The Spacetime Metric
Level 1 · FoundationsGrades 8–9About 6 hours

Waves, resonance, and spectra

See how repeating disturbances carry energy and reveal hidden structure.

Learn amplitude, frequency, wavelength, interference, resonance, and spectra—the language needed for light, cavities, plasma, and quantum modes.

Established foundations

Before you begin

  • Course 1: Measurement
  • Course 2: Matter and fields

By the end, you can

  • Relate speed, frequency, and wavelength.
  • Predict constructive and destructive interference.
  • Explain resonance without implying energy appears from nowhere.
  • Read a spectrum as a physical fingerprint.

Interactive model

Explore before calculating

Two wave patterns showing motion parallel and perpendicular to the direction of travel.
Longitudinal and transverse describe how a disturbance moves relative to the direction the wave travels.

Live laboratory

Standing-wave atelier

Change the boundary length, mode number, and wave speed. The allowed patterns reveal why resonators select discrete frequencies.

Mode: n = 2

Wavelength: 2.00 m

Frequency: 60.0 Hz

The 3 amber points are nodes. Energy driving near 60.0 Hz can build this pattern, but the driver still supplies that energy.

Level 1 · Foundations teaching kit

Record the investigation. Teach the reasoning.

A learner-facing lab record and a course-specific instructor guide turn the live model into a repeatable classroom investigation.

Learner record

Standing-wave mode record

How do boundary length, wave speed, and integer mode number determine nodes, wavelength, and frequency?

Download learner record

Instructor guide

Teach for evidence, not button pushing

Learners connect boundary conditions with discrete modes and keep resonant response separate from energy creation.

Download instructor guide
Open the complete print-friendly teaching kit →

Lesson 1 of 3

Amplitude, frequency, and wavelength

Which features of a repeating pattern determine what we observe?

Amplitude measures the size of an oscillation; frequency counts cycles per second; wavelength measures the spatial repeat distance.

For a wave traveling at speed v, the relationship is v = fλ. Changing frequency changes wavelength when the speed in the medium is fixed.

amplitudefrequencywavelengthwave speed

Worked example

A wave travels at 12 m/s with a frequency of 3 Hz. Find its wavelength.

  1. 1. Start with v = fλ.
  2. 2. Rearrange: λ = v/f.
  3. 3. Compute 12/3.

The wavelength is 4 m.

Try it

Human wave timer

Materials: A rope or spring and a stopwatch.

  1. 1. Create slow regular pulses.
  2. 2. Count ten cycles.
  3. 3. Divide ten by elapsed seconds to find frequency.
  4. 4. Increase frequency while keeping the disturbance controlled.

Notice: Higher frequency packs cycles closer together when wave speed is approximately unchanged.

Check your understanding: If wave speed stays constant and frequency doubles, what happens to wavelength?

Answer: It halves.

The product fλ must remain equal to the unchanged speed.

Lesson 2 of 3

Interference and resonance

Why can two small disturbances combine into a large response—or cancel?

When waves overlap, their displacements add. In phase they reinforce; out of phase they partly or fully cancel.

Resonance occurs when repeated driving matches a system's natural mode. The large response draws energy from the driver over many cycles.

superpositionphaseinterferenceresonance

Worked example

Two equal waves arrive with opposite displacement at the same time.

  1. 1. Apply superposition.
  2. 2. Add +A and −A.
  3. 3. The instantaneous sum is zero.

They destructively interfere at that place and time; energy accounting still requires the full wave field.

Try it

Find a pendulum resonance

Materials: A string, small weight, and a support.

  1. 1. Build a pendulum.
  2. 2. Push at random intervals and note the response.
  3. 3. Then push gently once per natural swing.
  4. 4. Compare the amplitude after equal numbers of pushes.

Notice: Correctly timed small inputs accumulate; resonance amplifies transferred energy rather than creating it.

Check your understanding: Does resonance create energy?

Answer: No.

It efficiently transfers energy from a periodic driver into a matching natural mode.

Lesson 3 of 3

Spectra and allowed modes

How can a pattern of frequencies reveal what a system is made of?

A spectrum shows how much signal exists at each frequency. Atoms, molecules, cavities, and vibrating objects allow characteristic modes.

Boundary conditions determine which wave patterns fit. This ordinary idea becomes essential when studying electromagnetic cavities and the Casimir effect.

spectrummodeboundary conditionfrequency peak

Worked example

A string fixed at both ends has length 1 m. What is the longest standing-wave wavelength that fits?

  1. 1. The fundamental mode fits half a wavelength along the string.
  2. 2. Set L = λ/2.
  3. 3. Compute λ = 2L.

The fundamental wavelength is 2 m.

Try it

Sound spectrum explorer

Materials: A free spectrum-analyzer app or a browser audio visualizer.

  1. 1. Record a steady vowel.
  2. 2. Record a whistle at similar loudness.
  3. 3. Compare frequency peaks.
  4. 4. Change pitch and identify which peaks move.

Notice: Similar loudness can hide very different frequency structures.

Check your understanding: What selects the allowed standing-wave modes in a cavity?

Answer: Its boundary conditions and geometry.

Only patterns satisfying the constraints at the boundaries persist as modes.

Continue into the evidence