No. From what I understand, the Uncertainty Principle won't allow this - so even at absolute zero (a temperature that can't really be achieved 100%), there will still be some vibrational energy left.
Temperature measures kinetic energy on a molecular level, and kinetic energy depends upon two things, speed and mass. So, if the temperature is a constant (since you have specified STP) the lighter the molecule is, the faster it will be moving. The lightest molecule, of course, is hydrogen. So hydrogen moves the fastest of any molecule at a given temperature.
Wavelength is the distance from one molecule to the nearest molecule occupying a similar position and moving in the same direction.
conduction
kinetic energy. kinetic energy is moving energy and wind is moving.
by putting energy into a molecule ------------------------------------------------------------- Energy is mainly of two form. One is matter and the other is radiation. Due to radiation such a photon energy would be given to a molecule. That energy will be stored within the molecule in the form of electromagnetic fields and mechanical too. Sometimes fast moving material particles with their mechanical energy would energize a molecule. That too will be stored in the form of electric or magnetic or mechanical form.
It may be called a "wave." Waves are a type of vibration that carry energy from molecule to molecule through matter. A "wave" can also be electromagnetic energy, which does not require matter to propagate.
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.
No. From what I understand, the Uncertainty Principle won't allow this - so even at absolute zero (a temperature that can't really be achieved 100%), there will still be some vibrational energy left.
Temperature measures kinetic energy on a molecular level, and kinetic energy depends upon two things, speed and mass. So, if the temperature is a constant (since you have specified STP) the lighter the molecule is, the faster it will be moving. The lightest molecule, of course, is hydrogen. So hydrogen moves the fastest of any molecule at a given temperature.
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.
The cell transfers energy through the process of cellular respiration, where molecules such as glucose are broken down to produce ATP (adenosine triphosphate). ATP then serves as the energy currency in the cell, shuttling energy from molecule to molecule to drive cellular processes.
Wavelength is the distance from one molecule to the nearest molecule occupying a similar position and moving in the same direction.
Triglycerides are a common lipid for energy storage. Triglycerides help in the process of moving blood glucose and adipose fat from the liver.
Energy was released when the molecule was formed from its elements
conduction