In physics and chemistry, "monatomic" is a combination of the words "mono" and "atomic", and means "single atom". It is usually applied to gases: a monatomic gas is a gas in which atoms are not bound to each other. Examples at standard conditions of temperature and pressure include all the noble gases (helium, neon, argon, krypton, xenon, and radon), though all chemical elements will be monatomic in the gas phase at sufficiently high temperature (or very low pressure). The thermodynamic behavior of a monatomic gas is much simpler when compared to polyatomic gases because it is free of any rotational or vibrational energy.
Noble gases
The only chemical elements that are stable single atoms (so they are not molecules) at standard temperature and pressure (STP) are the noble gases. These are helium, neon, argon, krypton, xenon, and radon. Noble gases have a full outer valence shell making them rather non-reactive species. While these elements have been described historically as completely inert, chemical compounds have been synthesized with all but neon and helium.
When grouped together with the homonuclear diatomic gases such as nitrogen (N2), the noble gases are called "elemental gases" to distinguish them from molecules that are also chemical compounds.
Thermodynamic properties
The only possible motion of an atom in a monatomic gas is translation (electronic excitation is not important at room temperature). Thus by the equipartition theorem, the kinetic energy of a single atom of a monatomic gas at thermodynamic temperature T is given by 
, where kB is the Boltzmann constant. One mole of atoms contains an Avogadro number (
) of atoms, so that the energy of one mole of atoms of a monatomic gas is 
, where R is the gas constant.
In an adiabatic process, monatomic gases have an idealised γ-factor (Cp/Cv) of 5/3, as opposed to 7/5 for ideal diatomic gases where rotation (but not vibration at room temperature) also contributes. Also, for ideal monatomic gases:
References
- "monatomic gas". Encyclopædia Britannica. Retrieved 6 June 2016.
- Laszlo, Pierre; Schrobilgen, Gary J. (1988-04-01). "Ein Pionier oder mehrere Pioniere? Die Entdeckung der Edelgas-Verbindungen". Angewandte Chemie. 100 (4): 495–506. Bibcode:1988AngCh.100..495L. doi:10.1002/ange.19881000406. ISSN 1521-3757.
- Christe, Karl O. (2001-04-17). "A Renaissance in Noble Gas Chemistry". Angewandte Chemie International Edition. 40 (8): 1419–1421. doi:10.1002/1521-3773(20010417)40:8<1419::aid-anie1419>3.0.co;2-j. ISSN 1521-3773. PMID 11317290.
- Heat Capacity of an Ideal Gas
- Heat Capacity of Ideal Gases
- Lecture 3: Thermodynamics of Ideal Gases & Calorimetry[permanent dead link], p. 2
In physics and chemistry monatomic is a combination of the words mono and atomic and means single atom It is usually applied to gases a monatomic gas is a gas in which atoms are not bound to each other Examples at standard conditions of temperature and pressure include all the noble gases helium neon argon krypton xenon and radon though all chemical elements will be monatomic in the gas phase at sufficiently high temperature or very low pressure The thermodynamic behavior of a monatomic gas is much simpler when compared to polyatomic gases because it is free of any rotational or vibrational energy Noble gasesThe only chemical elements that are stable single atoms so they are not molecules at standard temperature and pressure STP are the noble gases These are helium neon argon krypton xenon and radon Noble gases have a full outer valence shell making them rather non reactive species While these elements have been described historically as completely inert chemical compounds have been synthesized with all but neon and helium When grouped together with the homonuclear diatomic gases such as nitrogen N2 the noble gases are called elemental gases to distinguish them from molecules that are also chemical compounds Thermodynamic propertiesThe only possible motion of an atom in a monatomic gas is translation electronic excitation is not important at room temperature Thus by the equipartition theorem the kinetic energy of a single atom of a monatomic gas at thermodynamic temperature T is given by 32kBT displaystyle frac 3 2 k text B T where kB is the Boltzmann constant One mole of atoms contains an Avogadro number NA displaystyle N text A of atoms so that the energy of one mole of atoms of a monatomic gas is 32kBTNA 32RT displaystyle frac 3 2 k text B TN text A frac 3 2 RT where R is the gas constant In an adiabatic process monatomic gases have an idealised g factor Cp Cv of 5 3 as opposed to 7 5 for ideal diatomic gases where rotation but not vibration at room temperature also contributes Also for ideal monatomic gases the molar heat capacity at constant pressure Cp is 5 2 R 20 8 J K 1 mol 1 4 97 cal K 1 mol 1 the molar heat capacity at constant volume Cv is 3 2 R 12 5 J K 1 mol 1 2 98 cal K 1 mol 1 References monatomic gas Encyclopaedia Britannica Retrieved 6 June 2016 Laszlo Pierre Schrobilgen Gary J 1988 04 01 Ein Pionier oder mehrere Pioniere Die Entdeckung der Edelgas Verbindungen Angewandte Chemie 100 4 495 506 Bibcode 1988AngCh 100 495L doi 10 1002 ange 19881000406 ISSN 1521 3757 Christe Karl O 2001 04 17 A Renaissance in Noble Gas Chemistry Angewandte Chemie International Edition 40 8 1419 1421 doi 10 1002 1521 3773 20010417 40 8 lt 1419 aid anie1419 gt 3 0 co 2 j ISSN 1521 3773 PMID 11317290 Heat Capacity of an Ideal Gas Heat Capacity of Ideal Gases Lecture 3 Thermodynamics of Ideal Gases amp Calorimetry permanent dead link p 2
