How to Degas Solvents

Contributed by Jeffrey Bode
Department of Chemistry
University of California, Santa Barbara

For many (possibly most) organic reactions, the presence of oxygen in a reaction is more detrimental than traces of H ₂O. If a reaction fails unexpectedly, it is a good idea to ensure an oxygen free environment, part of which entails degassing the reaction solvent.

Reactions that Require Degassing:

• Any reactions heated above 120 ^oC or heated for a prolonged period over 80 ^oC
  These reactions are typically performed in a sealed tube and are often run by heating over the boiling point of the solvent. Especially in the case of intramolecular reactions, the formation of a yellowish or brown color in the reaction is indicative of the presence of oxygen. High temperature reactions are extremely sensitive to oxygen and even the act of opening the reaction to take a sample for TLC analysis can introduce enough oxygen to destroy or damage the reaction
• Organometallic reactions
  For many organometallic reactions, it is essential to provide an oxygen free (and sometimes N ₂ free) environment. It is not uncommon to see strict procedures prescribing 10 cycles of freeze-pump-thaw (see below) degassing for the use of sensitive catalysts.
• Radical and photochemical reactions
  Unless oxidation is the desired product, radical reactions, for obvious reasons, must be degassed.
• Substrates containing thiols, thioethers, phosphines, electron-rich aromatic, etc
  Heating, solvents, or the presence of other reagents can often induce the oxidation of such substrates even when otherwise stable.

Methods of Degassing

• Freeze-Pump-Thaw
  This is the most effective methods for solvent degassing. A solvent in a sealed Schlenk or heavy wall sealed tube is frozen by immersion of the flask in liquid N ₂. When the solvent is completely frozen, the flask is opened to the vacuum (high vacuum) and pumped 2-3 minutes, with the flask still immersed in liquid N ₂. The flask is then closed and warmed until the solvent has completely melted. This process is repeated (usually three times) and after the last cycle the flask is backfilled with an inert gas. Degassed solvent in a sealed Schlenk flask can usually be kept for 1-2 days.
• Atmosphere Exchange Under Sonication
  Solvents can be roughly degassed by repeated sonication under light vacuum (i.e. house vacuum) for 0.5-1 min and replenishing the atmosphere with an inert solvent. By using 5-10 cycles, degassed solvents for HPLC and some reactions can be obtained quickly.
• Purging
  Of the methods listed here, purging is the least effective way of degassing solvent, however it is acceptable for some applications, particularly when large amounts of solvent need to be roughly degassed. As it sounds, purging consists of bubbling an inert gas (usually N ₂ or Ar) through the solvent for 30 min - 1 hour. Care should be taken to prevent solvent evaporation and especially the condensation of water in the solvent by using an appropriate setup.