🌟 Nuclear Fusion in Stellar Cores

Stars generate and release energy primarily through nuclear fusion, which takes place in their extremely hot and dense cores. The conditions allow atomic nuclei to overcome electrostatic repulsion and undergo fusion.

During fusion, lighter nuclei (typically hydrogen) combine to form heavier elements (like helium). A small portion of mass is converted into energy, described by Einstein’s mass-energy equivalence:

E = Δm × c²

• E = energy released
• Δm = mass defect (mass lost)
• c = speed of light (3×10⁸ m/s)

🔁 The Proton-Proton Chain Reaction (in Sun-like Stars)

This is the primary fusion process in stars like our Sun. It occurs in several steps:

1. Step 1: p + p → ²H + e⁺ + ν_e
   Two protons fuse to form deuterium (¹H), releasing a positron and a neutrino.
2. Step 2: ²H + p → ³He + γ
   Deuterium captures another proton, forming helium-3 and emitting a gamma-ray.
3. Step 3: ³He + ³He → ⁴He + 2p
   Two helium-3 nuclei combine to form helium-4 and release two protons.

🔄 The net result is conversion of 4 hydrogen nuclei into 1 helium nucleus and energy in the form of radiation and kinetic energy.

🔥 The CNO Cycle (in More Massive Stars)

In stars heavier than the Sun, the carbon-nitrogen-oxygen (CNO) cycle dominates. It still converts hydrogen into helium, but uses carbon as a catalyst in a cyclic series of reactions.

The end result is the same: mass is converted into energy.

🚀 Energy Transport to the Surface

Energy produced in the stellar core travels outward through two mechanisms:

• Radiative Transport: Energy is carried by photons, which are absorbed and re-emitted through the radiative zone.
• Convective Transport: In outer, cooler layers, hot plasma moves, transferring heat via convection currents.

⚖️ Hydrostatic Equilibrium and Stellar Balance

The energy from fusion produces outward pressure that balances the inward pull of gravity. This balance is known as hydrostatic equilibrium, and it keeps the star stable.

If fusion slowed or stopped, gravity would dominate, potentially leading to collapse.