Matter tends to exist in its energy ground state. Both the nucleus and the electron cloud have energy states, representing different levels of excitation. The tendency is to return to ground or lowest state, and when that happens, a photon is emitted with charge representing the energy transition. When the photon comes from the nucleus, it is a gamma ray; when the photon comes from the electron cloud, it is an x-ray.
No matter or energy does not move. usually, frozen matter tends to move slower than warmer substances because if you heat up something, the atoms move more rapidly, moving into each other. If you do the opposite to that something, the atoms will slow down. -kos
Sliding friction tends to convert kinetic energy into thermal energy, thermal energy being heat, kinetic energy being movement.
The Second Law of Thermodynamics
There is no way to save thermal energy in the long term; heat tends to escape. You can reduce the losses by some isolation measures, as those used in a thermos bottle.There is no way to save thermal energy in the long term; heat tends to escape. You can reduce the losses by some isolation measures, as those used in a thermos bottle.There is no way to save thermal energy in the long term; heat tends to escape. You can reduce the losses by some isolation measures, as those used in a thermos bottle.There is no way to save thermal energy in the long term; heat tends to escape. You can reduce the losses by some isolation measures, as those used in a thermos bottle.
It tends to lose rotational energy due to friction.
Matter tends to exist in the lowest energy state. Atoms and molecules are constantly moving. When they are at a high energy state they are moving past each other and not interacting. This causes the matter to be unstable. When atoms and molecules are moving slowly, they interact more with each other and this makes the matter more stable.
the factors that effect the state of matter are:-temperaturepressurethe matter change their state because of the above. if the temperature increases the kinetic energy or the energy to move of the molecules and it tends to move away from each other that results in change of state. if the temperature decreases the kinetic energy decreases which pulls the molecules together and again results in the change of state.as the pressure increases the intermolecular space decreases and thereby changes the state like in the LPG (Liquefied Petroleum Gas) where petrol is pressurized to become liquid.thus we can conclude that the change of state of matter takes place to satisfy the surroundings of the matter.
Gases are only states of matter that can be compressed but tends to expand indefinitely.
Yes it tends to be more stable.
Where no matter exists, there is nothing to interfere with the rocket's motion through space. A body in motion tends to remain in motion, and if nothing interferes with that motion, the body will continue to move.
No. It tends to decrease.
It is in a solid state of matter. Unlike the deeper rocks of the mantle, crustal rocks do not readily deform, and heating from below will cause the lowest layers to melt into magma...which being less dense tends to flow upward.
Generally speaking, the state of matter tends to reflect the dissociation of bonds with increasing temperature. As you warm ice above 0 degrees Celcius, the fixed bonds of matter in the solid state disappear where one particular molecule is bonded to another specific molecule, and the matter turns into liquid. The intermolecular forces still exist, but the molecules do not associate with any particular other molecule anymore. When it turns to a gas above 100 degrees, the bond energy between molecules is no longer significant, and the molecules are free to roam in the gaseous state. Similar is true of transition with the bonds between atoms in the atomic lattice. This is a slight simplification as there are other states, for example there are intermediate states, also, at extremely low / cold temperatures the Einstein-Bose condensate may form where separate atoms may assume the same quantum state, and at extremely high temperatures, the electrons may dissociate from their nuclei and the matter enters the plasma state.
At lower energy, a system is more stable. At a higher energy, the system will have a tendency to achieve a lower energy. For example, a ball tends to roll down a slope, a compressed (or extended) spring tends to relax.At lower energy, a system is more stable. At a higher energy, the system will have a tendency to achieve a lower energy. For example, a ball tends to roll down a slope, a compressed (or extended) spring tends to relax.At lower energy, a system is more stable. At a higher energy, the system will have a tendency to achieve a lower energy. For example, a ball tends to roll down a slope, a compressed (or extended) spring tends to relax.At lower energy, a system is more stable. At a higher energy, the system will have a tendency to achieve a lower energy. For example, a ball tends to roll down a slope, a compressed (or extended) spring tends to relax.
No matter or energy does not move. usually, frozen matter tends to move slower than warmer substances because if you heat up something, the atoms move more rapidly, moving into each other. If you do the opposite to that something, the atoms will slow down. -kos
The system tends to attain the state of minimum potential energy, so the effect of static electricity wears out very fast.
Yes. And the molecular movement is depenadnt on the temperature. If the molecules move quickly, it tends to be in the gas state. If it slows, it may become liquid. If the movement is very slow, it would then be in a solid state.