⚛️Intro to Quantum Mechanics I Unit 10 – Hydrogen Atom and Atomic Orbitals

The hydrogen atom serves as a fundamental model for understanding atomic structure and quantum mechanics. Its single proton and electron provide a simple system to study quantum numbers, atomic orbitals, and energy levels. These concepts form the basis for more complex atomic systems. Quantum numbers describe the unique state of an electron, while atomic orbitals represent the probability distribution of electrons in space. The Schrödinger equation allows us to calculate wave functions and energy levels, providing a mathematical framework for the behavior of matter at atomic scales.

Study Guides for Unit 10

10.1

Schrödinger equation for the hydrogen atom

3 min read

10.2

Quantum numbers and atomic orbitals

4 min read

10.3

Electron spin and the Zeeman effect

4 min read

10.4

Multi-electron atoms and the periodic table

3 min read

Key Concepts

Quantum mechanics provides a mathematical framework for describing the behavior of matter and energy at the atomic and subatomic scales
The hydrogen atom, consisting of a single proton and electron, serves as a fundamental model for understanding atomic structure and quantum mechanics
Quantum numbers ( $n$ $n$ , $l$ $l$ , $m_l$ $m_{l}$ , and $m_s$ $m_{s}$ ) describe the unique state of an electron in an atom, including its energy, angular momentum, and spin
- Principal quantum number ( $n$ ) determines the main energy level and size of the orbital
- Azimuthal quantum number ( $l$ ) describes the shape of the orbital and the magnitude of the electron's angular momentum
- Magnetic quantum number ( $m_l$ ) specifies the orientation of the orbital in space relative to an external magnetic field
- Spin quantum number ( $m_s$ ) represents the intrinsic angular momentum of the electron
Atomic orbitals are mathematical functions that describe the probability distribution of an electron in an atom
- Orbitals are labeled based on their quantum numbers ( $1s$ , $2p$ , $3d$ , etc.)
- The shape and orientation of orbitals are determined by the azimuthal and magnetic quantum numbers
The Schrödinger equation is the fundamental equation in quantum mechanics used to determine the wave function and energy levels of a system, such as the hydrogen atom
The electron probability distribution describes the likelihood of finding an electron at a particular location within an atom
- The square of the wave function ( $|\Psi|^2$ ) gives the probability density of the electron
Spectroscopy techniques, such as absorption and emission spectroscopy, provide experimental evidence for the quantized energy levels in atoms
- Transitions between energy levels result in the absorption or emission of photons with specific frequencies

Historical Background

In the early 20th century, the classical model of the atom, known as the Rutherford model, failed to explain the stability of atoms and the discrete nature of atomic spectra
Max Planck introduced the concept of quantized energy in 1900 to explain the blackbody radiation spectrum, laying the foundation for quantum mechanics
- Planck proposed that energy is absorbed or emitted in discrete packets called quanta
In 1913, Niels Bohr developed a model of the hydrogen atom that incorporated quantized energy levels and successfully explained the observed spectral lines
- Bohr's model postulated that electrons orbit the nucleus in fixed, circular orbits with specific energies
- Transitions between these orbits result in the absorption or emission of photons with specific frequencies
Louis de Broglie proposed the wave-particle duality in 1924, suggesting that particles, such as electrons, can exhibit wave-like properties
- The de Broglie wavelength ( $\lambda = h/p$ ) relates the wavelength of a particle to its momentum
Werner Heisenberg introduced the uncertainty principle in 1927, stating that the position and momentum of a particle cannot be simultaneously determined with arbitrary precision
Erwin Schrödinger developed the wave equation in 1926, which describes the behavior of a quantum system and forms the basis for modern quantum mechanics
- The Schrödinger equation allows for the calculation of wave functions and energy levels for atoms and molecules

Quantum Numbers

Quantum numbers are a set of four integers that uniquely describe the state of an electron in an atom
The principal quantum number ( $n$ $n$ ) represents the main energy level and the average distance of the electron from the nucleus
- $n$ can take positive integer values (1, 2, 3, ...)
- Higher values of $n$ correspond to higher energy levels and larger orbital sizes
The azimuthal quantum number ( $l$ $l$ ) describes the shape of the orbital and the magnitude of the electron's angular momentum
- $l$ can take integer values from 0 to $n-1$
- $l$ values of 0, 1, 2, and 3 correspond to $s$ , $p$ , $d$ , and $f$ orbitals, respectively
The magnetic quantum number ( $m_l$ $m_{l}$ ) specifies the orientation of the orbital in space relative to an external magnetic field
- $m_l$ can take integer values from $-l$ to $+l$ , including 0
- Different $m_l$ values correspond to different orientations of the orbital (e.g., $p_x$ , $p_y$ , $p_z$ )
The spin quantum number ( $m_s$ $m_{s}$ ) represents the intrinsic angular momentum of the electron
- $m_s$ can take values of $+1/2$ (spin up) or $-1/2$ (spin down)
- The Pauli exclusion principle states that no two electrons in an atom can have the same set of four quantum numbers

Atomic Orbitals

Atomic orbitals are mathematical functions that describe the probability distribution of an electron in an atom
Orbitals are labeled based on their quantum numbers, with the general notation $nl$ $n l$ , where $n$ $n$ is the principal quantum number and $l$ $l$ is the azimuthal quantum number
- Examples of orbital labels include $1s$ , $2s$ , $2p$ , $3s$ , $3p$ , $3d$ , etc.
The shape of an orbital is determined by the azimuthal quantum number ( $l$ $l$ )
- $s$ orbitals ( $l=0$ ) are spherically symmetric
- $p$ orbitals ( $l=1$ ) have two lobes with a node at the nucleus and are oriented along the $x$ , $y$ , or $z$ axes
- $d$ orbitals ( $l=2$ ) have more complex shapes, such as cloverleaf or double-lobed configurations
The size of an orbital is primarily determined by the principal quantum number ( $n$ ), with larger $n$ values corresponding to larger orbitals
Orbitals with the same principal quantum number form an electron shell, while orbitals with the same principal and azimuthal quantum numbers form a subshell
The orientation of orbitals in space is described by the magnetic quantum number ( $m_l$ $m_{l}$ )
- For example, $p$ orbitals have three possible orientations: $p_x$ ( $m_l=-1$ ), $p_y$ ( $m_l=0$ ), and $p_z$ ( $m_l=+1$ )

Hydrogen Atom Model

The hydrogen atom, consisting of a single proton and electron, is the simplest atomic system and serves as a fundamental model for understanding atomic structure
In the Bohr model, the electron orbits the proton in fixed, circular orbits with specific energies
- The energy levels in the Bohr model are given by $E_n = -13.6 eV / n^2$ , where $n$ is the principal quantum number
- Transitions between energy levels result in the absorption or emission of photons with specific frequencies
The Schrödinger equation provides a more accurate description of the hydrogen atom by treating the electron as a wave function
- The time-independent Schrödinger equation for the hydrogen atom is $-(\hbar^2/2m)\nabla^2\Psi + V(r)\Psi = E\Psi$ , where $\hbar$ is the reduced Planck's constant, $m$ is the electron mass, $V(r)$ is the Coulomb potential, and $E$ is the energy eigenvalue
- Solutions to the Schrödinger equation give the wave functions (orbitals) and energy levels of the hydrogen atom
The energy levels of the hydrogen atom are quantized and depend only on the principal quantum number ( $n$ $n$ )
- The ground state of the hydrogen atom has $n=1$ and an energy of $-13.6 eV$
- Excited states have higher $n$ values and correspond to higher energy levels
The orbital angular momentum of the electron in the hydrogen atom is quantized and depends on the azimuthal quantum number ( $l$ )
The electron's magnetic moment, which arises from its spin, interacts with the magnetic field generated by its orbital motion, resulting in fine structure splitting of energy levels

Electron Probability Distributions

The electron probability distribution describes the likelihood of finding an electron at a particular location within an atom
The probability density is given by the square of the absolute value of the wave function, $|\Psi(r, \theta, \phi)|^2$ $∣Ψ (r, θ, ϕ) ∣^{2}$
- The wave function $\Psi(r, \theta, \phi)$ is a complex-valued function that depends on the radial distance ( $r$ ), polar angle ( $\theta$ ), and azimuthal angle ( $\phi$ )
- The probability of finding an electron in a small volume element $dV$ is given by $|\Psi(r, \theta, \phi)|^2 dV$
Radial probability distribution functions, $P(r)$ $P (r)$ , describe the probability of finding an electron at a certain distance from the nucleus
- $P(r)$ is obtained by integrating the probability density over the angular coordinates ( $\theta$ and $\phi$ )
- Radial nodes, where $P(r)=0$ , correspond to distances where the probability of finding an electron is zero
Angular probability distribution functions, $P(\theta, \phi)$ $P (θ, ϕ)$ , describe the probability of finding an electron in a particular direction relative to the nucleus
- $P(\theta, \phi)$ is obtained by integrating the probability density over the radial coordinate ( $r$ )
- Angular nodes, where $P(\theta, \phi)=0$ , correspond to directions in which the probability of finding an electron is zero
The shapes of atomic orbitals are directly related to the angular probability distributions
- For example, the angular probability distribution of a $p_z$ orbital has two lobes along the $z$ -axis, with a node in the $xy$ -plane

Spectroscopy and Energy Levels

Spectroscopy is the study of the interaction between matter and electromagnetic radiation
Atomic spectroscopy techniques, such as absorption and emission spectroscopy, provide experimental evidence for the quantized energy levels in atoms
Absorption spectroscopy involves measuring the wavelengths or frequencies of light that an atom absorbs
- When an atom absorbs a photon, an electron transitions from a lower energy level to a higher energy level
- The energy of the absorbed photon must match the energy difference between the two levels, $\Delta E = hf$ , where $h$ is Planck's constant and $f$ is the frequency of the photon
Emission spectroscopy involves measuring the wavelengths or frequencies of light that an atom emits
- When an electron transitions from a higher energy level to a lower energy level, a photon is emitted with energy equal to the difference between the levels
- The emitted photons form an emission spectrum, which consists of discrete spectral lines corresponding to specific energy level transitions
The spectral lines in the hydrogen atom's emission spectrum are named after the scientists who studied them
- The Lyman series corresponds to transitions from higher energy levels to the $n=1$ level and lies in the ultraviolet region
- The Balmer series corresponds to transitions from higher energy levels to the $n=2$ level and lies in the visible region
- The Paschen, Brackett, and Pfund series correspond to transitions to the $n=3$ , $n=4$ , and $n=5$ levels, respectively, and lie in the infrared region
Fine structure splitting of spectral lines occurs due to the interaction between the electron's spin and its orbital angular momentum
- The fine structure splitting is smaller than the energy differences between principal energy levels and requires high-resolution spectroscopy to resolve
Hyperfine structure splitting arises from the interaction between the electron's magnetic moment and the magnetic moment of the nucleus
- Hyperfine structure splitting is even smaller than fine structure splitting and is observed in high-precision spectroscopic measurements

Applications and Real-World Examples

Atomic clocks, which are among the most accurate timekeeping devices, rely on the precise frequency of atomic transitions
- Cesium-133 atoms are commonly used in atomic clocks due to the stability and precision of their hyperfine transition frequency
- GPS satellites and other global navigation systems rely on atomic clocks for accurate timing and positioning
Lasers, which produce coherent and monochromatic light, operate based on the principles of atomic energy levels and transitions
- Population inversion, where more atoms are in an excited state than in the ground state, is achieved through pumping techniques
- Stimulated emission of photons with a specific frequency occurs when excited atoms are triggered to release their energy
- Examples of laser applications include fiber-optic communication, laser surgery, and materials processing
Quantum computing and quantum information processing exploit the properties of quantum systems, such as atomic energy levels and superposition states
- Quantum bits (qubits) can be implemented using the energy levels of atoms or ions
- Atomic qubits have been used to demonstrate quantum algorithms, such as Shor's algorithm for factoring large numbers
Spectroscopic techniques are widely used in various fields, such as astronomy, chemistry, and materials science
- Astronomical spectroscopy allows for the determination of the composition, temperature, and velocity of celestial objects
- In chemistry, spectroscopy is used to identify compounds, study reaction mechanisms, and analyze molecular structures
- Materials science utilizes spectroscopic methods to characterize the electronic, optical, and magnetic properties of materials
Atomic physics and quantum mechanics have led to the development of advanced imaging techniques, such as scanning tunneling microscopy (STM) and atomic force microscopy (AFM)
- STM and AFM provide high-resolution images of surfaces at the atomic scale, enabling the study of individual atoms and molecules
- These techniques have revolutionized fields such as nanotechnology, surface science, and materials engineering