Calorimetric microfluidic sensor

What is claimed is: 1. A microfluidic sensor, the microfluidic sensor comprising: a microchannel constructed of paper that comprises a reaction site that comprises a reagent and a sample inlet, wherein the microchannel is configured to receive a liquid substance comprising a chemical at the sample inlet that travels by capillary action to the reaction site; a temperature sensor located proximal the reaction site of the microchannel and configured to measure a temperature as a result of a reaction between the reagent and the chemical in the liquid substance; and a controller communicatively connected to the temperature sensor, the controller receives the temperature measured by the temperature sensor and derives a concentration of the chemical in the liquid substance from the temperature. 2. The microfluidic sensor of claim 1 , further comprising a support layer to which the microchannel and the temperature sensor are secured. 3. The microfluidic sensor of claim 2 , further comprising an adhesive layer disposed between the temperature sensor and the microchannel, wherein the adhesive layer electrically insulates the temperature sensor from the microchannel and secures the microchannel and temperature sensor to the support layer. 4. The microfluidic sensor of claim 1 , wherein the temperature sensor is a resistive temperature detector. 5. The microfluidic sensor of claim 1 , wherein the microchannel overlaps the temperature sensor in a region about the reaction site and the microchannel in the region about the reaction site is dimensioned in a width dimension to be less than a dimension of the temperature sensor in a width dimension. 6. The microfluidic sensor of claim 5 , wherein the controller further operates to compensate the derived concentration of the chemical based upon the reaction rate between the reagent and the liquid substance. 7. The microfluidic sensor of claim 1 , further comprising an enclosure defined about at least the temperature sensor and the reaction site. 8. The microfluidic sensor of claim 1 , wherein the temperature sensor measures the temperature over time and the controller derives the concentration of the chemical in the liquid substance from a local maximum temperature change from a steady state temperature of the temperature sensor. 9. The microfluidic sensor of claim 1 , wherein the sample inlet is a first sample inlet and the microchannel further comprises a second sample inlet and the first sample inlet and the second sample inlet are orthogonal to a portion of the microchannel that comprises the reaction site. 10. The microfluidic sensor of claim 1 , wherein the reagent is selected to detect a predetermined target chemical in the liquid substance. 11. A microfluidic sensor system comprising: at least one microfluidic sensor, comprising: a microchannel constructed of paper that comprises a reaction site that comprises a reagent and a sample inlet, wherein the microchannel is configured to receive a liquid substance comprising a chemical at the sample inlet that travels by capillary action to the reaction site; and a temperature sensor located proximal the reaction site of the microchannel and configured to measure a temperature as a result of a reaction between the reagent and the chemical in the liquid substance; a controller communicatively connected to the at least one microfluidic sensor, the controller receives the temperature measured by the temperature sensor of at least one microfluidic sensor and derives a concentration of the chemical in the liquid substance from the temperature; and a graphical display operated by the controller to present the derived concentration of the chemical in the liquid substance. 12. The system of claim 11 , wherein the at least one microfluidic sensor is a plurality of microfluidic sensors, each of the microfluidic sensors of the plurality comprising a different reagent configured to react with a different chemical and wherein the same liquid substance comprising a chemical is received at the sample inlets of each of the plurality of microfluidic sensors, and the controller operates to identify the chemical based upon the derived concentrations from the temperatures received from the plurality of microfluidic sensors. 13. The system of claim 12 , wherein the controller is a central controller communicatively connected to each of the plurality of microfluidic sensors. 14. The system of claim 12 , wherein the controller is one controller of a plurality of controllers, each of the controllers in the plurality being communicatively connected to one of the microfluidic sensors of the plurality of microfluidic sensors. 15. The system of claim 11 , wherein the at least one microfluidic sensor further comprises: a support layer to which the microchannel and the temperature sensor are secured; and an adhesive layer disposed between the temperature sensor and the microchannel, wherein the adhesive layer electrically insulates the temperature sensor from the microchannel and secures the microchannel and temperature sensor to the support layer. 16. The system of claim 15 , wherein the temperature sensor is a resistive temperature detector. 17. A microfluidic sensor, the microfluidic sensor comprising: a microchannel that comprises a reaction site on a first finger, the reaction site comprises a reagent, a sample inlet, and a second finger wherein the microchannel is configured to receive a liquid substance comprising a chemical at the sample inlet that travels by capillary action to the reaction site; a first temperature sensor located proximal to the reaction site on the first finger of the microchannel and configured to measure a first temperature as a result of a reaction between the reagent and the chemical in the liquid substance; a second temperature sensor located proximal to the second finger of the microchannel and configured to measure a second temperature; and a controller communicatively connected to the first temperature sensor and the second temperature sensor, the controller receives the first temperature and the second temperature and the controller derives a concentration of the chemical in the liquid substance from a differential between the first temperature and the second temperature. 18. The microfluidic sensor of claim 17 wherein the microchannel is constructed of paper. 19. The microfluidic sensor of claim 17 wherein the temperature sensor is a resistive temperature sensor. 20. The microfluidic sensor of claim 17 , further comprising: a support layer to which the microchannel and the temperature sensor are secured; and an adhesive layer disposed between the temperature sensor and the microchannel, wherein the adhesive layer electrically insulates the temperature sensor from the microchannel and secures the microchannel and temperature sensor to the support layer.