The more energy a molecule can absorb in the form of internal vibrations and rotation, the higher the heat capacity will be. As an example, the heat capacity of an ideal gas depends on the number of moles, not the mass of the gas. The noble gases - which are monatomic, follow this fairly well at low pressures and reasonably warm temperatures since they have no atom-atom bonds to vibrate, nor do they have any significant rotational energy. Diatomic (and for that matter any polyatomic) gases however, deviate from this a bit because their energy content is not only determined by the kinetic energy of the molecules, but also by the rotational and vibrational energies.
Low specific heats
Funtional Residual Capacity amounts
Diffusion keeps the amounts of molecules inside and outside the cell in balance, or in a state of homeostasis.
Diffusion keeps the amounts of molecules inside and outside the cell in balance, or in a state of homeostasis.
Diffusion keeps the amounts of molecules inside and outside the cell in balance, or in a state of homeostasis.
Diffusion keeps the amounts of molecules inside and outside the cell in balance, or in a state of homeostasis.
Diffusion keeps the amounts of molecules inside and outside the cell in balance, or in a state of homeostasis.
There is the pan capacity and the system capacity. These are two different amounts. Your owner's manual will list these.
Covalent molecules with small amounts of argon which is monatomic. All molecules are covalent. Ionic compounds form crystals, not molecules.
Many molecules such as organic molecules have significantly large amounts of atoms such as sugar/sucrose (C12H22O11). Others have more Many molecules such as organic molecules have significantly large amounts of atoms such as sugar/sucrose (C12H22O11). There other molecules such as DNA and polymers that have no size limit and there is no maximum size of a molecule.
Signal molecules 😂
Gases.