Paper Number
IR9                         My Program 

Session
Interfacial Rheology, Surfactants, Foams, and Emulsions

Title
Bilgewater emulsions: Unraveling spontaneous formation and phase behavior through tailored surfactant, oil and salt strategies

Presentation Date and Time
October 14, 2024 (Monday) 2:10

Track / Room
Track 6 / Room 501

Authors (Click on name to view author profile)

1. Zheng, Yue (Applied Materials)
2. Howarter, John (Purdue University, Materials Engineering)
3. Erk, Kendra A. (Purdue University, School of Materials Engineering)
4. Martinez, Carlos J. (Purdue University, Materials Engineering)

Author and Affiliation Lines (in printed abstract book)
Yue Zheng¹, John Howarter², Kendra A. Erk² and Carlos J. Martinez^2
1Applied Materials, Santa Clara, CA 95054; ²School of Materials Engineering, Purdue University, West Lafayette, IN 47906

Speaker / Presenter 
Martinez, Carlos J.

Keywords
emulsions; surfactants

Text of Abstract
The formation of spontaneous emulsion has been of concern in wastewater remediation. In this work, the hydrophilic-lipophilic difference (HLD) framework was used to predict the formation of spontaneous emulsions using a mixture of Span-80 and SLES surfactants, different oils, and salinity conditions. Different systems' spontaneity and emulsion behavior were modeled by estimating the HLDmix with a simple mixing rule. The influence of surfactant ratio, salinity, and oil type was investigated. Spontaneous emulsification could only be observed when our systems' HLDmix was between -0.96 and 1.04. Within this range, a negative HLDmix resulted in a greater spontaneity to form o/w emulsion, and a w/o emulsion was more likely to form when the HLDmix was positive. When the HLDmix was close to 0 (between -0.22 and 0.56 in our systems), emulsions were formed in the oil and aqueous phases with high spontaneity. This trend was also confirmed by estimating the dispersed phase content with emulsion turbidity. A combined effect of ultra-low interfacial tension, Span-80 micelle swelling, and interfacial turbulence due to Marangoni effects are likely the main mechanisms of the spontaneous emulsification observed in this study. A synergistic reduction in interfacial tension was observed between Span-80 and SLES (< 1 mN/m). When the HLD of the system was close to 0, a bicontinuous emulsion phase was formed at the oil-water interface. The bicontinuous emulsion broke up over time due to the ultra-low interfacial tension and interfacial turbulence, forming dispersed oil and water droplets. Results from this work provide a practical method to suggest what surfactant composition, salinity, and oil type could promote (or eliminate) the conditions favorable for spontaneous emulsification. These findings are valuable in many fields, such as bilge water treatment, where nanometer-sized emulsions are used.