The disclosure relates in its first aspect to a process of conversion of a gaseous stream comprising methane into hydrogen (51) and carbon (25), the process is remarkable in that it comprises a step (a) of providing a first gaseous stream (3, 7); a step (b) of bromination and synthesis in which the first gaseous stream (3, 7) is put in contact with a second stream (53) comprising bromine resulting in the formation of a third stream (15) comprising methyl bromides and hydrogen bromide, and of a fourth stream (25) comprising carbon including graphite and/or carbon black; a step (c) of separation performed on the third stream (15) to recover a hydrogen bromide-rich stream (41) which is then oxidized in a step (d) to produce a stream (51) comprising hydrogen. The second aspect relates to the installation for performing the process of the first aspect and the third aspect concerns the use of bromine in such process.

The disclosure relates in its first aspect to a process of conversion of a gaseous stream comprising methane into hydrogen (51) and carbon (25), the process is remarkable in that it comprises a step (a) of providing a first gaseous stream (3, 7); a step (b) of bromination and synthesis in which the first gaseous stream (3, 7) is put in contact with a second stream (53) comprising bromine resulting in the formation of a third stream (15) comprising methyl bromides and hydrogen bromide, and of a fourth stream (25) comprising carbon including graphite and/or carbon black; a step (c) of separation performed on the third stream (15) to recover a hydrogen bromide-rich stream (41) which is then oxidized in a step (d) to produce a stream (51) comprising hydrogen. The second aspect relates to the installation for performing the process of the first aspect and the third aspect concerns the use of bromine in such process.

Provided is a production method that enables production of monofluoromethane by a gas phase flow method without using a catalyst. The method of producing monofluoromethane includes causing electrical discharge of a feedstock gas containing a fluorine-containing inorganic compound, a compound represented by formula 1: CH.sub.3—R (R is a hydrogen atom, a chlorine atom, a bromine atom, an iodine atom, or an organic group other than a hydrocarbon group), and an inert gas, while in a continuous flow state, and then causing continuous release to outside of an electrical discharge zone.

Provided is a production method that enables production of monofluoromethane by a gas phase flow method without using a catalyst. The method of producing monofluoromethane includes causing electrical discharge of a feedstock gas containing a fluorine-containing inorganic compound, a compound represented by formula 1: CH.sub.3—R (R is a hydrogen atom, a chlorine atom, a bromine atom, an iodine atom, or an organic group other than a hydrocarbon group), and an inert gas, while in a continuous flow state, and then causing continuous release to outside of an electrical discharge zone.

A process for producing a reaction mixture comprising a plurality of C.sub.3 chlorinated alkane isomers comprising chlorinating a C.sub.3 chlorinated alkane starting material in a chlorination zone to produce the plurality of C.sub.3 chlorinated alkane isomers, the plurality of C.sub.3 chlorinated alkane isomers each having at least one more chlorine atom than the C.sub.3 chlorinated alkane starting material, wherein the concentration of the C.sub.3 chlorinated alkane starting material is controlled such that conversion of the C.sub.3 chlorinated alkane starting material to the plurality of C.sub.3 chlorinated alkane isomers, represented by the molar ratio of the C.sub.3 chlorinated alkane starting material:C.sub.3 chlorinated alkane isomers in the reaction mixture present in the chlorination zone, does not exceed about 40:60.

A process for producing a reaction mixture comprising a plurality of C.sub.3 chlorinated alkane isomers comprising chlorinating a C.sub.3 chlorinated alkane starting material in a chlorination zone to produce the plurality of C.sub.3 chlorinated alkane isomers, the plurality of C.sub.3 chlorinated alkane isomers each having at least one more chlorine atom than the C.sub.3 chlorinated alkane starting material, wherein the concentration of the C.sub.3 chlorinated alkane starting material is controlled such that conversion of the C.sub.3 chlorinated alkane starting material to the plurality of C.sub.3 chlorinated alkane isomers, represented by the molar ratio of the C.sub.3 chlorinated alkane starting material:C.sub.3 chlorinated alkane isomers in the reaction mixture present in the chlorination zone, does not exceed about 40:60.

A process for producing a reaction mixture comprising a plurality of C.sub.3 chlorinated alkane isomers comprising chlorinating a C.sub.3 chlorinated alkane starting material in a chlorination zone to produce the plurality of C.sub.3 chlorinated alkane isomers, the plurality of C.sub.3 chlorinated alkane isomers each having at least one more chlorine atom than the C.sub.3 chlorinated alkane starting material, wherein the concentration of the C.sub.3 chlorinated alkane starting material is controlled such that conversion of the C.sub.3 chlorinated alkane starting material to the plurality of C.sub.3 chlorinated alkane isomers, represented by the molar ratio of the C.sub.3 chlorinated alkane starting material:C.sub.3 chlorinated alkane isomers in the reaction mixture present in the chlorination zone, does not exceed about 40:60.

A method of producing carbon tetrachloride, the method comprising the step of reacting chlorine with chloroform in the presence of electromagnetic radiation within a reaction mixture that includes the chlorine, the chloroform, and carbon tetrachloride, where the concentration of chloroform is less than 5000 ppm by weight relative to the weight of the reaction mixture, where the reaction mixture includes at least stoichiometric levels of chlorine relative to chloroform, where the electromagnetic radiation creates chloride radicals, and where the reaction mixture is well mixed.

A method of producing carbon tetrachloride, the method comprising the step of reacting chlorine with chloroform in the presence of electromagnetic radiation within a reaction mixture that includes the chlorine, the chloroform, and carbon tetrachloride, where the concentration of chloroform is less than 5000 ppm by weight relative to the weight of the reaction mixture, where the reaction mixture includes at least stoichiometric levels of chlorine relative to chloroform, where the electromagnetic radiation creates chloride radicals, and where the reaction mixture is well mixed.

A method of producing carbon tetrachloride, the method comprising the step of reacting chlorine with chloroform in the presence of electromagnetic radiation within a reaction mixture that includes the chlorine, the chloroform, and carbon tetrachloride, where the concentration of chloroform is less than 5000 ppm by weight relative to the weight of the reaction mixture, where the reaction mixture includes at least stoichiometric levels of chlorine relative to chloroform, where the electromagnetic radiation creates chloride radicals, and where the reaction mixture is well mixed.