Identification of heat capacity properties of formation fluid

What is claimed is: 1. A downhole fluid sensing device for determining heat capacity of a formation fluid produced by a sampled subterranean well, the device comprising: an annulus shaped elongated sensor package body interiorly defining a substantially cylindrical fluid sampling space, the elongated sensor package body and the sampling space having a common longitudinal center axis; a fluid entrance port providing a well fluid ingress into the fluid sampling space; a fluid exit port providing a well fluid egress out of the fluid sampling space; an upstream-to-downstream fluid flow path for a sampled well fluid extending from the fluid entrance port to the fluid exit port across the sampling space; a heat source coupled to the elongated sensor package body and located circumferentially around at least a portion of the fluid flow path between the fluid entrance port and the fluid exit port for inputting heat into the sampled well fluid; and a plurality of temperature sensing devices coupled to the elongated sensor package body and located between the fluid entrance port and fluid exit port for measuring heat conducted to the sampled well fluid, wherein each of the plurality of temperature sensing devices is radially spaced from the heat source and wherein the measurement is used to calculate the heat capacity of the formation fluid. 2. The downhole well fluid sensing device of claim 1 , wherein the heat source is concentrically positioned about the longitudinal center axis of the sampling space. 3. The downhole well fluid sensing device of claim 2 , wherein the heat source is positioned within the sampling space at a distance from the longitudinal center axis. 4. The downhole well fluid sensing device of claim 2 , wherein the heat source is positioned outside the annulus shaped, elongate sensor package body at a distance from the longitudinal center axis. 5. The downhole well fluid sensing device of claim 4 , wherein the heat source is a coiled heating element wound about an exterior of the annulus shaped, elongate sensor package body. 6. The downhole well fluid sensing device of claim 2 , wherein the heat source exteriorly circumscribes the annulus shaped, elongate sensor package body. 7. The downhole well fluid sensing device of claim 1 , wherein the heat source comprises a plurality of heat inputs positioned at different locations about the elongate sensor package body. 8. The downhole well fluid sensing device of claim 1 , wherein, at least one of the plurality of temperature sensing devices is located between the heat source and the fluid entrance port for measuring heat conducted upstream from the heat source and at least one of the plurality of temperature sensing devices is located between the heat source and the fluid exit port for measuring heat conveyed downstream from the heat source by the sampled well fluid flow. 9. The downhole well fluid sensing device of claim 1 , wherein the plurality of temperature sensing devices are one of: aligned, one with the others and positioned substantially parallel to the common longitudinal center axis of the elongate body and sampling space; arrayed thermocouple sensors; arrayed fiber Bragg grating sensors; optical time domain reflectometer (OTDR)-based Brillouin distributed fiber temperature sensors; and arrayed resistivity temperature detectors. 10. The downhole well fluid sensing device of claim 1 , wherein the heat source extends along a majority of the elongate sensor package body. 11. A downhole fluid sensing device for determining heat capacity of a formation fluid produced by a sampled subterranean well, the device comprising: an annulus shaped elongated sensor package body interiorly defining a substantially cylindrical fluid sampling space, the elongated sensor package body and the sampling space having a common longitudinal center axis; a fluid entrance port providing a well fluid ingress into the fluid sampling space; a fluid exit port providing a well fluid egress out of the fluid sampling space; an upstream-to-downstream fluid flow path for a sampled well fluid extending from the fluid entrance port to the fluid exit port across the sampling space; a heat source coupled to the elongated sensor package body and located is centrally positioned longitudinally within the sample space on a longitudinal center axis between the fluid entrance port and the fluid exit port for inputting heat into the sampled well fluid; and a plurality of temperature sensing devices coupled to the elongated sensor package body and located between the fluid entrance port and fluid exit port for measuring heat conducted to the sampled well fluid, wherein each of the plurality of temperature sensing devices is radially spaced from the heat source and wherein the measurement is used to calculate the heat capacity of the formation fluid, wherein the heat source is centrally positioned longitudinally within the sample space on the longitudinal center axis. 12. A method for determining heat capacity of a formation fluid produced by a sampled subterranean well, the method comprising: receiving, through a fluid entrance port, formation fluid flow in an annulus shaped, elongate body interiorly defining a substantially cylindrical fluid sampling space, the elongate body and the sampling space having a common longitudinal center axis; applying thermal energy to the fluid sampling space, wherein the thermal energy is applied by a heat source coupled to the elongate body and located circumferentially around at least a portion of the fluid sampling space; measuring a temperature change over time at a plurality of temperature sensing devices concentrically coupled to the elongate body, wherein the plurality of temperature sensing devices are longitudinally spaced along the sampling space and radially separated from the heat source; and calculating the heat capacity of the formation fluid based on the temperature change profile and transient temperature response decay slope. 13. The method of determining the heat capacity of a formation fluid of claim 12 further comprising pumping the formation fluid via a fluid exit port, out of the fluid sampling space, wherein the fluid mass density is measured with a density meter. 14. The method of determining the heat capacity of a formation fluid of claim 12 wherein applying thermal energy comprises applying a pulse modulated thermal energy to the formation fluid along a portion of the substantially cylindrical fluid sampling space, wherein the pulse of thermal energy is applied by a heat source. 15. The method of determining the heat capacity of a formation fluid of claim 12 , further comprising the step of: altering, in-situ, an external heating or energy supply system, based on the calculated thermal property for downhole hydrocarbon fluid production optimization, wherein, during time modulated external heat energy excitation, mufti-point thermal sensing arrays are measured relative temperature response amplitudes, the thermal responses are displayed in real-time, and transmitted to surface for fluid heat capacity analyses. 16. The method of determining the heat capacity of a formation fluid of claim 12 , further comprising the step of: transmitting the calculated thermal property to a surface computer for use altering a drilling or production parameter. 17. The method of determining the heat capacity of a formation fluid of claim 12 , wherein the heat source is positioned within the sampling space at a distance from the longitudinal center axis. 18. The method of determining the heat