PCHM Jeopardy Template

Particle in a box

Harmonic Oscillator

Rotational motion

Quantum Behavior

Spectroscopy

100

In the particle-in-a-box model, the particle is confined between these types of walls.

infinitely high potential walls

100

This model approximates molecular vibrations.

harmonic oscillator

100

Rotational motion for a particle on a ring involves motion around this shape.

circle/ring

100

Quantum systems can only possess these allowed energy values.

quantized/discrete energy

100

Vibrational transitions are commonly observed using this type of spectroscopy.

infrared spectroscopy

200

The wavefunction for a particle in a box must equal this at the walls.

200

Unlike the particle in a box, the lowest energy of the harmonic oscillator is this value.

zero-point energy

200

Rotational energy depends on this molecular property.

moment of inertia

200

A standing wave forms only when this condition is satisfied.

constructive interference/boundary conditions

200

This model predicts equally spaced energy levels and a nonzero ground-state energy.

quantum harmonic oscillator

300

Energy levels in a particle in a box become more separated when the box becomes this.

smaller

300

The spacing between harmonic oscillator energy levels is this.

equally spaced

300

Rotational quantum numbers can be positive, negative, or this value

300

This explains why a particle cannot have zero energy in a box.

uncertainty principle

300

Absorption of energy causes transitions between these.

energy levels

400

This quantum number labels the allowed energy states in a 1D box.

400

Increasing the bond strength constant kkk causes vibrational frequency to do this.

increases

400

The angular momentum operator along the z-axis is represented by this symbol.

L^z

400

As quantum number increases, quantum behavior becomes more like this theory.

classical mechanics

400

The energy difference between quantum states determines this property of absorbed light.

frequency/wavelength

500

As the quantum number increases, the number of nodes changes in this way.

it increases

500

Lighter atoms vibrate at higher frequencies because frequency depends inversely on this quantity.

reduced mass

500

Rotational energy levels become closer together as the moment of inertia does this.

increases

500

Probability density is obtained from the wavefunction using this mathematical operation.

squaring the magnitude of the wavefunction

500

Spectroscopy works because molecules interact with electromagnetic radiation through these quantized motions.

vibrational and rotational motions