Unresolved complex mixture

Unresolved complex mixture (UCM), or hump, is a feature frequently observed in <a href="/facts/Gas_chromatography/kwLY8vt1">gas chromatographic</a> (GC) data of <a href="/facts/Crude_oil/IQV0bHVd">crude oils</a> and extracts from organisms exposed to oil.
The reason for the UCM hump appearance is that GC cannot resolve and identify a significant part of the <a href="/facts/Hydrocarbon/Dcg95Ju5">hydrocarbons</a> in crude oils. The resolved components appear as peaks while the UCM appears as a large background/platform. In non-<a href="/facts/Biodegraded/d1UW4dfR">biodegraded</a> oils the UCM may comprise less than 50% of the total area of the chromatogram, while in biodegraded oils this figure can rise to over 90%. UCMs are also observed in certain refined fractions such as lubricating oils and references therein.
In attempting to determine "the processes that regulate the fate of petroleum following release to the environment,” geochemist <a href="/facts/Christopher_M._Reddy/yjJELlPx">Christopher M. Reddy</a> of <a href="/facts/Woods_Hole_Oceanographic_Institution/qqmQY6PN">Woods Hole Oceanographic Institution</a> invented an application of <a href="/facts/Comprehensive_two-dimensional_gas_chromatography/EmKV5VqN">comprehensive two-dimensional gas chromatography</a> (GCxGC) that resolves UMPs and that he patented. As it degrades in a marine environment, oil undergoes complex transformations, producing residues composed of extremely complex organic mixtures that accumulate in such “protective environments” as fiddler crabs and marsh grass. These residues form the majority of the unresolved complex mixture (UCM) resulting from the breakdown of crude oils that <a href="/facts/Gas_chromatography/kwLY8vt1">GC</a> had previously been unable to resolve but which Reddy’s novel GCxGC application has made accessible, enabling determination of “the underlying processes controlling petroleum fate” as it degrades in a marine environment. 
The technique Reddy invented is now widely applied in the characterization of petroleum in environmental samples as well as in analyses of other complex organic mixtures, and, because of it, GCxGC has transitioned from “a niche qualitative analysis tool to a robust quantitative technique.” For this innovative work, Reddy was awarded the Clair C. Patterson Award in 2014 by the <a href="/facts/Geochemical_Society/H8oPatEC">Geochemical Society</a> for "an innovative breakthrough in environmental geochemistry of fundamental significance within the last decade, particularly in service to society. To be viewed as innovative, the work must show a high degree of creativity and/or be a fundamental departure from usual practice while contributing significantly to understanding in environmental geochemistry."
Reddy's first investigation into oil spills employing the new method was at the West Falmouth Harbor of Massachusetts, where the barge Florida had run aground in 1969, spilling 175,000 gallons of heating oil. Reddy and his team studied the area from 1999 to 2008, identifying chemical and biological effects that persisted even after 30 years. According to geologist and biogeoscientist <a href="/facts/Timothy_Eglinton/5upEp9g4">Timothy Eglinton</a>, at the time Reddy received the Patterson Award, the "string of papers" he and his team members had published "on this oil spill ... collectively represent[ed] amongst the most comprehensive, sustained and multifaceted investigations of the environmental fate of a single petroleum spill" published to date, thanks to Reddy's use of the novel GCxGC method he had pioneered.
One reason why it is important to study the nature of UCMs is that some have been shown to contain toxic components, but only a small range of known petrogenic toxicants, such as the <a href="/facts/United_States_Environmental_Protection_Agency/ghI985SI">USEPA</a> list of 16 <a href="/facts/Polycyclic_aromatic_hydrocarbon/K52xSfNC">polycyclic aromatic hydrocarbons</a> (PAHs), tend to be routinely monitored in the environment.
Analysis of the hydrocarbon fraction of crude oils by GC reveals a complex mixture containing many thousands of individual components. Components that are resolved by GC have been extensively studied e.g. However, despite the application of many analytical techniques the remaining components have, until very recently, proved difficult to separate due to the large numbers of co-eluting compounds. Gas chromatograms of mature oils have prominent n-alkane peaks which distract attention from the underlying unresolved complex mixture (UCM) of hydrocarbons often referred to as the ‘hump’. Processes such as weathering and biodegradation result in a relative enrichment of the UCM component by removal of resolved components and the creation of new compounds. It has been shown that both resolved and unresolved components of oils are subject to concurrent biodegradation, i.e. it is not a sequential process, but due to the recalcitrant nature of some components, the rates of biodegradation of individual compounds greatly varies. The UCM fraction often represents the major component of hydrocarbons within hydrocarbon-polluted <a href="/facts/Sediment/zsIH1A6U">sediments</a> (see reference therein) and biota e.g. A number of studies has now demonstrated that aqueous exposure to components within the UCM can affect the health of marine organisms, including possible hormonal disruption, and high concentrations of environmental UCMs have been strongly implicated with impaired health in wild populations.

Unresolved complex mixture open-in-new

Unresolved complex mixture