through visible to infrared. In emission mode, the graph shows narrow bright peaks on a dark baseline. In absorption mode, it shows dark notches carved out of a flat continuum reference at those same wavelengths.

Carry the line story forward

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Wave bridge to quantizationModern Physics