Ultrastable and Low‐Threshold Random Lasing from Narrow‐Bandwidth‐Emission Triangular Carbon Quantum Dots

Large sand bodies in the subsurface are shown to provide a unique laboratory for understanding both reservoirs and crude oils. Here, we treat the discovery by downhole fluid analysis of a gravitational concentration gradient of asphaltenes, the most dense component of crude oil, in a 2500-ft column of crude oil in the reservoir. The continuous trend of crude oil properties across the field implies flow connectivity of this giant sand body, addressing the single largest uncertainty in the development of deepwater oil fields todaydrainage area that can be achieved by each one of the extremely expensive wells. Consequently, downhole fluid analysis provides a new way to identify flow connectivity and to achieve significantly improved efficiency in oil production in high-cost arenas. In addition, detailed downhole and laboratory analyses of the asphaltene gravitational gradient show that asphaltenes are dispersed in crude oils of this weight as nanoaggregates. This observation agrees with the recently reported asphaltene nanoaggregates in toluene by high-Q ultrasonics and by NMR diffusion measurements. Finally, this case study suggests that resins are predominantly not associated with these asphaltene nanoaggregates, implying that the 70-year-old asphaltene−resin micelle model is in error. This asphaltene−resin micelle model, which has virtually no supporting data, appears to be substantially misleading in treating asphaltene colloidal structure.

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Nanoaggregates of Asphaltenes in a Reservoir Crude Oil and Reservoir Connectivity

Betancourt

et al. 2008

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Recently, asphaltenes have been shown to form nanoaggregates in toluene at very low concentrations (10 -4 mass fraction). Subsequently, in situ analysis of a 3000 ft vertical column of crude oil by downhole fluid analysis (DFA) indicated that the asphaltenes in a black crude oil exhibit gravitational sedimentation according to the Boltzmann distribution and that the asphaltene colloidal size is ∼2 nm. Here, we perform a follow-up study of a reservoir black oil from a different field. The black oil in a 658 ft vertical column is analyzed by DFA and advanced laboratory analytical chemical methods. An asphaltene colloidal particle size is found to be ∼2 nm according to the Archimedes buoyancy term in the Boltzmann distribution. In addition, an equation of state (EoS) approach based on literature critical constants and molecular weights for asphaltenes gives an aggregation number of ∼8. Molecular compositional similarities between different oil samples were established with comprehensive two-dimensional gas chromatography (GC × GC). Likewise, results from electrospray ionization Fourier transform ion cyclotron resonance mass spectroscopy (ESI FT-ICR MS) of the samples are consistent with the oils being from the same equilibrium column of oil. The results herein support a growing body of literature indicating that asphaltenes in black oils form relatively tightly bonded nanoaggregates of a single size range. The similarity of results between asphaltenes in crude oil and asphaltenes in toluene points to a very limited role of resins in these nanoaggregates, in contrast to much speculation. The implications of this work on the determination of reservoir connectivity are discussed.

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Soraya S. Betancourt

The Colloidal Structure of Crude Oil and the Structure of Oil Reservoirs

Nanoaggregates of Asphaltenes in a Reservoir Crude Oil and Reservoir Connectivity

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