Spectral Terms and Notations

Spectral Terms and Notation in Atomic Physics

Spectral terms provide a compact way of describing the quantum states of electrons in atoms. They summarize the total orbital angular momentum, spin, and multiplicity of a given electronic configuration.

General Form of a Spectral Term

A spectral term is written as:

$$^{2S+1}L_J$$

• S: Total electron spin quantum number.
• 2S+1: Multiplicity (singlet, doublet, triplet, etc.).
• L: Total orbital angular momentum, denoted by letters (S, P, D, F, ... for L=0,1,2,3,...).
• J: Total angular momentum, combining L and S, ranging from \( \lvert L+S \rvert \) to \( \lvert L-S \rvert \) in steps of 1.

Examples of Spectral Terms

(a) Hydrogen Ground State

The electron has spin \(S = \tfrac{1}{2}\) and orbital angular momentum \(L = 0\). Thus:

$$^{2}S_{1/2}$$

This represents a doublet-S state with total \(J = 1/2\).

(b) Helium \(1s2s\) Configuration

For two electrons, spins can pair to form either:

• Singlet state: \(S=0\), term \(^1S_0\)
• Triplet state: \(S=1\), term \(^3S_1\)

This splitting explains why helium exhibits both singlet and triplet spectral series.

Notes on Multiplicity

The multiplicity \(2S+1\) determines how many closely spaced energy levels appear. Higher multiplicity (like triplets) often correspond to lower energy due to electron exchange effects.

In short, spectral term notation provides a compact way to describe the structure of atomic energy levels.

Motion of a Block On an Inclined Plane

mg

mg sinθ

mg cosθ / N

f

Inclined Plane — Controls

Angle θ 30°

tanθ = 0.577

Material pair (μ_s, μ_k)

Wood on Wood — μs=0.4 μk=0.2 Ice on Ice — μs=0.1 μk=0.03 Rubber on Concrete — μs=1.0 μk=0.8 Steel on Steel — μs=0.8 μk=0.6 Teflon on Steel — μs=0.04 μk=0.02 Glass on Glass — μs=0.94 μk=0.4

Use the dropdown to pick preset friction coefficients.

μ_s 0.40

μ_k 0.20

Vector labels

Decomposition

High-contrast

Pause on tab change & keyboard accessible.

Static Friction: \( f_s \leq \mu_s N = \mu_s m g \cos\theta \)

Kinetic Friction: \( f_k = \mu_k N = \mu_k m g \cos\theta \)

Net Force (parallel): \( F_{\text{net}} = m g \sin\theta - f \)

Condition for motion: \( \tan\theta > \mu_s \)

Built for teaching — 3B1B-inspired visuals • Keyboard: Tab to controls • Mobile-friendly.

Projectile Motion With Air Drag Interactive Simulation

Projectile Motion — Interactive

A simple projectile motion simulation - tweak speed, angle, and see velocity vectors.

Speed

Angle

Height

Show Trail

Show Vector

Show Components

Vector Scale

Show Grid

Scale (px/m)

Simple Drag

g = 9.81 m/s²

Speed: 0 m/s

Velocity: (0,0) m/s

Time: 0.00 s

Position: (0,0) m

Max Height: 0.00 m

Time of Flight: 0.00 s

Kinetic Energy: 0 J

Potential Energy: 0 J

Total Energy: 0 J

Interactive projectile motion — energy and velocity visualization.

Atwood Machine

Atwood Machine Controls

Mass m₁ (kg)

3.0 kg

Mass m₂ (kg)

1.0 kg

Pulley radius R (m)

0.12 m

Pulley J (kg·m²)

0.000 kg·m²

Friction b (N·m·s)

0.020 N·m·s

Show Forces Show Trails

Legend — Vectors shown:
Tension, Weight.

$$\textbf{Equation for Acceleration}$$

$$ a = \frac{(m_1 - m_2)g - \dfrac{b}{R}\,\omega}{m_1 + m_2 + \dfrac{J}{R^2}} $$

Tip: change masses, pulley inertia (J) or friction (b) to see dynamics.

KAZ | Atwood Machine | Inspired by 3Blue1Brown

Interactive Simple Pendulum Simulation - A Simple, Simple Pendulum Simulator

Pendulum Controls & Energies

Length

Gravity

Amplitude

Damping

Show Angle Show Forces Show Trails

Energy (J)

Kinetic

0

Potential

0

Total

0

Legend — Vectors shown:
Tension, Weight, Restoring.

$$\textbf{Equation of Motion}$$

$$\frac{\mathrm{d^2} \theta}{\mathrm{d} t^2} + \frac{b}{{m}{L^2 }}\frac{\mathrm{d}\theta}{\mathrm{d} t} + \frac{g}{L}\sin\theta = 0$$

Tip: Adjust sliders to see effects. Equation governs motion.

KAZ | Inspired by 3Blue1Brown |