Terahertz laser, terahertz source and use of such a terahertz laser

What is claimed is: 1. A terahertz laser adapted to emit at least a first electromagnetic radiation a first emission frequency of which is between 700 GHz and 1200 GHz, said laser including: an infrared laser source, a resonant optical cavity arranged to be optically pumped by the infrared laser source, the resonant optical cavity containing ammonia gas as an amplifier medium and having at least one configuration for which the resonant optical cavity is a resonant cavity at the first emission frequency, wherein the infrared laser source is a continuous semiconductor laser source capable of exciting molecules of the ammonia gas from an initial energy level to at least a first excited energy level, the molecules of the ammonia gas placed in this first excited energy level being likely to be de-excited by a pure inversion transition related to an umbrella type inversion mode of ammonia molecule, a de-excitation energy of which corresponds to the first emission frequency. 2. The terahertz laser according to claim 1 , wherein the infrared laser source is a quantum cascade laser. 3. The terahertz laser according to claim 2 , adapted to emit at least a second electromagnetic radiation a second emission frequency of which is between 700 GHz and 1200 GHz, wherein the infrared laser source is a quantum cascade laser tunable to a wavelength range including at least two wavelengths capable of exciting the molecules of the ammonia gas from the initial energy level to the first and a second excited energy level respectively, the molecules of the ammonia gas placed in this second excited energy level being likely to be de-excited by a pure inversion transition related to an umbrella type inversion mode of the ammonia molecule the de-excitation energy of which corresponds to the second emission frequency, the resonant optical cavity having at least one configuration for which the resonant optical cavity is a resonant cavity at the second emission frequency. 4. The terahertz laser according to claim 1 , wherein the first energy level excited by the infrared laser source is an energy level of vibration v 2 =1 accessible by a transition of the branch Q with a quantum number J lower than 10. 5. The terahertz laser according to claim 1 , wherein the ammonia gas is chosen from the group including ammonia the nitrogen atom of which is an isotope 14 , ammonia the nitrogen atom of which is an isotope 15 and a mixture thereof, and wherein the relative volume proportion in the amplifier medium of one from ammonia the nitrogen atom of which is the isotope 14 and ammonia the nitrogen atom of which is the isotope 15 is higher than 90%. 6. The terahertz laser according to claim 1 , wherein the ammonia gas is a mixture of ammonia the nitrogen atom of which is an isotope 14 and ammonia the nitrogen atom of which is the isotope 15 , the relative volume proportions in the amplifier medium of ammonia the nitrogen atom of which is the isotope 14 and ammonia the nitrogen atom of which is the isotope 15 being both between 40 and 60%. 7. The terahertz laser according to claim 1 , wherein the ammonia gas is a mixture of ammonia the nitrogen atom of which is an isotope 14 and ammonia the nitrogen atom of which is an isotope 15 , the resonant cavity being configured to enable the relative volume proportions in the amplifier medium of ammonia the nitrogen atom of which is the isotope 14 and ammonia the nitrogen atom of which is the isotope 15 to be modified. 8. The terahertz laser according to claim 1 , including at least one infrared optical fibre comprising a first and a second end, the first end being connected to the outlet of the infrared laser source and the second end being connected to the resonant optical cavity so as to provide an optical connection between the infrared laser source and the resonant optical cavity. 9. The terahertz laser ( 1 ) according to claim 1 , wherein the infrared laser source is adapted to emit a pump radiation to optically pump the resonant optical cavity ( 20 ), and wherein the resonant cavity includes an inlet for injecting the pump radiation, a surface area of the inlet being entirely circumscribed by a circle having a diameter lower than c/1,706f with c being the velocity of light and f the first emission frequency. 10. The terahertz laser according to claim 9 , wherein the diameter of the circle is lower than c/2f. 11. The terahertz laser according to claim 1 , wherein the outlet of the infrared laser source is positioned at the inlet of the resonant optical cavity. 12. The terahertz laser according to claim 9 , wherein the resonant optical cavity includes a converging lens arranged to decrease the divergence of the pump radiation at the outlet of the inlet. 13. A terahertz source adapted to emit at least a third electromagnetic radiation a third emission frequency of which is between 700 GHz and 1200 GHz, the terahertz source including: a terahertz laser according to claim 1 , a hyperfrequency source capable of emitting a hyperfrequency radiation the emission frequency of which is between 1 GHz and 200 GHz, a non-linear medium or device arranged to mix the first terahertz radiation provided by the terahertz laser and the hyperfrequency radiation to provide the third radiation. 14. A use of a terahertz laser ( 1 ) according to claim 1 , to perform imaging, spectroscopy, data transmission or obstacle detection in the terahertz range.