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Energy in glucose is released. That energy is stored in ATP
the ATP molecule is broken down
The binding energy of the molecule compared to the binding energy of the ions it splits into when it is dissolved determines the change in heat of the water. The stronger a molecule is bound, the higher its binding energy and the more heat is needed to break it apart, which cools the water.
potential energy of a molecule is equivelent to the energy of the molecule in a fusion state
Reducing the size of a molecule gives that molecule greater potential energy because the molecule isn't using that energy since it is smaller. Being larger would make less potential energy.
Energy in glucose is released. That energy is stored in ATP
the ATP molecule is broken down
Nothing. For anything to happen at all, energy - more specifically, available energy - is required.
Adipose (or fat) will be used by the body if no carbohydrates are available.
The binding energy of the molecule compared to the binding energy of the ions it splits into when it is dissolved determines the change in heat of the water. The stronger a molecule is bound, the higher its binding energy and the more heat is needed to break it apart, which cools the water.
potential energy of a molecule is equivelent to the energy of the molecule in a fusion state
Energy is not 'matter', so it is not be a molecule.
Reducing the size of a molecule gives that molecule greater potential energy because the molecule isn't using that energy since it is smaller. Being larger would make less potential energy.
Glucose is the energy that is locked inside an organic molecule most readily accessible in.
The geometry of the molecule actually determines number of electron pairs on the central atom. The electron pairs will be arranged in such a way to minimize the repulsion and therefore, have the lowest possible energy.
Yes, quantum numbers define the energy states and the orbitals available to an electron. The principal quantum number (n) determines the energy level or shell of an electron, the azimuthal quantum number (l) determines the shape or orbital type, the magnetic quantum number (m) determines the orientation of the orbital, and the spin quantum number (+1/2 or -1/2) determines the spin state of the electron. Together, these quantum numbers provide a complete description of the electron's state within an atom.
Frequency determines the scalar energy of electromagnetic wave, E= hf=hc/r.