Application of ultraviolet fluorometry and excitation–emission matrix spectroscopy (EEMS) to fingerprint oil and chemically dispersed oil in seawater

“…The spectral ranges generally correspond to the results in [13] for other oil grades. The dashed lines show spec tral regions characteristic of the natural conditions of Russian Far Eastern seas, where intensity maxima are regularly observed [12]: H1 and H2 are the fluores cence regions of humin compounds, P1, of protein compounds, CA, of chlorophyll a, and NP, of pheny lalanine, possibly [14][15][16][17].…”

Change of seawater fluorescence properties when mixing with crude oil

“…The spectral ranges generally correspond to the results in [13] for other oil grades. The dashed lines show spec tral regions characteristic of the natural conditions of Russian Far Eastern seas, where intensity maxima are regularly observed [12]: H1 and H2 are the fluores cence regions of humin compounds, P1, of protein compounds, CA, of chlorophyll a, and NP, of pheny lalanine, possibly [14][15][16][17].…”

Change of seawater fluorescence properties when mixing with crude oil

“…There is a clear difference between the preparation that contain the oil droplets (Zhou et al, 2013). Bugden et al (2008) and others have attributed the emission peaks at 340 nm to be a characteristic of the more water soluble low and medium molecular weight aromatics, while the emission peak at 445 nm is probably associated with the higher molecular weight (≥3-ring) aromatics. …”

Physical and Chemical Characterization of Crude Oil-Water Mixtures: Understanding the Effects of Interfacial Process to Chemical Bioavailability

“…It has been established, so far, that this technique can characterize natural organic matter (Baker and Spencer, 2004;Winter et al, 2007) and detect different types of aquatic pollutants, like sewage (Baker, 2001;Reynolds, 2002), oil (Budgen et al, 2008;Patra and Mishra, 2002;Carstea et al, 2010) or pesticides (Jiji et al, 2000). Furthermore, DOM fluorescence data correlate with water quality parameters such as: total organic carbon (Vodacek et al, 1995), aquatic plankton (Mopper and Schultz, 1993), faecal coliforms (Pfeiffer et al, 2008) and biological oxygen demand (Reynolds and Ahmad, 1997;Hudson et al, 2008).…”

Fluorescence Spectroscopy as a Potential Tool for In-Situ Monitoring of Dissolved Organic Matter in Surface Water Systems