Wireless thermionic sensor

What is claimed is: 1 . A thermionic sensor comprising: a sensor housing at least partially defining an emission chamber in which vacuum conditions are maintained; a cathode disposed in the emission chamber; an anode disposed in the emission chamber and spaced apart from the cathode; and an electrically conductive layer disposed in the emission chamber facing the anode and cathode, wherein the thermionic sensor is configured to output a detection signal when the anode and cathode are at substantially the same temperature. 2 . The thermionic sensor of claim 1 , wherein the sensor housing comprises a substantially non-porous ceramic material. 3 . The thermionic sensor of claim 1 , wherein the emission chamber is maintained at a pressure of less than about 100 micro Torr. 4 . The thermionic sensor of claim 1 , wherein the cathode comprises tungsten alloyed with about 0.2% to about 5.0 wt % of a rare earth element, based on the total weight of the cathode. 5 . The thermionic sensor of claim 4 , wherein the rare earth element comprises lanthanum. 6 . The thermionic sensor of claim 1 , wherein the anode comprises substantially pure tungsten. 7 . The thermionic sensor of claim 1 , wherein: the sensor housing comprises a flexible portion configured to flex in response to an amount of ambient pressure applied to the sensor housing; and the electrically conductive layer is attached to the flexible portion, such that a distance between the electrically conductive layer and the cathode and anode changes in accordance with the amount of ambient pressure. 8 . The thermionic sensor of claim 1 , further comprising a refractory metal encasing the sensor housing. 9 . The thermionic sensor of claim 1 , wherein the sensor is configured to detect the temperature or pressure of an ambient environment. 10 . The thermionic sensor of claim 1 , wherein the anode comprises: an outer anode disposed around the cathode; and an inner anode disposed between the outer anode and the cathode, the inner and outer anodes being spaced apart from one another. 11 . The thermionic sensor of claim 1 , wherein the sensor housing comprises: a bottom plate upon which the cathode and the anode are disposed; and a top plate disposed on the bottom plate and upon which the conductive layer is disposed. 12 . The thermionic sensor of claim 11 , further comprising a spacer disposed between the top plate and the bottom plate. 13 . The thermionic sensor of claim 1 , wherein: one of the cathode and the anode is circular; and the other of the cathode and the anode is C-shaped. 14 . The thermionic sensor of claim 1 , wherein the cathode and the anode are spaced apart by a substantially constant minimum distance. 15 . The thermionic sensor of claim 1 , further comprising a substrate, wherein, the substrate and the housing cooperate to define the emission chamber, and the anode and the cathode are disposed on the substrate. 16 . A thermionic sensor comprising: a sensor housing comprising a substantially non-porous ceramic material and at least partially defining an emission chamber that is maintained at a pressure of less than about 100 micro Torr; a cathode disposed in the emission chamber; an anode disposed in the emission chamber and spaced apart from the cathode; and an electrically conductive layer disposed in the emission chamber facing the anode and cathode. 17 . The thermionic sensor of claim 16 , wherein the thermionic sensor is configured to output a detection signal when the anode and cathode are at substantially the same temperature. 18 . The thermionic sensor of claim 11 , further comprising a substrate on which the sensor housing is disposed, the substrate comprising the substantially non-porous ceramic material. 19 . The thermionic sensor of claim 11 , wherein the thermionic sensor is configured to: apply a bias voltage between the cathode and anode; and electrically float the conductive layer. 20 . The thermionic sensor of claim 11 , further comprising leads extending from the cathode and the anode to outside of the sensor housing.