Award Date
August 2025
Degree Type
Dissertation
Degree Name
Doctor of Philosophy (PhD)
Department
Mechanical Engineering
First Committee Member
Kwang Kim
Second Committee Member
Brendan O'Toole
Third Committee Member
Woosoon Yim
Fourth Committee Member
Jeremy Cho
Fifth Committee Member
David Lee
Number of Pages
221
Abstract
Nature can often create some of the most efficient and elegant solutions to complex problems, and engineering stands to benefit greatly from these time-tested designs. One of the more sophisticated examples of this is the lateral line system in fish: a distributed network of superficial and canal neuromasts that enables aquatic species to detect fluid disturbances with remarkable precision. This dissertation leverages that biological framework to explore the potential of electroactive polymers (EAPs), aiming not just to replicate structure, but to emulate function.Two classes of EAPs form the basis of this work: electroactive plasticized polymer gels (EPPGs) and ionic polymer-metal composites (IPMCs). Both offer their own unique morphology and mechanoelectrical transduction (MET) mechanisms that make them well-suited candidates for mimicking the different components of an artificial lateral line. Their implementation is examined across two case studies: (1) a soft surface-mounted sensing skin inspired by superficial neuromasts, and (2) an internal sensor embedded within a synthetic canal structure, emulating the filtering behavior of canal neuromasts. The relationship between fluid dynamics, sensor geometry, and EAP response was explored through an integrated analytical, numerical, and experimental framework. The artificial skin successfully detected turbulent transitions at predicted thresholds, capturing nuanced spatial disturbances downstream. The canal sensor exhibited clear frequency-selective resonance around 90–110 Hz, matching analytical and simulation predictions. These findings demonstrate the feasibility of bioinspired EAP flow sensors and highlight opportunities to refine analytical models through experimental insights, enhancing real-world fluid sensing applications.
Keywords
Bioinspired Sensors; Electroactive Polymers; Flow Sensing; Fluid-Structure Interaction; Lateral Line System; Smart Materials
Disciplines
Aerodynamics and Fluid Mechanics | Engineering Science and Materials | Materials Science and Engineering | Mechanical Engineering
File Format
Degree Grantor
University of Nevada, Las Vegas
Language
English
Repository Citation
Minaian, Nazanin, "Bio-Inspired Electroactive Polymer (EAP) Sensors for Surface and Canal Flow Sensing in Dynamic Environments" (2025). UNLV Theses, Dissertations, Professional Papers, and Capstones. 5388.
http://dx.doi.org/10.34917/39385614
Rights
IN COPYRIGHT. For more information about this rights statement, please visit http://rightsstatements.org/vocab/InC/1.0/
Included in
Aerodynamics and Fluid Mechanics Commons, Engineering Science and Materials Commons, Materials Science and Engineering Commons, Mechanical Engineering Commons