Good question. If you get the answer, notify those folk in Stockholm.
The states of matter and energy in the Big bang are so far away from our knowledge that the physics and math are beyond our ken.
[It has been said that just before the big Bang there was a sense of something about to happen.]
Some cosmologies suggest a Big Inflation, followed by a Big Collapse in a cyclic fashion. Fertile fields for the sci-fi writers, along with monopoles and FTL speeds.
The bonds holding the molecule together are made of energy, when these bonds are broken, the energy holding the molecule together is released.
The energy in a glucose molecule is stored in the bonds between the atoms.
The Strong Force.
In general "Heat", the higher the temperature the more energy the atom's or molecules have to brake the IMF forces holding them together or the bonding forces holding them together e.g. covalent bonds or ionic bonds.
Nuclear or nucleus binding energy are one and the same. IT is the force which is holding the nucleons together (protons and neutrons). Higher the binding energy , higher the stability of the nucleus.
Heat, or energy, is needed for evaporation to occur. Energy breaks bonds holding water molecules together, making evaporation possible.
because the energy is holding everything together. when they fall apart they release the energy. So as long as nothing causes them to fall apart, no explosions
It exploded when the flame on the engine ran out of energy and flamed the Challenger.
The bonded particles are constantly vibrating and as they are given more energy (such as by heating them) they convert that energy into kinetic energy meaning that they vibrate more until they vibrate fast enough to break the forces holding them together.
mostly gravitational energy produced by the exploded star.. and also many radiations if this is improved email me at : aditya.vardhan@rocketmail.com
Energy is released when the bonds holding the atoms together are broken. As the molecule size increases, so does the number chemical bonds needed to hold the structure together. These bonds contain energy, which enables the molecule to work. Lipids store a lot of energy.
That is an extremely odd way of phrasing it.The energy between two bonded atoms is the bond energy, but it's not the amount of energy required to "keep them held together", it's the energy required to pull them APART.If the atoms aren't bonded, then the force required to keep them together is a function of the distance between them (and the types of atoms they are). The usual approximation is the Lennard-Jones potential, which at the "holding them together" distance is usually described by a twelfth-degree polynomial, but I should stress again that this is an approximation.