Suspended-membrane thermal detector comprising a deformable part for thermal short-circuit

The invention claimed is: 1. A thermal detector configured to detect electromagnetic radiation, comprising: a substrate; a membrane that absorbs electromagnetic radiation, thermally insulated with respect to the substrate, and comprising: a fixed detecting part comprising a thermometric transducer, a deformable thermal short-circuit part, comprising a fixed end assembled to the fixed detecting part, and an opposite free end, configured to deform under the effect of a temperature change of the absorbent membrane, so that the free end of the deformable part comes into contact with the substrate at a contact temperature T c of the absorbent membrane; wherein the deformable part: comprises a shape-memory alloy having an inverse martensitic transformation of a martensitic phase into an austenitic phase of said alloy between austenite start A s and austenite finish A f temperatures, and a direct martensitic transformation of the austenitic phase into the martensitic phase between martensite start M s and martensite finish M f temperatures, the austenite finish temperature A f being above the martensite start temperature M s , and is arranged with respect to the substrate in such a way that the free end is in contact with the substrate at the contact temperature T c above the austenite start temperature A s . 2. The thermal detector according to claim 1 , wherein the deformable part: has a maximum travel Δp max between a first position p r of the free end for a temperature T m of the absorbent membrane less than or equal to the martensite finish temperature M f , and a second position p d,max of the free end corresponding to a temperature T m greater than or equal to the austenite finish temperature A f , and is positioned with respect to the substrate in such a way that a maximum distance d max separating the free end occupying the first position p r and a contact surface of the substrate on which the free end is in contact at the contact temperature T c is less than or equal to the maximum travel Δp max . 3. The thermal detector according to claim 1 , wherein the shape-memory alloy is a metal alloy based on NiTi. 4. The thermal detector according to claim 1 , wherein the shape-memory alloy is a metal alloy selected from Ti 50.5 Ni 24.5 Pd 25 , Ti 85.3-x Ni x Hf 14.7 with x>50 at %, and Ti 7 Ni 11 Zr 43 Cu 39-x Co x with x>10 at %. 5. The thermal detector according to claim 1 , wherein the substrate has a contact surface on which the free end is in contact at the contact temperature T c , and in which the shape-memory alloy is in the form of a longitudinal strip between the fixed end and the free end, one face of which, oriented towards the contact surface of the substrate, has projecting features. 6. The thermal detector according to claim 1 , wherein the substrate has a flat upper face, and comprises a contact pad that extends from the upper face and has a contact surface on which the free end is in contact at the contact temperature T c . 7. The thermal detector according to claim 6 , wherein the contact pad is made of at least one heat-conducting material identical to that of the anchoring pillars. 8. The thermal detector according to claim 1 , wherein the substrate has a flat upper face, and in which the absorbent membrane is held above the upper face of the substrate by heat-insulating arms, and by anchoring pillars that extend approximately orthogonally to the plane of the upper face of the substrate. 9. A method for fabricating the thermal detector according to claim 1 , comprising the following steps: supplying a substrate having a contact surface; depositing at least one sacrificial layer; making anchoring pillars through the sacrificial layer; making heat-insulating arms and an absorbent membrane on the sacrificial layer, the absorbent membrane comprising a deformable part located opposite the contact surface; removing the sacrificial layer.