Asphaltenes are molecular substances that are found in crude oil, along with resins, aromatic hydrocarbons, and saturated hydrocarbons. [See Mullins, OC et al Editors, Asphaltenes, Heavy Oils and Petroleomics, Springer, New York (2007) 700 pages, 23 Chapters, 46 contributing scientists.] Pumpjack pumping an oil well near Sarnia, Ontario Petroleum (from Greek petra – rock and elaion – oil or Latin oleum – oil ) or crude oil is a thick, dark brown or greenish liquid. ... Resin is a hydrocarbon secretion formed in special resin canals of many plants, from many of which (for example, coniferous trees) it is exuded in soft drops from wounds, hardening into solid masses in the air. ... An aromatic hydrocarbon (abbreviated as AH), or arene is a hydrocarbon, the molecular structure of which incorporates one or more planar sets of six carbon atoms that are connected by delocalised electrons numbering the same as if they consisted of alternating single and double covalent bonds. ...

Asphaltenes consist primarily of CHNOS with trace V and Ni. The CH ratio is approximately 1:1.2 depending on the asphaltene source. Asphaltenes are defined operationally as the n-heptane insoluble, toluene soluble component of a carbonaceous material such as crude oil, bitumen or coal. Asphaltenes have been shown to have a distribution of molecular weights in the range of 400 amu to 1500 amu with a maximum around 750 amu. All techniques are now roughly in accord including many different mass spectral methods (ESI FT-ICR MS, APPI, APCI FIMS, LDI) and many different diffusion techniques (time-resolved fluorescence depolarization, fluorescence correlation spectroscopy, Taylor dispersion). Aggregation of asphaltenes at very low concentrations (in toluene) led to aggregate weights being misinterpreted as molecular weigths with techniques such as VPO or GPC. The chemical structure is difficult to assertain, due to the complex nature of the asphaltenes, but has been studied by all available technicues including X-ray, elemental, and pyrolysis GC-FID-GC-MS. However, it is undisputed that the asphaltenes are composed mainly of polyaromatic carbon i.e. polycondenzed aromatic benzene units with oxygen, nitrogen, and sulfur,(NSO-compounds) combined with minor amounts of a series of heavy metals, particularly vanadium and nickel which occur in porphyrin structures. Furthermore, ashaltene rotational diffusion measurements show that small PAH chromophores (blue fluorescing) are in small asphaltene molecules while big PAH chromophores(red fluorescing)are in big molecules. This implies that there is only one fused polycyclic aromatic hydrocarbon (PAH) ring system per molecule. Very recent fragmentation studies by FT ICR-MS strongly support this 'island' molecular architecture refuting the 'archipelago' molecular architecture. General Name, Symbol, Number oxygen, O, 8 Chemical series nonmetals, chalcogens Group, Period, Block 16, 2, p Appearance colorless (gas) very pale blue (liquid) Standard atomic weight 15. ... General Name, Symbol, Number nitrogen, N, 7 Chemical series nonmetals Group, Period, Block 15, 2, p Appearance colorless gas Standard atomic weight 14. ... General Name, Symbol, Number sulfur, S, 16 Chemical series nonmetals Group, Period, Block 16, 3, p Appearance lemon yellow Standard atomic weight 32. ...

Asphaltenes are today widely recognised as soluble, chemcially altered fragments of kerogen which migrated out of the source rock for the oil, during oil catagenesis. Asphaltenes had been thought to be held in solution in oil by resins (similar structure and chemistry, but smaller) but recent data shows this is incorrect. Indeed it has recently been established that asphaltenes are nanocolloidally suspended in crude oil and in toluene solutions of sufficient concentrations. In any event for low surface tension liquids such as alkanes and toluene, surfactants are not necessary to maintain nanocolloidal suspensions of asphaltenes.

The nickel to vanadium contents of asphaltens reflect the pH-Eh conditions of the paleo-depositional environment of the source rock for oil (Lewan, 1980;1984) and this ratio is therefore in use in the petroleum industry for oil-oil correlation and for identification of potential source rocks for oil (oil exploration)

The word "asphaltene" was coined by Boussingault in 1837 when he noticed that the distillation residue of some bitumens had asphalt-like properties. Jean Baptiste Joseph Dieudonne Boussingault (February 2, 1802 - May 11, 1887) was a French chemist. ... Queen Victoria, Queen of the United Kingdom (1837 - 1901) 1837 (MDCCCXXXVII) was a common year starting on Sunday (see link for calendar). ... Laboratory distillation set-up using, without a fractionating column 1: Heat source 2: Still pot 3: Still head 4: Thermometer/Boiling point temperature 5: Condenser 6: Cooling water in 7: Cooling water out 8: Distillate/receiving flask 9: Vacuum/gas inlet 10: Still receiver 11: Heat control 12: Stirrer speed... Bitumen is a mixture of organic liquids that are highly viscous, black, sticky, entirely soluble in carbon disulfide, and composed primarily of highly condensed polycyclic aromatic hydrocarbons. ...

Asphaltenes in the form of {destillation} distillation products from refineries is used as "tar-mats" on roads.

Heavy oils, tar-sands and biodegraded oils (as bacteria can not assimilate asphalten[e]s, but readily consumes saturated hydrocarbons and also certain aromatic hydrocarbon isomers- enzymatically controlled) contain much higher proportions of asphalten[e]s than do medium API oils or light oils, and condensates are virtually devoid of asphalten[e]s.

They are of particular interest to the petroleum industry because of their depositional effect in production equipment such as tubulars in oil wells. In addition, asphaltenes impart high viscosity to crude oils negatively impacting production. The variable asphaltene concnetration in crude oils within individual reservoris creates a myriad of production problems.