The Bohr model only works for one electron species. Why do we discuss it in this text (what's good about it)?

The Bohr model, proposed by Niels Bohr in 1913, is an early model of atomic structure and only works for one-electron species like hydrogen and hydrogen-like ions (such as He+ and Li²⁺). The model successfully explains the hydrogen atom's energy levels, electron orbits, and quantized energy emissions.

One of the key advantages of the Bohr model is its simplicity. It offers a straightforward way to calculate the energy levels of hydrogen-like atoms. Using the Bohr model, we can easily determine the electron's energy in each orbit around the nucleus using the formula \(E_n = -\frac{13.6 eV}{n^2}\), where n is the principal quantum number (integer n≥1).

Even though the Bohr model has limitations, it sets the stage for the development of quantum mechanics. The idea of quantized energy levels and the wave-particle duality introduced by the model are fundamental concepts in quantum theory. These concepts were further elaborated and refined by scientists like Erwin Schrödinger, Werner Heisenberg, and Max Born, who contributed to the development of the modern quantum mechanics theory.

The Bohr model accurately predicts the hydrogen atoms' spectral lines, also known as the hydrogen emission spectrum. The model explains the observed spectral lines by the electrons absorbing or emitting photons. As the electrons transition between energy levels (orbits), they absorb or emit energy corresponding to the difference in energy levels. This energy difference is observed as discrete lines in the emission spectrum.

Despite its limitations, the Bohr model is widely discussed in educational settings because it serves as an excellent starting point for introducing the concept of atomic structure. The model's simplicity and visualization of electron orbits help students easily grasp the essentials of atomic theory. In conclusion, even though the Bohr model has its limitations, it is discussed in physics and chemistry texts because of its simplicity, ease of calculation, foundational role in quantum mechanics, the explanation of spectral lines in the hydrogen atom, and its educational value. While more advanced models like the Schrödinger model have surpassed the Bohr model, understanding the Bohr model helps students build a strong foundation for further learning in atomic and quantum physics.