THERMAL SIMULATION EXPERIMENT METHOD FOR HYDROCARBON-WATER-ROCK INTERACTIONS BASED ON ISOTOPE TRACING

Abstract

A thermal simulation experiment method for hydrocarbon-water-rock interactions based on isotope tracing is disclosed. N-eicosane, water and feldspar grains are first heated and reacted in a high temperature high pressure (HTHP) reactor. The reactor is quenched in water to room temperature and samples from the reaction are tested to obtain the composition and content of gas products, the isotopic compositions of gas products, the water solutions and authigenic clays, the nuclear magnetic resonance (NMR) spectra of the liquid hydrocarbons and water solutions, and textures and compositions of minerals. The genetic mechanisms of mass exchange and occurrence of hydrocarbon-water-rock interactions are analyzed. A thermal simulation experiment method using multiple isotope tracing, calibrates the exchange processes and paths for H and O between the hydrocarbons, water and minerals to provide evidence for deciphering the mechanism of the organic-inorganic interactions is disclosed.

Claims

1. A method for a thermal simulation of hydrocarbon-water-rock interactions based on isotope tracing comprising the steps: step 1: conducting hydrocarbon-water-rock thermal simulation experiments: combining n-eicosane, water, and grains of a feldspar in a reactor, and sealing the reactor under argon; heating the reactor for a reaction and quenching the reactor with water to room temperature at an end of the reaction to produce a plurality of samples; step 2: testing the plurality of samples obtained in step 1 after the reaction to obtain data comprising a composition and a content of a gas product, an isotopic composition of the gas product, an isotopic composition of a water solution, an isotopic composition of an authigenic clay, high-field nuclear magnetic resonance (NMR) spectra of liquid hydrocarbons and the water solution in the plurality of samples, a mineral texture, and a mineral composition; step 3: deciphering genesis of the hydrocarbon-water-rock interactions: based on the data obtained in step 2, analyzing genetic mechanisms of a mass exchange and an occurrence of the hydrocarbon-water-rock interactions; wherein in step 1, the n-eicosane is n-C.sub.20H.sub.42 or n-C.sub.20D.sub.42; the water is H.sub.2.sup.18O, D.sub.2.sup.18, or D.sub.2.sup.18O; and the feldspar is K−feldspar.

2. The method according to claim 1, wherein a mass ratio of the n-eicosane, the water, and the grains of the feldspar used in step 1 is (0-10):(0-10):(0-1), and a mass of the n-eicosane, a mass of the water, and a mass of the grains of the feldspar cannot all be zero at the same time.

3. The method according to claim 1, wherein the reactor used in step 1 undergoes a pretreatment and the pretreatment comprises heating the reactor at 740-760° C. for 7-9 hours, then cleaning the reactor with acetone and distilled water, and drying the reactor at 60° C.

4. The method according to claim 1, wherein a temperature used in step 1 to heat the reactor is 339-341° C., and a time for the reaction is 9-11 days.

5. The method according to claim 1, wherein a gas chromatography-mass spectrometry system is used to detect the composition and the content of the gas product of step 2.

6. The method according to claim 1, wherein a gas chromatography isotope ratio mass spectrometer is used to detect the isotopic composition of the gas product remaining after testing the composition and the content of the gas product in step 2.

7. The method according to claim 6, wherein detecting the isotopic composition of the water solution in step 2 comprises: separating liquid products in the reactor to obtain a first upper liquid hydrocarbon and a first lower water solution; evaporating the first lower water solution at 75-85° C. to obtain a remaining lower water solution, and purifying the remaining lower water solution using bromoethane filtration, activated carbon filtration, and C.sub.18 molecular sieve in sequence; and using the gas chromatography isotope ratio mass spectrometer to test an isotopic composition of the remaining lower water solution.

8. The method according to claim 1, wherein testing the isotopic composition of the authigenic clay in step 2 comprises: separating liquid products in the reactor to obtain a first upper liquid hydrocarbon and a first lower water solution; centrifuging the first lower water solution and collecting a clay precipitate; separating the clay precipitate on a surface of the grains of the feldspar in the reactor, mixing the clay precipitate obtained from centrifugation and from the surface of the grains of the feldspar to obtain a clay precipitate mixture, washing the clay precipitate mixture with dichloromethane and water in turn, and then using a gas chromatography isotope ratio mass spectrometer to detect the isotopic composition of the authigenic clay.

9. The method according to claim 8, wherein testing the high-field NMR of the liquid hydrocarbons and the water solution in step 2 comprises: separating liquid products in the reactor to obtain a second upper liquid hydrocarbon and a second lower water solution; removing water from the second upper liquid hydrocarbon using anhydrous copper sulfate to obtain the liquid hydrocarbons; mixing the liquid hydrocarbons and the second lower water solution with a deuterium-free reagent, and then using a high-field NMR to obtain the high-field NMR spectra of the liquid hydrocarbons and the second lower water solution respectively.

10. The method according to claim 1, wherein detecting the mineral texture and the mineral composition in step 2 comprises: drying the grains of the feldspar after the reaction, spraying gold on the grains of the feldspar, and using a scanning electron microscope (SEM) and an energy dispersive spectroscopy (EDS) to detect the mineral texture and the mineral composition.

11. The method according to claim 7, wherein testing the isotopic composition of the authigenic clay in step 2 comprises: separating liquid products in the reactor to obtain a second upper liquid hydrocarbon and a second lower water solution; centrifuging the the second lower water solution and collecting a clay precipitate; separating the clay precipitate on a surface of the grains of the feldspar in the reactor, mixing the clay precipitate obtained from centrifugation and from the surface of the grains of the feldspar to obtain a clay precipitate mixture, washing the clay precipitate mixture with dichloromethane and water in turn, and then using the gas chromatography isotope ratio mass spectrometer to detect the isotopic composition of the authigenic clay.

12. The method according to claim 9, wherein detecting the mineral texture and the mineral composition in step 2 comprises: drying the grains of the feldspar after the reaction, spraying gold on the grains of the feldspar, and using a scanning electron microscope (SEM) and an energy dispersive spectroscopy (EDS) to detect the mineral texture and the mineral composition.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0023] In order to clearly explain the techniques and detailed examples of the present invention, the attached figures are briefly introduced.

[0024] FIGS. 1A-1D show the high-field NMR spectra of liquid hydrocarbons and water solutions in Experiment 3, 4, 5, 6, 7 and 10. FIG. 1A shows the D-NMR spectra of liquid hydrocarbons, FIG. 1B shows the D-NMR spectra of water solutions, FIG. 1C shows the H-NMR spectra of liquid hydrocarbons, and FIG. 1D shows the H-NMR spectra of water solutions.

[0025] FIGS. 2A-2L show the SEM images of original K−feldspar, leached K−feldspar and authigenic minerals after experiments. FIG. 2A shows original feldspar surface, FIG. 2B shows feldspar surface in Experiment 2; FIG. 2C shows extensively leached feldspar (LF) in Experiment 3; FIG. 2D shows leached feldspar (LF) and euhedral boehmite (Bo) in Experiment 3; FIG. 2E shows extensively leached feldspar (LF) in Experiment 4; FIG. 2F shows leached feldspar (LF) and euhedral kaolinite in Experiment 4; FIG. 2G shows flower-like illite (muscovite) aggregates in Experiment 5; FIG. 2H shows lash-shaped boehmite in Experiment 5; FIG. 2I and FIG. 2J show thin plate-shaped illite (muscovite) aggregates on leached feldspar surface in Experiment 7; FIG. 2K shows subhedral plate-shaped illite (muscovite) on leached feldspar surface Experiment 8; FIG. 2L shows small euhedral illite (muscovite) on leached feldspar surface Experiment 9.

DETAILED DESCRIPTION OF THE EMBODIMENTS

[0026] The present invention provides a thermal simulation experiment method for hydrocarbon-water-rock interactions based on isotope tracing which involve the following steps:

[0027] Step 1: Conducting of hydrocarbon-water-rock thermal simulation experiments: put the n-eicosane, water and feldspar grains in reactors, and the reactors are sealed in the presence of argon. Heating the reactors for reaction and quench the reactor in water to room temperature as the experiments are finished.

[0028] Step 2: Testing of samples after reaction: the samples produced in the reactors in Step 1 were tested, for the purpose of obtaining the composition and content of gas products, the isotopic compositions of gas products, the water solutions and authigenic clays, the High-field Nuclear Magnetic Resonance (NMR) spectra of the liquid hydrocarbons and water solutions, and the mineral textures and compositions.

[0029] Step 3: Decipher genesis of hydrocarbon-water-rock interactions: Based on the data obtained in Step 2, the genetic mechanisms of mass exchange and occurrence of hydrocarbon-water-rock interaction are analyzed.

[0030] In Step 1, the n-eicosane is n-C.sub.20H.sub.42 or n-C.sub.20D.sub.42; the water is H.sub.2.sup.18O, D.sub.2.sup.18O or D.sub.2.sup.18O; the feldspar is K−feldspar.

[0031] In the invention, the grain size of feldspar particles in Step 1 is preferably 150-250 μm. It is further preferably 170-230 μm, and more preferably 190 μm.

[0032] In the present invention, the feldspar grains used in Step 1 are preferably placed directly in the reactor with n-eicosane and water, or the feldspar grains are placed in the Hastelloy alloy mesh bag with a mesh size of 150, and then placed directly in the reactor with n-eicosane and water.

[0033] In the present invention, the mass ratio of n-eicosane, water and feldspar grains in Step 1 is preferably (0-10):(0-10):(0-1), and the mass of n-eicosane, water and feldspar grains is not zero at the same time. It is further preferably (3-9):(2-7):(0.5-1), more preferably 5:5:1.

[0034] In the invention, the reactor used in Step 1 is preferably a high temperature and high pressure Hastelloy reactor. The outer diameter of the reactor is preferably 20 mm, the wall thickness is preferably 5 mm, and the height is preferably 120 mm.

[0035] In the invention, the reactors used in Step 1 are pretreated before experiments. The pretreatment is preferably as follows: heat the reactor at 740-760° C. for 7-9h, and then wash it with acetone, water and dry it successively after heating; It is further preferably heated at 744-756° C. for 7-8 h, more preferably heated at 750° C. for 8 h.

[0036] In the present invention, the reaction temperature in Step 1 is preferably 339-341° C., further preferably 340° C. The reaction time is preferably 9-11 days, further preferably 10 days.

[0037] In the present invention, the method for detecting the composition and content of the gas products in Step 2 is to place the reactors in the gas collection device and detect the composition and content of the gas product using the gas chromatography-mass spectrometry system.

[0038] In the present invention, the method for detecting the gas product isotope in Step 2 is: after testing the composition and content of the gas product, use the gas chromatography isotope ratio mass spectrometer to detect the remaining gas product isotope.

[0039] In the present invention, the method for detecting the isotope of aqueous solution in Step 2 is as follows: separating the liquid products in the reactor to obtain the upper liquid hydrocarbon and the lower water solution; After evaporating the lower water solution at 75-85° C., purification was conducted using bromoethane filtration, activated carbon filtration, Cis molecular sieve in sequence; and then use isotope ratio mass spectrometer to test the isotope of the water solution.

[0040] In the present invention, the method for testing authigenic clay isotopes in Step 2 is to separate the liquid products in the reactor to obtain the upper liquid hydrocarbon and the lower water solution; Centrifuge the lower water solution and collect the precipitated clay; Separate the clay on the surface of feldspar grains in the reactor, mix the clay samples obtained from centrifuge and from feldspar surface, wash with dichloromethane and water in turn, and then use isotope ratio mass spectrometer to detect the isotope of authigenic clay.

[0041] In the present invention, the method of High-field NMR testing of liquid hydrocarbon and water solution in Step 2 is to separate the liquid products in the reactor to obtain the upper liquid hydrocarbon and lower water solution; Remove water from the upper liquid hydrocarbon using anhydrous copper sulfate to obtain liquid hydrocarbon; Mix the liquid hydrocarbon and the lower aqueous solution with the deuterium-free reagent respectively, and then use High-field NMR to test the NMR spectra of the liquid hydrocarbon and the lower aqueous solution respectively.

[0042] In the present invention, the method for detecting the mineral textures and mineral composition in Step 2 is to dry the feldspar grains after reaction, then spray gold, and use scanning electron microscope (SEM) and Energy Dispersive Spectroscopy (EDS) to detect the mineral textures and mineral composition.

[0043] The technical solutions in the embodiments of the invention will be described clearly and completely below. Apparently, the described embodiments are only part of the embodiments of the invention, not all of them. Based on the embodiments in the invention, all other embodiments obtained by ordinary technicians in this field without creative work fall within the scope of protection of the invention.

[0044] The instant invention provides a thermal simulation experiment method for hydrocarbon-water-rock interactions based on isotope tracing which involve the following steps:

(1) Sample Preparation

[0045] Samples composed of n-C.sub.20H.sub.42, n-C.sub.20D.sub.42, H.sub.2.sup.16O, D.sub.2.sup.16O, D.sub.2.sup.18O and K−feldspar (KAlSi.sub.3O.sub.8) grains were used in the embodiments. n-C.sub.20H.sub.42 was supplied by Aladdin Industrial Corporation (AIC, Shanghai) and has a purity greater than 99.5%; n-C.sub.20D.sub.42 was supplied by Canada C/D/N isotopes Inc., with 98.3% wt % deuterium; H.sub.2O used was ultrapure water from AIC, with δD of −31.3‰ and δ.sup.18O of −4.97‰. Pure D.sub.2.sup.16O supplied by AIC was of 99.96 wt % deuterium. Pure D.sub.2.sup.18O was supplied by the Wuhan Niuruide Special Gas Co., Ltd, with 99% deuterium and 97% .sup.18O. K−feldspar grains with sizes between 150 μm to 250 μm were used in the experiments, and δ.sup.18O of the feldspar is 9.4‰-SMOW. K−feldspar grains were used directly or placed into Hastelloy alloy mesh bags (length 6 cm) with mesh size of 150 mesh.

(2) Thermal Experiments

[0046] The thermal experiments were conducted in HTHP Hastelloy pressure reactors (20 mm outside diameter, 5 mm wall thickness, and 120 mm height). All reactors were heated at 750° C. for 8 h to burn any organic matter. After heating, the reactors were cleaned with acetone and distilled water and were dried at 60° C.

[0047] Then n-eicosane (n-C.sub.20H.sub.42, n-C.sub.20D.sub.42), water (H.sub.2.sup.16O, D.sub.2.sup.16O, D.sub.2.sup.18O), feldspar grains or mesh bags with feldspar grains were placed into the Hastelloy pressure reactors, with different combinations of the species as listed in Table 1. Once loaded, the open ends of the reactors were purged with argon to remove air from the reactor; subsequently, the reactors were sealed in the presence of argon. Lastly, the reactors were weighed to obtain the weight before heating. Then, the reactors were placed in a single furnace and heated at 340° C. (error <±1° C.) for 10 days. After heating, the reactors were quenched to room temperature in cold water within 10 min. After drying, the reactors were weighed again to ensure no leakage during experiments.

TABLE-US-00001 TABLE 1 Summary of n-Eicosane (n-C.sub.20H.sub.42, n-C.sub.20D.sub.42)- water (H.sub.2O, D.sub.2O)-feldspars used in experiments. No. n-C.sub.20H.sub.42 n-C.sub.20D.sub.42 H.sub.2.sup.16O D.sub.2.sup.16O D.sub.2.sup.18O K-feldspar 1 2 g / / / / / 2 2 g / / / / 2 g 3 2 g / 2 g / / 20 mg in mesh bag 4 2 g / / 2 g / 20 mg in mesh bag 5 2 g / / / 2 g 2 g in mesh bag 6 2 g / / / 2 g 7 / 2 g 2 g / / 2 g in mesh bag 8 2 g / 2 g / / 2 g in mesh bag 9 / / 2 g / / 2 g 10 2 g / 2 g / / /

(3) Analysis of Gases, Liquids, and Minerals after Experiments

[0048] Samples obtained in reactor were tested with the following processes:

[0049] Testing of gas composition and content. Place the reactors in the gas collection device and detect the composition and content of the gas product using the gas chromatography-mass spectrometry system. The data were listed in Table 2.

TABLE-US-00002 TABLE 2 Gas yields of C.sub.1-C.sub.5, H.sub.2 and CO.sub.2 in different thermal experiments after 10-d heating. Gases Experiments (mL/g) 1 2 3 4 5 6 7 8 9 10 C.sub.1 0.078 0.088 0.531 0.557 5.742 1.460 0.323 0.117 0.000 0.280 C.sub.2 0.187 0.273 0.963 0.847 6.479 1.804 0.497 0.362 0.000 0.683 C.sub.2ene 0.002 0.003 0.004 0.003 0.031 0.013 0.006 0.004 0.000 0.003 C.sub.3 0.114 0.150 0.551 0.631 2.698 0.726 0.268 0.199 0.000 0.367 C.sub.3ene 0.017 0.027 0.031 0.025 0.153 0.061 0.029 0.036 0.000 0.031 iC.sub.4 0.000 0.000 0.001 0.002 0.020 0.001 0.000 0.000 0.000 0.003 nC.sub.4 0.034 0.038 0.141 0.072 0.563 0.176 0.072 0.051 0.000 0.107 iC.sub.5 0.002 0.002 0.003 0.000 0.008 0.002 0.003 0.003 0.000 0.003 nC.sub.5 0.002 0.003 0.001 0.002 0.006 0.003 0.004 0.004 0.000 0.002 H.sub.2 0.550 0.491 0.338 0.427 1.241 0.664 0.698 0.651 0.000 0.158 CO.sub.2 0.000 0.000 0.087 0.079 0.249 0.156 0.261 0.020 0.000 0.051

[0050] Table 2 shows that gases were generated in all the experimental systems carried out with n-C.sub.20H.sub.42 (n-C.sub.20D.sub.42), and are dominated by C.sub.1-n-C.sub.4 alkanes and H.sub.2. Isobutene (i-C.sub.4), pentane (n-C.sub.5, i-C.sub.5), ethene and propene were also generated, but with comparatively lower yields. H.sub.2 was generated in both the anhydrous and hydrous systems. However, CO.sub.2 was detected only in the hydrous systems. Overall, the yields of hydrocarbon gases were highest in the Experiments 5 and 6 with the presence of D.sub.2.sup.18O water, followed by Experiment 4 with D.sub.2.sup.16O water, and lastly Experiment 7 with n-C.sub.20D.sub.42 (Table 2). All isotopically labeled systems generated more hydrocarbon gases and H.sub.2 than those experiments without labeled reactants. In addition, the presence of feldspar was accompanied with high yields of hydrocarbon gases, H.sub.2 and CO.sub.2 in Experiment 3 (compared with Experiment 10) and Experiment 5 (compared with Experiment 6) (FIG. 1), regardless of with or without .sup.18O labeled water.

[0051] b. Testing of isotopic composition of CH.sub.4, C.sub.2H.sub.6 and CO.sub.2 gases. After the GC analysis, the remaining gas components were used for isotope analysis using a Thermo Fisher MAT-253 GC-isotope ratio mass spectrometry (GC-IRMS). This analysis was performed on a VG Isochrom II interfaced to an HP 5890 GC fitted with a Poraplot Q column (30 mm×0.32 mmi.Math.d.Math.). The isotopic composition of CH.sub.4 and C.sub.2H.sub.6 generated in the Experiments 3 and 4 were determined and presented in Table 3.

TABLE-US-00003 TABLE 3 Isotopic composition of CH.sub.4 and C.sub.2H.sub.6 generated in thermal systems with and without δD labeled water. Species δ.sup.13C (‰) δD (‰) AT D/H No. combination CH.sub.4 C.sub.2H.sub.6 CH.sub.4 C.sub.2H.sub.6 CH.sub.4 C.sub.2H.sub.6 3 n-C.sub.20H.sub.42 + H.sub.2.sup.16O + −58.490 −41.23 −287 −313 0.0111 0.0107 20 mg K-feldspar 4 n-C.sub.20H.sub.42 + D.sub.2.sup.16O + −58.342 −41.42 938607 185123 12.7661 2.8172 20 mg K-feldspar

[0052] The data in Table 3 show that the δ.sup.13C compositions of CH.sub.4 and C.sub.2H.sub.6 in the hydrous systems with and without δD labeled water are almost identical. In contrast, the δD composition of the CH.sub.4 and C.sub.2H.sub.6 in the different hydrous systems varies significantly. In the n-C.sub.20H.sub.42+H.sub.2.sup.16O+20 mg feldspar system (Experiment 3), the δD (AT % D/H) values of CH.sub.4 and C.sub.2H.sub.6 are −287‰ (0.0111) and −313‰ (0.0107), respectively. While in Experiment 4 (n-C.sub.20H.sub.42+D.sub.2.sup.16O+20 mg feldspar), the δD (AT % D/H) values of CH.sub.4 and C.sub.2H.sub.6 are 938607‰ (12.7661) and 185123‰ (2.8172), respectively, higher than that in Experiment 3.

[0053] The isotopic composition of CO.sub.2 generated in experiments 3-6 was determined and present in Table 4.

TABLE-US-00004 TABLE 4 Isotopic compositions of CO.sub.2 in systems with and without δ.sup.18O labeled water. No. Species combination δ.sup.13C (‰) δ.sup.18O (‰) At .sup.18O/.sup.16O 3 n-C.sub.20H.sub.42 + H.sub.2.sup.16O + 20 mg −15.17 −16.78 0.1967 K-feldspar 4 n-C.sub.20H.sub.42 + D.sub.2.sup.16O + 20 mg −14.97 −16.77 0.1967 K-feldspar 5 n-C.sub.20H.sub.42 + D.sub.2.sup.18O + 2 g −246 60631 11.00 K-feldspar 6 n-C.sub.20H.sub.42 + D.sub.2.sup.18O −250 95731 16.25

[0054] Table 4 show that the δ.sup.18O values of the CO.sub.2 in Experiments 3 and 4 without δ.sup.18O labeled water are close to −16.77‰, with an AT % .sup.18O/.sup.16O (atom ratio between .sup.18O and .sup.16O) value of 0.1967, while in Experiments 5 and 6 with δ.sup.18O labeled water, the δ.sup.18O values are much higher. In Experiment 6 (n-C.sub.20H.sub.42+D.sub.2.sup.18O), the δ.sup.18O value of the CO.sub.2 reaches up to 95731‰, with an At % .sup.18O/.sup.16O value of 16.25; in Experiment 5 (n-C.sub.20H.sub.42+D.sub.2.sup.18O+feldspar), the δ.sup.18O value of the CO.sub.2 is 60631‰, with an At % .sup.18O/.sup.16O value of 11.00, which is lower than in Experiment 6 without K−feldspar. In addition to the large differences of the δ.sup.18O values, the δ.sup.13C values of CO.sub.2 also show big differences between the experiments with and without δ.sup.18O labeled water, with δ.sup.13C values of approximately −15‰ in Experiments 3 and 6, and approximately −250‰ in Experiments 5 and -6, respectively (Table 4).

[0055] c. Testing of isotopic composition of water. After thermal experiments, the liquid organics-water solutions were firstly separated to obtain the liquid hydrocarbons at the upper and the water solutions at the lower part of the reactors. Each water sample was then filtered with bromoethane and activated carbon after low-temperature evaporation (80° C.) to remove the organic solutes (e.g., alcohols, organic acids, etc.). Finally, the water samples were purified using C.sub.18 molecular sieves. The treated water samples were then analyzed using the LabRAM HR800 Raman spectrometer with a 532 nm laser excitation. Here no dissolved organic molecules were detected in the water samples. After purification, the water samples were analyzed using the Thermo Fisher MAT-253 IRMS to obtain the hydrogen and oxygen isotope composition. The D/H ratios were reported using both the direct atomic abundance ratios (At D/H) and the delta values (δD) in unit of ‰ relative to V.sub.SMOW, and the .sup.18O/.sup.16O were reported using the delta values (δ.sup.18O) in unit of ‰ relative to V.sub.SMOW. The isotopic composition of the original water and water after heating was determined for Experiments 7-10 were listed in Table 5.

TABLE-US-00005 TABLE 5 Isotopic compositions of water and clay minerals in systems with and without δD labeled n-eicosane Water after experiments Clays after experiments No. δD (‰) AT D/H δ.sup.18O (‰) δD (‰) AT D/H Initial water −31.3 0.01508 −4.97 / / 7 36997 0.5883 −1.17 12943.22 0.219 8 −38.3 0.014953 0.23 162.39 0.018 9 −36.9 0.014968 −4.73 22.33 0.016 10 −37.3 0.014962 −4.08 / /

[0056] Table 5 show that with the presence of n-C.sub.20D.sub.42 in Experiment 7, the water after experiment exhibited a much higher δD (AT % D/H) value of 35935‰ (0.5883). Without addition of n-C.sub.20D.sub.42, the δD isotope composition of water after heating was much lower, with δD (AT % D/H) values of around −37‰ (0.014969) (Table 5). The original water has a δ.sup.18O value of −4.97‰ with the presence of K−feldspar, the δ.sup.18O value of water after heating with K−feldspar became higher, ranging from −4.73‰ to 0.23‰

[0057] d. Testing of isotopic composition of clays. Newly formed clay minerals precipitated in the water solution were collected by centrifuging of the waters. Feldspar grains were cleaned using dichloromethane and distilled water to remove the oil covering the mineral surfaces. Clays precipitated on feldspar grain surfaces were then separated gently by milling using pestle and mortar, and peeling fine debris from feldspar grains was then mixed with distilled water and stirred with a glass rod to collect the suspension on the upper layer. The suspension fluid was centrifuged at 2,000 rpm to collect the precipitated clay minerals. Clays obtained from water and feldspar surfaces were then repeatedly cleaned using dichloromethane and distilled water times to remove possible residual organic matter. Clay samples were identified using SEM, EDS and Raman spectrometer to ensure no residual of organics. Lastly, the clays were dried and dispersed for isotope analysis. Prepared clays were analyzed using the Thermo Fisher MAT-253 IRMS to obtain the hydrogen isotope composition. δD composition of newly generated clay minerals in Experiments 7-9 was determined (Table 5).

[0058] Table 5 shows that the clay minerals in Experiments 8 and 9 without n-C.sub.20D.sub.42 have δD (AT % D/H) values of 162.39‰ (0.00018) and 22.33‰ (0.00016), respectively. In Experiment 7 with C.sub.20D.sub.42, the δD (AT % D/H) value of the authigenic clay is 12943.22‰ (0.00219), and thus much higher than in Experiments 8 and 9 without n-C.sub.20D.sub.42.

[0059] e. Testing of High-field NMR spectra of liquid alkanes and waters. Separate the liquid products in the reactor to obtain the upper liquid hydrocarbon and the lower water solution. After separation and centrifuge, anhydrous copper sulfate (ACS) was added in the separated liquid organics to remove residual water, this process was repeated until no color change of the ACS was visible. Separated liquid alkane and water samples were mixed with deuterium free reagents to homogenize the field. The samples were then examined using the AVANCE III 600 MHz Nuclear Magnetic Resonance (NMR) with a broadband BBFO probe to gather the .sup.1H NMR spectrum and .sup.2H NMR spectrum of each sample. The standard ZG30 echo pulse sequence was used for the .sup.1H NMR spectrum and the standard ZG echo pulse sequence for the .sup.2H NMR spectrum. The pulse lengths were kept as short as possible to minimize any artefacts in the spectra due to finite pulse length effects. For the .sup.1H NMR spectrum, the 90° pulse lengths were 10.5 μs and the echo delay was 40 μs. For the .sup.2H NMR spectrum, the 90° pulses were 149 μs and the delay between pulses was 40 μs. In all experiments, the final delay prior to acquisition was set such that a few data points were collected before the top of the echo. This allows us to manually correct the phase of the FID and shift the points in the time domain before removing the points before the top of the echo. This process is important for obtaining spectra with a flat baseline. At the beginning of each series, the sample set point temperature was raised to 25° C. and the sample was allowed to equilibrate for at least 20 minutes. Spectra were then collected four times for the .sup.1H NMR spectrum and 32 times for the .sup.2H NMR spectrum. At the end of each series, the temperature was set to starting conditions of the experiment series and the spectrum was collected again to verify sample stability. The results were presented in FIGS. 1A-1D.

[0060] FIGS. 1A-1D show that after heating, neither water nor liquid organics in Experiments 3 (n-C.sub.20H.sub.42+H.sub.2.sup.16O+20 mg feldspar) and 10 (n-C.sub.20H.sub.42+H.sub.2.sup.16O) contained detectable deuterium (FIGS. 1A and 1B). In contrast, the resulting liquid organics in Experiments 5 (n-C.sub.20H.sub.42+D.sub.2.sup.18O+2 g feldspar) and 6 (n-C.sub.20H.sub.42+D.sub.2.sup.18O) with δD labeled water contained detectable amounts of deuterium (FIG. 1A). In Experiment 7 with a combination of n-C.sub.20D.sub.42, H.sub.2O and K−feldspar, the resulting water contained a detectable amount of deuterium (FIG. 1B), consistent with the tested isotopic composition (Table 5). After heating, the liquid organics in the systems with n-C.sub.20H.sub.42 and the water in the systems with H.sub.2O still show strong hydrogen signal (FIGS. 1C and 1D).

[0061] f. Testing of mineral textures and compositions. After the experiments, the feldspars grains were firstly cleaned using acetone and distilled water to remove the oil covering the mineral surfaces. The cleaned mineral grains were then fixed on aluminum stubs with conducting tape and coated with gold. The minerals were then identified using the Coxem-30 plus SEM to describe the textures of the K−feldspar and secondary minerals. A Bruker energy dispersive spectrometer (EDS) system (XFlasher Detector 430-M). SEM images were presented in FIGS. 2A-2L.

[0062] The SEM images of feldspars before and after thermal experiments show that feldspars in the anhydrous n-C.sub.20H.sub.42+feldspar system experienced no dissolution (FIGS. 2A-2B), and no secondary minerals were generated after 10 days. In the hydrous systems, distinct feldspar dissolution occurred, with precipitation of secondary minerals (FIGS. 2C-2L). For the systems with only 20 mg feldspars, these feldspars were leached quite extensively (FIGS. 2C-2F), and secondary minerals including kaolinite and illite were observed to be present on K−feldspar surfaces and in the water solutions. For the systems with 2 g feldspars, the grains were dissolved, and illite and muscovite were commonly observed on K−feldspar surfaces, and also in the water solutions (FIGS. 2G-2L). In the system with only H.sub.2O and feldspar, feldspar was also altered with the precipitation of illite.

(4) Genetic Mechanisms of Hydrocarbon-Water-Rock Interactions

[0063] With the results obtained in the last step, the genetic mechanism of hydrocarbon-water-rock interactions was analyzed.

[0064] In a hot anhydrous n-C.sub.20H.sub.42−feldspar system, feldspar is not altered following n-C.sub.20H.sub.42 degradation, indicating no organic-inorganic interactions in the absence of water. In the hot hydrous n-C.sub.20H(D).sub.42-H(D).sub.2O−feldspar systems, distinct mass exchange occurs among the organic and inorganic components, leading to extensive organic-inorganic interactions. Here, the results demonstrate that in the generic n-C.sub.20H(D).sub.42-H(D).sub.2O−feldspar systems, both n-C.sub.20H.sub.42 and water provided hydrogen for the generated gaseous and liquid hydrocarbons; besides water, n-C.sub.20H.sub.42 also provided hydrogen for authigenic OH-containing clays. After heating, an significant enrichment of deuterium (δD) was identified in the liquid hydrocarbons in the n-C.sub.20H.sub.42-D.sub.2O−(feldspar) systems and in the water of the n-C.sub.20D.sub.42-H.sub.2O−(feldspar) systems, indicating an extensive formation and recombination of free radicals (e.g., D*, H*, OD*, OH*, R.sub.H*, R.sub.D*) at elevated temperature. These promote the mass exchange between organic compounds and water. Apart from water, K−feldspar (KAlSi.sub.3O.sub.8) also provides oxygen for generated CO.sub.2, as verified by the difference of δ.sup.18O composition of CO.sub.2 in the systems with and without feldspar. The dilution of δ.sup.18O in D.sub.2.sup.18O water after reaction in an n-C.sub.20H.sub.42-D.sub.2.sup.18O−feldspar system indicated that oxygen from feldspar was initially transferred to water via mineral dissolution, and subsequently invoked in CO.sub.2 generation.

[0065] The δD and δ.sup.18O data, and HF-NMR H/D spectra of newly formed species in the hydrous systems demonstrate that water serves as a bridge (solvent and also a reactant) for mass exchanges among the organic and inorganic fractions, probably via formation (initiation) and consumption (termination) of free radicals and ions. Hence, the presence of water highlights its function to erase boundaries and to enable reactions among organic and inorganic components at elevated temperatures.

[0066] The above is only the preferred embodiment of the invention. Ordinary technicians in the technical field can make several improvements and refinishes without departing from the principle of the invention. These improvements and refinishes should also be considered as the protection scope of the invention.