In-situ thin film based temperature sensing for high temperature uniformity and high rate of temperature change thermal reference sources

What is claimed is: 1. A method for generating a blackbody radiation spectrum, comprising: providing a thin-film device having a first carbon nanotube layer configured to generate heat in response to an applied voltage, a second carbon nanotube layer configured to generate the blackbody radiation spectrum in response to the heat from the first carbon nanotube layer, and a thermocouple between the first carbon nanotube layer and the second carbon nanotube layer for measuring a temperature at the second carbon nanotube layer; supplying a current through the first carbon nanotube layer to generate heat in the first carbon nanotube layer; using the thermocouple layer to measure the temperature at the second carbon nanotube layer; and controlling the current at the first carbon nanotube layer to provide a selected temperature of the second carbon nanotube layer for generating the blackbody radiation spectrum. 2. The method of claim 1 , wherein the thermocouple further comprises a copper-carbon nanotube thermocouple. 3. The method of claim 2 , wherein the copper-carbon nanotube thermocouple includes carbon nanotube material forming a main body proximate the second carbon nanotube layer and a carbon nanotube tail having an reference junction distal from the second carbon nanotube layer and includes a copper electrode having a junction end affixed to the main body a contact end distal from the main body, and the temperature is related to a voltage difference between the reference junction of the carbon nanotube tail and the contact end of the copper electrode. 4. The method of claim 1 , wherein the thermocouple includes a strip of alumel deposited on the second carbon nanotube layer and a strip of chromel deposited on the second carbon nanotube layer and an end of the strip of alumel is in contact with an end of the strip of chromel. 5. The method of claim 1 , wherein the thermocouple is further configured to measure the temperature at the second carbon nanotube layer while providing a local variation of the temperature at the second carbon nanotube layer of less than about +−0.5 kelvin. 6. The method of claim 1 , wherein the second carbon nanotube layer includes a planar surface and a plurality of carbon nanotubes, wherein a selected carbon nanotube has a longitudinal axis directed substantially normal to the planar surface and emits photons directed along the longitudinal axis in response to the heat from the first carbon nanotube layer. 7. The method of claim 1 , further comprising spreading the heat from the first carbon nanotube layer transversely using a graphene stack between the first carbon nanotube layer and the thermocouple.