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TZOFFSETFROM:-0500
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DTSTART:20260308T070000
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TZOFFSETFROM:-0400
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DTSTART:20251102T060000
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BEGIN:VEVENT
UID:6a29048b91cdd
DTSTART;TZID=America/Toronto:20260626T100000
SEQUENCE:0
TRANSP:TRANSPARENT
DTEND;TZID=America/Toronto:20260626T110000
URL:https://uwaterloo.ca/chemical-engineering/events/phd-comprehensivetopog
 raphy-functionalized-biomaterials
LOCATION:E6 - Engineering 6 Room 2022 200 University Ave West Waterloo ON N
 2L 3G1 Canada
SUMMARY:PhD Comprehensive/Topography-Functionalized Biomaterials for Tissue
 \nEngineering by Daichen Liu
CLASS:PUBLIC
DESCRIPTION:Thesis Proposal Title: Topography-Functionalized Biomaterials f
 or\nTissue Engineering
DTSTAMP:20260610T063035Z
END:VEVENT
BEGIN:VEVENT
UID:6a29048b950e0
DTSTART;TZID=America/Toronto:20260720T120000
SEQUENCE:0
TRANSP:TRANSPARENT
DTEND;TZID=America/Toronto:20260720T130000
URL:https://uwaterloo.ca/chemical-engineering/events/phd-comprehensivebiomi
 metic-hydrogels-design-strategies-and
LOCATION:E6 - Engineering 6 Room 2022 200 University Ave West Waterloo ON N
 2L 3G1 Canada
SUMMARY:PhD Comprehensive/Biomimetic Hydrogels: Design Strategies and\nTran
 sformative Applications in Biomedicine by Maggie Wong
CLASS:PUBLIC
DESCRIPTION:Biomimetic Hydrogels: Design Strategies and Transformative\nApp
 lications in Biomedicine
DTSTAMP:20260610T063035Z
END:VEVENT
BEGIN:VEVENT
UID:6a29048b95c0d
DTSTART;TZID=America/Toronto:20260513T093000
SEQUENCE:0
TRANSP:TRANSPARENT
DTEND;TZID=America/Toronto:20260513T103000
URL:https://uwaterloo.ca/chemical-engineering/events/seminar-speaker-profes
 sor-lawrence-yoon-suk-lee
LOCATION:E6 - Engineering 6 Room 4022 200 University Ave West Waterloo ON N
 2L 3G1 Canada
SUMMARY:Seminar Speaker: Professor Lawrence Yoon Suk Lee
CLASS:PUBLIC
DESCRIPTION:ABSTRACT \nDriven by the growing need for clean and sustainable
  energy sources\, a\nnumber of carbon-neutral energy conversion technologi
 es have been\nextensively explored over recent years\, which include photo
 - and\nelectrocatalytic water-splitting systems\, fuel cells\, and metal i
 on\nbatteries. In particular\, water electrolysis\, consisting of hydrogen
 \nevolution reaction (HER) and oxygen evolution reaction (OER)\, is\nconsi
 dered a promising and efficient way to produce a clean energy\ncarrier\, h
 ydrogen\, to meet such energy demands. Green hydrogen\nproduced by renewab
 le-energy-powered water electrolysis could help\nresolve the energy crisis
  and cut our carbon footprint at the same\ntime.
DTSTAMP:20260610T063035Z
END:VEVENT
BEGIN:VEVENT
UID:6a29048b9693d
DTSTART;TZID=America/Toronto:20260505T100000
SEQUENCE:0
TRANSP:TRANSPARENT
DTEND;TZID=America/Toronto:20260505T110000
URL:https://uwaterloo.ca/chemical-engineering/events/che-win-joint-seminar
LOCATION:QNC - Quantum Nano Centre Room 1501 200 University Avenue West Wat
 erloo ON N2L 3G1 Canada
SUMMARY:CHE-WIN Joint Seminar
CLASS:PUBLIC
DESCRIPTION:ABSTRACT: Dehumidification accounts for a substantial fraction 
 of\nenergy use and associated emissions in air‑conditioning systems\,\nr
 epresenting roughly 53% of energy‑related air conditioning\nemissions on
  a global average. Vapor-selective membranes\, which\npreferentially trans
 port water molecules while blocking the transport\nof other gases\, have e
 merged as a promising alternative technology for\nthe heating\, ventilatio
 n\, and air conditioning (HVAC) industry\, even\nbeing ranked as a top alt
 ernative technology by the US Department of\nEnergy. Over the past 20 year
 s\, the field has seen a significant\namount of research interest in the d
 evelopment of high-performance\nmembrane materials and synthesis procedure
 s. However\, translation of\nthese materials advances into practical HVAC 
 systems has largely\nrelied on idealized thermodynamic system models\, wit
 h a notable lack\nin experimental demonstration. As a result\, a disconnec
 t persists\nbetween membrane material development\, component-level limita
 tions\,\nand realistic system and process design. This seminar presents ou
 r\nongoing work aimed at bridging this gap by explicitly linking real\nmem
 brane properties to component sizing\, operating constraints\, and\nsystem
 ‑level efficiency. The broader goal of this research is to\nestablish a 
 holistic framework that integrates materials\, components\,\nand system de
 sign to clarify tradeoffs\, define benchmark performance\ntargets\, and gu
 ide future research and development towards the broader\nadoption of high-
 efficiency\, membrane-based HVAC technologies.
DTSTAMP:20260610T063035Z
END:VEVENT
BEGIN:VEVENT
UID:6a29048b97b02
DTSTART;TZID=America/Toronto:20260422T133000
SEQUENCE:0
TRANSP:TRANSPARENT
DTEND;TZID=America/Toronto:20260422T143000
URL:https://uwaterloo.ca/chemical-engineering/events/lecture-series
LOCATION:DC - William G. Davis Computer Research Centre Room 1302 200 Unive
 rsity Avenue West Waterloo ON N2L 3G1 Canada
SUMMARY:Lecture Series
CLASS:PUBLIC
DESCRIPTION:Porous media form the backbone of electrochemical energy storag
 e and\nconversion technologies\, governing transport\, reaction access\, a
 nd\noverall efficiency in redox flow batteries\, electrolyzers\, and fuel\
 ncells. Despite their central role\, most porous electrodes and\ntransport
  layers have changed little over decades\, relying on\nrandomized architec
 tures that constrain performance\, durability\, and\ncost. Dr. van der Hei
 jden’s research group reimagines porous media\nas engineered components\
 , structures that can be deliberately designed\nrather than inherited. By 
 integrating pore‑scale modeling\, operando\nimaging\, computational opti
 mization\, and advanced manufacturing\, the\ngroup uncovers fundamental st
 ructure–performance relationships and\ndevelops new architectures that r
 educe transport losses. This talk\nhighlights how tailored porous microstr
 uctures can enable more\nefficient\, robust\, and scalable electrochemical
  devices.
DTSTAMP:20260610T063035Z
END:VEVENT
BEGIN:VEVENT
UID:6a29048b98735
DTSTART;TZID=America/Toronto:20260423T133000
SEQUENCE:0
TRANSP:TRANSPARENT
DTEND;TZID=America/Toronto:20260423T143000
URL:https://uwaterloo.ca/chemical-engineering/events/phd-defencehalide-and-
 sulfide-solid-electrolytes-all-solid
LOCATION:QNC Room 1501 200 University Avenue West Waterloo ON N2L 3G1 Canad
 a
SUMMARY:PhD Defence/Halide and Sulfide Solid Electrolytes for All-Solid-Sta
 te\nBatteries: Structure and Interface Engineering by Lanting Qian
CLASS:PUBLIC
DESCRIPTION:All-solid-state batteries (ASSBs) are widely regarded as a prom
 ising\nnext-generation energy-storage technology due to their potential to
 \ndeliver enhanced safety\, higher energy density\, and improved\ncompatib
 ility with high-voltage electrode materials. This thesis\nfocuses on the d
 esign\, structural elucidation\, and interfacial\nengineering of halide an
 d sulfide solid electrolytes for high-voltage\nASSBs\, with particular emp
 hasis on understanding how crystallographic\ndisorder and chemical modific
 ation influence lithium-ion transport and\ninterfacial stability. A compre
 hensive suite of experimental and\ncomputational techniques—including sy
 nchrotron and neutron\ndiffraction\, total scattering and pair distributio
 n function analysis\,\nelectron microscopy\, X-ray spectroscopies\, time-o
 f-flight secondary\nion mass spectrometry (ToF-SIMS)\, electrochemical cha
 racterization\,\nand first-principles calculations—is employed to establ
 ish robust\nstructure–property–interface relationships.
DTSTAMP:20260610T063035Z
END:VEVENT
BEGIN:VEVENT
UID:6a29048b9923d
DTSTART;TZID=America/Toronto:20260427T130000
SEQUENCE:0
TRANSP:TRANSPARENT
DTEND;TZID=America/Toronto:20260427T140000
URL:https://uwaterloo.ca/chemical-engineering/events/phd-comprehensivestruc
 ture-processing-function-relationships
LOCATION:E6 - Engineering 6 Room 2022 200 University Ave West Waterloo ON N
 2L 3G1 Canada
SUMMARY:PhD Comprehensive/Structure-Processing-Function Relationships in\nA
 queous-Processed Highly Conductive Hybrid Materials by Hossein\nIpakchi
CLASS:PUBLIC
DESCRIPTION:Structure-Processing-Function Relationships in\nAqueous-Process
 ed Highly Conductive Hybrid Materials
DTSTAMP:20260610T063035Z
END:VEVENT
BEGIN:VEVENT
UID:6a29048b99d08
DTSTART;TZID=America/Toronto:20260501T100000
SEQUENCE:0
TRANSP:TRANSPARENT
DTEND;TZID=America/Toronto:20260501T110000
URL:https://uwaterloo.ca/chemical-engineering/events/distinguished-speaker-
 seminar-series
LOCATION:E6 - Engineering 6 Room 4022 200 University Ave West Waterloo ON N
 2L 3G1 Canada
SUMMARY:Distinguished Speaker Seminar Series
CLASS:PUBLIC
DESCRIPTION:Denitrification is a vital microbial process within the nitroge
 n\ncycle\, where nitrate (NO3⁻) is reduced to nitrogen gas (N2)\, thereb
 y\nalleviating nitrogen pollution in aquatic environments. Traditionally\,
 \norganic carbon sources have been recognized as the primary electron\ndon
 ors for denitrification. However\, recent research has underscored\nthe si
 gnificance of sulfur compounds as alternative electron donors\,\nespeciall
 y in settings where organic carbon is scarce. The current\nparadigm acknow
 ledges the coexistence of heterotrophic and autotrophic\ndenitrifiers in c
 ompleting the denitrification pathway.\nFacultative sulfur-driven denitrif
 ication represents an innovative\nbiological process that integrates sulfi
 de oxidation with\ndenitrification\, providing a dual solution for wastewa
 ter treatment.\nThis process leverages specific heterotrophic bacteria cap
 able of\noxidizing sulfide while concurrently reducing nitrates\, effectiv
 ely\neliminating both sulfide and nitrogen compounds from wastewater. The\
 nfacultative nature of these bacteria enables them to adapt to\nfluctuatin
 g oxygen levels\, thereby enhancing the process's flexibility\nand efficie
 ncy. This presentation will delve into recent advancements\nin facultative
  sulfur-driven denitrification\, with a focus on its\napplication in engin
 eered systems such as wastewater treatment plants\nand bioreactors. By exp
 loring the mechanisms and benefits of this\nprocess\, we aim to highlight 
 its potential for improving wastewater\nmanagement and contributing to sus
 tainable environmental practices.
DTSTAMP:20260610T063035Z
END:VEVENT
BEGIN:VEVENT
UID:6a29048b9a861
DTSTART;TZID=America/Toronto:20260410T090000
SEQUENCE:0
TRANSP:TRANSPARENT
DTEND;TZID=America/Toronto:20260410T100000
URL:https://uwaterloo.ca/chemical-engineering/events/phd-comprehensivelife-
 hydrogels-passive-molecules
LOCATION:E6 - Engineering 6 Room 2022 200 University Ave West Waterloo ON N
 2L 3G1 Canada
SUMMARY:PhD Comprehensive/Life-like Hydrogels: From Passive Molecules to\nI
 ntelligent Microrobots by Negar Rajabi Dehnavi
CLASS:PUBLIC
DESCRIPTION:Life-like Hydrogels: From Passive Molecules to Intelligent Micr
 orobots
DTSTAMP:20260610T063035Z
END:VEVENT
BEGIN:VEVENT
UID:6a29048b9b252
DTSTART;TZID=America/Toronto:20260410T130000
SEQUENCE:0
TRANSP:TRANSPARENT
DTEND;TZID=America/Toronto:20260410T140000
URL:https://uwaterloo.ca/chemical-engineering/events/phd-comprehensivesoft-
 microrobots-advanced-reproductive-cell
LOCATION:E6 - Engineering 6 Room 2022 200 University Ave West Waterloo ON N
 2L 3G1 Canada
SUMMARY:PhD Comprehensive/Soft Microrobots for Advanced Reproductive Cell\n
 Transport (SMARCT) by Negin Bouzari
CLASS:PUBLIC
DESCRIPTION:Soft Microrobots for Advanced Reproductive Cell Transport (SMAR
 CT)
DTSTAMP:20260610T063035Z
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