BEGIN:VCALENDAR
VERSION:2.0
X-WR-CALNAME:EventsCalendar
PRODID:-//hacksw/handcal//NONSGML v1.0//EN
CALSCALE:GREGORIAN
BEGIN:VTIMEZONE
TZID:America/New_York
LAST-MODIFIED:20240422T053451Z
TZURL:https://www.tzurl.org/zoneinfo-outlook/America/New_York
X-LIC-LOCATION:America/New_York
BEGIN:DAYLIGHT
TZNAME:EDT
TZOFFSETFROM:-0500
TZOFFSETTO:-0400
DTSTART:19700308T020000
RRULE:FREQ=YEARLY;BYMONTH=3;BYDAY=2SU
END:DAYLIGHT
BEGIN:STANDARD
TZNAME:EST
TZOFFSETFROM:-0400
TZOFFSETTO:-0500
DTSTART:19701101T020000
RRULE:FREQ=YEARLY;BYMONTH=11;BYDAY=1SU
END:STANDARD
END:VTIMEZONE
BEGIN:VEVENT
CATEGORIES:College of Engineering,Thesis/Dissertations
DESCRIPTION:Title: "Predicting Microbiologically Influenced Corrosion Sever
ity from Electrochemical Impedance Spectroscopy Using Interpretable Machin
e Learning" by Raksha Mohan Thesis Advisor: Maricris Mayes, Associate Prof
essor, Chemistry & Biochemistry Thesis Committee:Firas Khatib, Associate P
rofessor, Computer & Information ScienceDonghui Yan, Associate Professor,
Mathematics Abstract: Microbiologically influenced corrosion (MIC) account
s for an estimated 20-30% of global corrosion losses, yet reliable quantit
ative prediction of MIC severity remains unsolved. Electrochemical measure
ments combined with interpretable machine learning provide a promising fra
mework for addressing this challenge. MIC depends on coupled microbial, bi
ofilm, and interfacial electrochemical processes, and charge-transfer resi
stance (Rct) is a useful proxy for corrosion severity, as expressed in log
₁₀(Rct) from electrochemical impedance spectroscopy (EIS). However, ph
ysically interpretable predictive models for MIC remain limited. Here, we
show that machine learning regressors can predict log₁₀(Rct) in MIC sy
stems involving Pseudomonas and Vibrio across varying environmental condit
ions. A dataset of 116 EIS and 83 potentiodynamic polarization observation
s was compiled from ten peer-reviewed sources. Random forest and Gradient
Boosting Machine (GBM) regressors were compared using stratified five-fold
cross-validation, and Shapley additive explanations (SHAP) were used to i
nterpret model behavior in physically meaningful terms. GBM outperformed R
andom Forest, achieving a higher cross-validated R². SHAP analysis identi
fied double-layer CPE admittance as the dominant predictor of corrosion se
verity, consistent with its role as a reporter of biofilm-induced interfac
ial disorder, while genomic species descriptors contributed modest but int
erpretable signals consistent with known difference in metabolic versatili
ty between the two organisms. This work establishes a reproducible and int
erpretable baseline for quantitative MIC prediction and, to our knowledge,
provides the first application of SHAP analysis to EIS-derived features i
n MIC while demonstrating the value of integrating genomic descriptors wit
h electrochemical features for corrosion modeling. Zoom Meeting ID: 922 35
04 5299Passcode: 941562\nEvent page: /events/cms/dat
a-science-ms-thesis-defense-by-raksha-mohan.php\nEvent link: https://umass
d.zoom.us/j/92235045299?pwd=gOpd6QBNGaNhrJaTwjQXCEkGjk8iSb.1
X-ALT-DESC;FMTTYPE=text/html:Title: "Predicting Microbiologi
cally Influenced Corrosion Severity from Electrochemical Impedance Spectro
scopy Using Interpretable Machine Learning"
\nby Raksha Mohan
\n<
p>Thesis Advisor: Maricris Mayes\, Associate Professor\, Chemistry & Bioch
emistry\nThesis Committee:
Firas Khatib\, Associate Professor\
, Computer & Information Science
Donghui Yan\, Associate Professor\,
Mathematics
\nAbstract:
\nMicrobiologically influenced corrosi
on (MIC) accounts for an estimated 20-30% of global corrosion losses\, yet
reliable quantitative prediction of MIC severity remains unsolved. Electr
ochemical measurements combined with interpretable machine learning provid
e a promising framework for addressing this challenge. MIC depends on coup
led microbial\, biofilm\, and interfacial electrochemical processes\, and
charge-transfer resistance (Rct) is a useful proxy for corrosion severity\
, as expressed in log₁₀(Rct) from electrochemical impedance spectrosco
py (EIS). However\, physically interpretable predictive models for MIC rem
ain limited. Here\, we show that machine learning regressors can predict l
og₁₀(Rct) in MIC systems involving Pseudomonas and Vibrio across varyi
ng environmental conditions.
\nA dataset of 116 EIS and 83 potentiod
ynamic polarization observations was compiled from ten peer-reviewed sourc
es. Random forest and Gradient Boosting Machine (GBM) regressors were comp
ared using stratified five-fold cross-validation\, and Shapley additive ex
planations (SHAP) were used to interpret model behavior in physically mean
ingful terms. GBM outperformed Random Forest\, achieving a higher cross-va
lidated R². SHAP analysis identified double-layer CPE admittance as the d
ominant predictor of corrosion severity\, consistent with its role as a re
porter of biofilm-induced interfacial disorder\, while genomic species des
criptors contributed modest but interpretable signals consistent with know
n difference in metabolic versatility between the two organisms.
\nT
his work establishes a reproducible and interpretable baseline for quantit
ative MIC prediction and\, to our knowledge\, provides the first applicati
on of SHAP analysis to EIS-derived features in MIC while demonstrating the
value of integrating genomic descriptors with electrochemical features fo
r corrosion modeling.
\nZoom Meeting ID: 922 3504 5299
Passcode
: 941562
Event page: /eve
nts/cms/data-science-ms-thesis-defense-by-raksha-mohan.php
Event li
nk:
DTSTAMP:20260423T082059
DTSTART;TZID=America/New_York:20260423T120000
DTEND;TZID=America/New_York:20260423T140000
LOCATION:SENG 311
SUMMARY;LANGUAGE=en-us:Data Science MS Thesis Defense by Raksha Mohan
UID:c9e796823e980d8f8f37314e5467ae2b@www.umassd.edu
END:VEVENT
END:VCALENDAR