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Abstract

At the low temperatures (approx. 10 K) and high densities (approx. 100 000 H₂ molecules per cm⁻³ ) of molecular cloud cores and protostellar envelopes, a large amount of molecular species (in particular those containing C and O) freeze-out onto dust grain surfaces. It is in these regions that the deuteration of H₃+ becomes very efficient, with a sharp abundance increase of H₂D+ and D₂H+. The multi-deuterated forms of H₃+ participate in an active chemistry: (i) their collision with neutral species produces deuterated molecules such as the commonly observed N₂D+, DCO+ and multi-deuterated NH₃; (ii) their dissociative electronic recombination increases the D/H atomic ratio by several orders of magnitude above the D cosmic abundance, thus allowing deuteration of molecules (e.g. CH₃OH and H₂O) on the surface of dust grains. Deuterated molecules are the main diagnostic tools of dense and cold interstellar clouds, where the first steps toward star and protoplanetary disc formation take place. Recent observations of deuterated molecules are reviewed and discussed in view of astrochemical models inclusive of spin-state chemistry. We present a new comparison between models based on complete scrambling (to calculate branching ratio tables for reactions between chemical species that include protons and/or deuterons) and models based on non-scrambling (proton hop) methods, showing that the latter best agree with observations of NH₃ deuterated isotopologues and their different nuclear spin symmetry states.