Changes in Asphaltene Microenvironments Evidenced by Fluorescence Solvatochromism

Abstract: This work involved the study of Cold Lake asphaltenes' behavior in toluene and o-dichlorobenzene. The changes in asphaltene microenvironments with the increase in asphaltene concentration were observed using fluorescence solvatochromism. The reporter molecule chosen was the environmentally sensitive fluorophore PRODAN. This procedure represents a novel and sensitive method to study asphaltene solutions, and might bring additional information to the existent database of asphaltene properties.A pre-aggregation m… Show more

“…They interpreted the shift to occur at a critical aggregation concentration (CAC) (range 0.2-1.5 g/l) and suggested that the CAC was caused by the formation of larger asphaltene molecular aggregates from the smaller asphaltene molecular aggregates. The CAC values reported by Pietaru and Cramb [19] were close to the MCP values measured by Priyanto et al [18]. Both MCP and CAC, nevertheless, are close to CMC values reported in the literature.…”

“…It is believed that there is a change in the rate of aggregation at this point. In this study, henceforth, this point is called the critical aggregation concentration (CAC), the same terminology employed by Pietaru and Cramb [19]. The surface tension decreases observed were relatively small in the range of 36.1-35.5 mN/m.…”

“…Their first transition point may be related to a molecular association phenomenon while the second may indicate CMC-like aggregation. Pietraru and Cramb [19] found fluorescence spectral shifts at asphaltene concentrations higher than those observed by Groenzin and Mullins [16]. They interpreted the shift to occur at a critical aggregation concentration (CAC) (range 0.2-1.5 g/l) and suggested that the CAC was caused by the formation of larger asphaltene molecular aggregates from the smaller asphaltene molecular aggregates.…”

Asphaltene aggregation in organic solvents

“…They interpreted the shift to occur at a critical aggregation concentration (CAC) (range 0.2-1.5 g/l) and suggested that the CAC was caused by the formation of larger asphaltene molecular aggregates from the smaller asphaltene molecular aggregates. The CAC values reported by Pietaru and Cramb [19] were close to the MCP values measured by Priyanto et al [18]. Both MCP and CAC, nevertheless, are close to CMC values reported in the literature.…”

“…It is believed that there is a change in the rate of aggregation at this point. In this study, henceforth, this point is called the critical aggregation concentration (CAC), the same terminology employed by Pietaru and Cramb [19]. The surface tension decreases observed were relatively small in the range of 36.1-35.5 mN/m.…”

“…Their first transition point may be related to a molecular association phenomenon while the second may indicate CMC-like aggregation. Pietraru and Cramb [19] found fluorescence spectral shifts at asphaltene concentrations higher than those observed by Groenzin and Mullins [16]. They interpreted the shift to occur at a critical aggregation concentration (CAC) (range 0.2-1.5 g/l) and suggested that the CAC was caused by the formation of larger asphaltene molecular aggregates from the smaller asphaltene molecular aggregates.…”

Asphaltene aggregation in organic solvents

“…51,52 FL spectra of aromatic moieties are fundamentally related to the aromatic fluorophores' sizes and conjugation; the appearance of new bands, shifts in emission wavelengths and FL intensity have been correlated with changes surrounding these fluorophores, like the bathochromic red shifts caused by intermolecular aggregation. [53][54][55] One problem with asphaltenes is their color;…”

Effect of Precipitating Conditions on Asphaltene Properties and Aggregation

“…That is, the fluorescence solvatochromism was observed in the nanocapsule. The fluorescence intensity depended on the polarity parameter [19] of the solvent as shown in Fig. 6b: 1697 RFU for ethanol (0.289), 1028 RFU for 2-propanol (0.273), and 925 RFU for DMSO (0.263).…”

Behavior of fluorescent molecules bound to the interior of silica nanocapsules in various solvents