Although Gill is psychic she has a very logical mind and is contantly curious to learn what, when, where, why and how?  Therefore sharing her knowledge for others to better understand:

The statement "Quantum energy cannot be destroyed" touches on fundamental principles in physics, particularly the law of conservation of energy and concepts from quantum mechanics.

• Conservation of Energy
  • The law of conservation of energy is a fundamental principle in physics which states that energy cannot be created or destroyed, only transformed from one form to another. This principle applies universally, including in the realm of quantum mechanics.

• Quantum Mechanics and Energy
  • In quantum mechanics, energy is often quantised, meaning it exists in discrete units or "quanta." For example, the energy levels of electrons in an atom are quantised, and electrons can only occupy specific energy levels.

• Energy Transitions
  • In quantum systems, energy transitions involve the absorption or emission of quanta, such as photons. When an electron in an atom moves to a higher energy level, it absorbs a photon (a quantum of light), and when it drops to a lower energy level, it emits a photon.

• Quantum Field Theory
  • In quantum field theory, particles are excitations of underlying fields. For example, photons are excitations of the electromagnetic field. The energy of these particles and fields is subject to the conservation of energy principle.

• Energy Conservation in Quantum Mechanics
  • Indestructibility of Energy. In the quantum realm, energy conservation holds true. While energy can change forms (such as potential energy converting to kinetic energy or vice versa), the total energy in a closed system remains constant. This means quantum energy, like all forms of energy, cannot be destroyed, only transformed.

Implications - Understanding energy conservation in quantum mechanics is crucial for technologies like lasers, semiconductors, and quantum computing. For instance, in lasers, electrons transition between energy levels, emitting photons of specific energies (light) without violating energy conservation.

• Quantum Entanglement and Information
  • In phenomena like quantum entanglement, energy conservation also plays a role. When two particles become entangled, their properties are linked, but the total energy of the system remains conserved.

In summary, the principle that "quantum energy cannot be destroyed" aligns with the broader law of conservation of energy. In quantum mechanics, energy is quantised and can transform between different states and forms, but the total energy in a closed system remains constant.