Systems and methods for icing resistant total air temperature probes

What is claimed is: 1. A total air temperature data probe, the probe comprising: a probe base; and a probe body having a leading edge and a trailing edge and extending from the probe base along a first axis, the probe body comprising: a first interior airflow passage comprising a first annulus aligned with the first axis; a second interior airflow passage comprising a second annulus aligned with the first axis; and a tubular heat shield separating the first annulus from the second annulus; wherein the second annulus is defined by a space between the tubular heat shield and an interior wall of the probe body; a temperature sensor positioned within the first annulus; a heating element positioned within the second annulus; a notched intake port positioned at a distal end of the probe body, wherein the probe body provides a conductive thermal path from the heating element to the notched intake port, the notched intake port including an open channel extending inward from a first face of the distal end into an intake aperture of the probe body opening to both the first annulus and the second annulus, and a cutaway region that defines a recessed second face inset from the first face and exposes the open channel at least partially from the leading edge; and wherein the notched intake port further comprises a slot inset from the recessed second face that traverses across at least a portion of the intake aperture perpendicularly to the open channel. 2. The probe of claim 1 , wherein the open channel runs parallel to the axis of the probe body. 3. The probe of claim 1 , wherein the slot is separated from the leading edge by a lip. 4. The probe of claim 1 , wherein the first face of the distal end is flat and oriented normal to the probe axis. 5. The probe of claim 1 , further comprising a weep hole penetrating from a base of the notched intake port to the trailing edge of the probe body. 6. The probe of claim 1 , wherein the first interior airflow passage and the second interior air-flow passage are concentric tubular air passages. 7. The probe of claim 1 , the probe body further comprising an air ejector, the air ejector comprising: an ejector inlet coupled to an aircraft provided pressurized air supply; a low pressure chamber coupled to the ejector inlet through a flow restrictor; and at least one ejector exhaust port; wherein when the aircraft provided pressurized air supply is applied to the ejector inlet, the low pressure chamber pulls an airflow through the first annulus and the second annulus, and ejects the airflow from the probe body through the at least one ejector exhaust port. 8. The probe of claim 7 , wherein the air ejector is aligned with the first axis. 9. The probe of claim 1 , further comprising a plurality of exhaust ports positioned along a side of the probe body. 10. The probe of claim 1 , wherein the heating element comprises a wire, a cable, or a film. 11. The probe of claim 1 , wherein the heating element comprises a cartridge inserted within the second annulus. 12. The probe of claim 1 , wherein the heating element is non-uniformly constructed to concentrate conductive heating to designated regions of the probe body. 13. A method for a total air temperature data probe, the method comprising: creating an airflow through a first annulus and a second annulus of a probe body, the probe body comprising a leading edge and a trailing edge; directing the airflow through the first annulus and the second annulus from a notched intake port positioned at a distal end of the probe body, the notched intake port including an open channel extending inward from a first face of the distal end into an intake aperture of the probe body, and a cutaway region that defines a recessed second face inset from the first face and exposes the open channel at least partially from the leading edge, wherein the intake aperture opens to both the first annulus and the second annulus; directing a first portion of the airflow passing through the first annulus across a temperature sensor positioned within the first annulus; heating a second portion of the airflow passing through the second annulus with a heating element located within the second annulus; and exhausting the airflow from the probe body; wherein the probe body further comprises a tubular heat shield, wherein the second annulus is defined by a space between the tubular heat shield and an interior wall of the probe body and the tubular heat shield separates the first annulus from the second annulus. 14. The method of claim 13 , further comprising obtaining a total air temperature measurement from the temperature sensor. 15. The method of claim 13 , wherein the probe body provides a conductive thermal path from the heating element to the notched intake port. 16. The method of claim 13 , wherein creating the airflow through the first annulus and the second annulus of the probe body comprises: operating an air ejector within the probe body, the air ejector comprising: an ejector inlet coupled to an aircraft provided pressurized air supply; a low pressure chamber coupled to the ejector inlet through a flow restrictor; and at least one ejector exhaust port; wherein when the aircraft provided pressurized air supply is applied to the ejector inlet, the low pressure chamber pulls the airflow through the first annulus and the second annulus, and ejects the airflow from the probe body through the at least one ejector exhaust port.