Recessed carbon nanotube article and method for making same

What is claimed is: 1. A recessed carbon nanotube article comprising: a base; a substrate disposed on the base; a plurality of wells disposed in the substrate and bounded by the base and a substrate wall; and a carbon nanotube element disposed in individual wells and that consists of a plurality of vertically aligned carbon nanotubes such that a longitudinal length of the vertically aligned carbon nanotubes is less than a depth of the well in which the carbon nanotube element is disposed. 2. The recessed carbon nanotube article of claim 1 , further comprising a well cover disposed on the substrate opposing the carbon nanotube element and that, in combination with the base and the substrate wall, bounds the well in absence of contact with the vertically aligned carbon nanotubes. 3. A process for making a recessed carbon nanotube article, the process comprising: forming a substrate on a base; forming a well in the substrate, the well being bound by the base and a substrate wall; forming vertically aligned carbon nanotubes in the well; terminating formation of vertically aligned carbon nanotubes in the well prior to a terminus of the vertically aligned carbon nanotubes penetrating beyond the well; and disposing a well cover on the substrate to cover the vertically aligned carbon nanotubes and the well in an absence of contact between the vertically aligned carbon nanotubes and the well cover. 4. The process of claim 3 , further comprising removing the well cover from the substrate to expose the vertically aligned carbon nanotubes in the well. 5. The process of claim 3 , further comprising hermetically sealing the well cover to the substrate to hermetically seal the well. 6. The process of claim 5 , wherein hermetically sealing the well cover to the substrate comprises wafer bonding the well cover to the substrate. 7. The process of claim 5 , wherein hermetically sealing the well cover further comprises: introducing a gas in the well; and sealing the gas in the well upon hermetically sealing the well cover. 8. The process of claim 3 , wherein forming the well in the substrate comprises: lithographically defining the well; deep reactive ion etching of the well into the substrate; and terminating the deep reactive ion etching at the base. 9. The process of claim 3 , wherein forming vertically aligned carbon nanotubes in the well comprises: disposing a catalyst on the base in the well; and performing chemical vapor deposition to deposit the vertically aligned carbon nanotubes. 10. The process of claim 9 , wherein chemical vapor deposition occurs at a temperature of the base and the substrate from 400° C. to 1000° C. with a carbon feedstock gas. 11. A recessed carbon nanotube bolometer comprising: a base; a substrate disposed on the base; a plurality of wells disposed in the substrate and bounded by the base and a substrate wall; a radiation absorber disposed in individual wells and that: consists of a plurality of vertically aligned carbon nanotubes such that a longitudinal length of vertically aligned carbon nanotubes is less than a depth of the well in which the radiation absorber is disposed; receives a stimulant radiation; and produces absorber heat from the stimulant radiation by the vertically aligned carbon nanotubes; a plurality of thermistors disposed on the base such that a first thermistor: is locally disposed and in thermal communication with a first radiation absorber in an absence of thermal communication with radiation absorbers that are adjacent to the first radiation absorber; receives the absorber heat from the vertically aligned carbon nanotubes; and produces a thermistor signal from the absorber heat; and a plurality of heaters disposed on the base such that a first heater: is locally disposed and in thermal communication with the first radiation absorber and disposed proximate to the first thermistor, in an absence of thermal communication with radiation absorbers that are adjacent to the first radiation absorber; receives electrical substitution current; produces, from the electrical substitution current, electrical substitution heat; and communicates the electrical substitution heat to the first thermistor that is proximately disposed to the first heater, wherein the thermistors and heaters are arranged as an electrical substitution member comprising an individual thermistor and an individual heater; and a readout member disposed on the base such that the heaters and the thermistors are interposed between the readout member and the base. 12. The recessed carbon nanotube bolometer of claim 11 , further comprising a well cover disposed on the substrate opposing the carbon nanotube element and that, in combination with the base and the substrate wall, bounds the well in absence of contact with the vertically aligned carbon nanotubes. 13. The recessed carbon nanotube bolometer of claim 11 , wherein the readout member comprises a plurality of readout circuits such that an individual readout circuit is: locally disposed on and in electrical communication with an individual electrical substitution member, so that each electrical substitution member is independently and individually electrically addressed by individual readout circuits, wherein for each electrical substitution member the readout circuit in electrical communication with the electrical substitution member comprises a heater circuit in communication with the heater and a thermistor circuit in communication with the thermistor, the heater circuit providing the electrical substitution current to the heater, and the thermistor circuit receiving the thermistor signal from the thermistor. 14. A process for making a recessed carbon nanotube bolometer, the process comprising: forming a substrate on a base; forming a well in the substrate, the well being bound by the base and a substrate wall; forming vertically aligned carbon nanotubes in the well; terminating formation of vertically aligned carbon nanotubes in the well prior to a terminus of the vertically aligned carbon nanotubes penetrating beyond the well; disposing a well cover on the substrate to cover the vertically aligned carbon nanotubes and the well in an absence of contact between the vertically aligned carbon nanotubes and the well cover; forming a thermistor on the base opposite the well and the vertically aligned carbon nanotubes so that the thermistor is in thermal communication with the vertically aligned carbon nanotubes through the base; and forming a heater proximate to the thermistor and on the base opposite the well and the vertically aligned carbon nanotubes to make the recessed carbon nanotube bolometer so that the heater is in thermal communication with the vertically aligned carbon nanotubes through the base, wherein the thermistor and the heater are arranged as an electrical substitution member on the base. 15. The process of claim 14 , further comprising forming a bump bond member on the base proximate to the electrical substitution member. 16. The process of claim 15 , further comprising disposing a readout member on the electrical substitution member so that the heater is in electrical communication with a readout circuit and the thermistor circuit is in electrical communication with a thermistor circuit, wherein the readout circuit and the thermistor circuit are part of a readout circuit of the readout member. 17. The process of claim 15 , wherein forming the bump bond member on the base comprises: lithographically defining the bump bond member on the base; and dep