Estimating downhole fluid volumes using multi-dimensional nuclear magnetic resonance measurements

The invention claimed is: 1. An article of manufacture comprising one or more tangible, non-transitory, machine-readable media comprising instructions that, when executed by a processor, cause the processor to: receive a first well log measurement comprising a multi-dimensional nuclear magnetic resonance measurement obtained by a first downhole tool in a well; receive a second well log measurement that, alone or in combination with the multi-dimensional nuclear magnetic resonance measurement, describes a total organic carbon measurement of the well, wherein the second well log measurement is obtained by the first downhole tool or a second downhole tool in the well; compute a reservoir producibility index (RPI) based at least in part on the first well log measurement and the second well log measurement, wherein the instructions to compute the reservoir producibility index (RPI) comprise instructions to: compute a carbon weight fraction of light oil W C_Oil on based at least in part on the first well log measurement; compute a total organic carbon (TOC) based at least in part on the second well log measurement; and compute the reservoir producibility index (RPI) using the carbon weight fraction of light oil W C_Oil and the total organic carbon (TOC); and wherein the instructions to compute the carbon weight fraction of light oil W C_Oil comprise instructions to: (a) compare expected multi-dimensional nuclear magnetic resonance responses for water and hydrocarbon to the actual multi-dimensional nuclear magnetic resonance responses from the first well log measurement to obtain an estimate of one or more fluid volumes of the hydrocarbon, wherein the one or more fluid volumes of the hydrocarbon comprises the carbon weight fraction of light oil W C_Oil or a value that can be used to obtain the carbon weight fraction of light oil W C_Oil ; (b) compute an uncertainty of the estimate of the fluid volume of the hydrocarbon based at least in part on the second well log measure; and iteratively perform (a) and (b) using one or more variations of the expected multi-dimensional nuclear magnetic resonance responses for water and hydrocarbon to cause the uncertainty of the estimate to be reduced or optimized; and display the reservoir producibility index (RPI) on a well log. 2. The article of manufacture of claim 1 , wherein the first well log measurement comprises a 2D nuclear magnetic resonance measurement of T1 and T2. 3. The article of manufacture of claim 1 , wherein the first well log measurement comprises a 2D nuclear magnetic resonance measurement of diffusion (D) and T2. 4. The article of manufacture of claim 1 , wherein the second well log measurement comprises a spectroscopy measurement. 5. The article of manufacture of claim 1 , wherein the second well log measurement comprises one or more well log values from which total organic carbon (TOC) may be obtained. 6. The article of manufacture of claim 1 , wherein: the carbon weight fraction of light oil W c_oil is computed in accordance with the following relationship: W C_Oil =( k×φ oil ×ρ oil )/ρ b where k is the ratio between carbon weight of light oil and total light oil weight, ϕ oil and the ρ oil are the oil porosity and density, and ρ b is the bulk density of the formation; the total organic carbon (TOC) is computed in accordance with the following relationship: TOC= W C_Oil +W C_Bitumen +W C_Kerogen where W C_Oil is the carbon weight fraction of light oil, W C_Bitumen is a carbon weight fraction of bitumen, and W C_Kerogen is a carbon weight fraction of kerogen; and the reservoir producibility index (RPI) is computed in accordance with the following relationship: RPI= W C_Oil ×W C_Oil /TOC. 7. A method comprising: using a first downhole tool disposed in a well, obtaining a first well log measurement comprising a multi-dimensional nuclear magnetic resonance measurement using a first downhole tool in the well in a geological formation comprising shale; using the first downhole tool or a second downhole tool disposed in the well, obtaining a second well log measurement that, alone or in combination with the multi-dimensional nuclear magnetic resonance measurement, describes a total organic carbon measurement of the well; and using the first well log measurement and the second well log measurement to compute one or more fluid volumes of hydrocarbon in the well or compute a reservoir producibility index (RPI), or both, and wherein the one or more fluid volumes of hydrocarbon in the well are computed including by: (a) comparing expected T1-T2 nuclear magnetic resonance responses for hydrocarbon to the measured T1-T2 nuclear magnetic resonance responses from the first well log measurement to obtain an estimate of the one or more fluid volumes of the hydrocarbon; (b) computing an uncertainty of the estimate of the fluid volume of the hydrocarbon based at least in part on the second well log measurement; and iteratively performing (a) and (b) using one or more variations of the expected multi-dimensional nuclear magnetic resonance responses for hydrocarbon to cause the uncertainty of the estimate to be reduced or optimized. 8. The method of claim 7 , wherein the reservoir producibility index (RPI) is computed based at least in part on the computed one or more fluid volumes of hydrocarbon in the well.