Aim
This program focuses on how nanotechnology is transforming industrial filtration—from high-flux membranes and nano-enabled adsorbents to anti-fouling coatings and smart filtration systems. Participants will learn how nano-material choices (nanofibers, graphene-based layers, metal oxides, nanocomposites, and functional coatings) improve selectivity, permeability, durability, and contaminant removal across water treatment, pharmaceuticals, chemicals, food processing, and air filtration industries.
Program Objectives
- Understand filtration fundamentals and where nano-enabled systems deliver real advantages.
- Explore nanomaterials used in membranes, filters, and adsorbent-based separation systems.
- Learn design strategies for high flux, high selectivity, and long operational lifetime.
- Study fouling mechanisms and nano-based anti-fouling / self-cleaning approaches.
- Build practical knowledge of fabrication, characterization, and performance benchmarking.
- Understand scale-up, safety, compliance, and industrial implementation considerations.
Program Structure (Humanized)
Module 1: Why Industrial Filtration Needs Nano-innovation
- We start with the real-world challenges: fouling, high energy use, low selectivity, and short membrane life.
- Where nanotechnology helps: better pore control, higher surface area, smarter interfaces, and stronger materials.
- Industrial contexts: water reuse, pharma-grade purification, chemical separations, and clean air systems.
Module 2: Filtration Fundamentals (Fast, Practical, and Useful)
- Membrane processes: microfiltration, ultrafiltration, nanofiltration, reverse osmosis.
- Key performance metrics: flux, rejection, selectivity, TMP, permeability, and recovery.
- Separation mechanisms: size exclusion, charge repulsion, adsorption, and affinity-based capture.
Module 3: Nanomaterials Used in Industrial Filtration
- Nanofibers (electrospun mats) for high surface area and tunable porosity.
- Carbon nanomaterials: graphene oxide and CNT concepts for enhanced transport and selectivity.
- Metal/metal oxide nanomaterials: TiO₂, ZnO, Fe₃O₄ for antimicrobial and catalytic effects.
- Nanocomposites: polymer + nano-fillers for strength, permeability, and fouling resistance.
Module 4: Membrane Fabrication & Nano-integration Strategies
- How nano-enhanced membranes are actually built: blending, coating, interfacial assembly, and layer stacking.
- Surface functionalization to control hydrophilicity, charge, and affinity.
- Thin-film nanocomposite (TFN) logic and why it improves performance (conceptual workflow).
- Practical issues: aggregation, leaching, and maintaining uniform dispersion.
Module 5: Anti-fouling and Self-cleaning Designs
- Understanding fouling types: organic, inorganic scaling, biofouling, and colloidal fouling.
- Nano-enabled anti-fouling strategies: hydrophilic layers, zwitterionic concepts, antimicrobial surfaces.
- Self-cleaning ideas: photocatalytic coatings (TiOâ‚‚), reactive surfaces, and easy-release interfaces.
- How to evaluate fouling resistance: flux decline curves and cleaning recovery.
Module 6: Nano-adsorbents and Hybrid Filtration Systems
- When membranes alone are not enough: combining adsorption + filtration for stronger removal.
- Nano-adsorbents for heavy metals, dyes, organics, PFAS-like contaminants (conceptual), and pathogens.
- Magnetic nano-adsorbents for easy recovery and regeneration (workflow-level).
- Designing hybrid systems: pre-treatment + membrane polishing for industrial quality output.
Module 7: Characterization & Performance Benchmarking
- Membrane morphology and pore structure: SEM concepts, porometry overview.
- Surface properties: contact angle (hydrophilicity), surface charge (zeta potential concepts).
- Mechanical and chemical durability testing for industrial conditions.
- Performance tests: flux, rejection, long-run stability, and fouling recovery.
Module 8: Industrial Applications & Case Scenarios
- Water and wastewater: heavy metals, dyes, oil-water separation, and reuse systems.
- Pharmaceutical and biotech: high-purity filtration, sterility assurance concepts, process polishing.
- Chemical and petrochemical: solvent-resistant filtration and separation challenges.
- Food and beverage: clarification, contaminant removal, and hygiene-driven filtration.
- Air filtration: fine particulate capture and antimicrobial filter surfaces (overview).
Module 9: Scale-up, Safety, and Implementation Challenges
- Scaling fabrication: consistency, coating uniformity, and batch-to-batch reproducibility.
- Nanomaterial leaching and containment—how industries manage the risk.
- Operational costs: energy, cleaning chemicals, membrane replacement cycles.
- EHS considerations: safe handling, disposal, and basic compliance thinking.
Module 10: Emerging Trends & Future Directions
- Smart membranes: responsive gating, sensing-integrated filtration (conceptual).
- Advanced anti-fouling chemistries and next-gen coatings.
- AI/IoT monitoring for predictive maintenance and performance optimization (overview).
- Commercial readiness: what makes a nano-filtration solution adoptable at scale.
Final Project (Industry-Style Design Task)
- Design a nano-enabled filtration solution for a chosen industrial sector (water/pharma/chemical/air/food).
- Choose materials, membrane type, nano-integration strategy, and anti-fouling approach.
- Create a validation plan: characterization + performance + fouling tests + durability checks.
- Example projects: TFN membrane for dye wastewater, nano-adsorbent + UF hybrid for heavy metal removal, anti-biofouling membrane for industrial reuse.
Participant Eligibility
- Students and researchers in Materials Science, Chemical Engineering, Environmental Science, and Nanotechnology.
- Industry professionals in water treatment, filtration systems, pharma manufacturing, and chemical processing.
- R&D and plant teams involved in membranes, separation, and process optimization.
Program Outcomes
- Understand how nanomaterials improve filtration performance and lifetime.
- Ability to select membrane types and nano-integration strategies for specific contaminants.
- Practical understanding of fouling mechanisms and anti-fouling design approaches.
- Confidence in planning filtration performance tests and interpreting key metrics.
- Awareness of scale-up, safety, cost, and industrial implementation needs.
Program Deliverables
- Access to e-LMS: Full access to learning resources, case studies, and templates.
- Hands-on Assignments: Material selection tasks, filtration design worksheets, and benchmarking exercises.
- Project Guidance: Mentor support for final project design and reporting.
- Final Examination: Certification awarded after successful completion of exam and assignments.
- e-Certification and e-Marksheet: Digital credentials provided upon successful completion.
Future Career Prospects
- Membrane / Filtration R&D Specialist
- Water Treatment Process Engineer (Nano-enabled Systems)
- Separation Science & Materials Scientist
- Industrial Sustainability & Resource Recovery Analyst
- Environmental Nanotechnology Researcher
- Advanced Filtration Product Development Associate
Job Opportunities
- Water & Wastewater Treatment Companies: Membrane and filtration technology teams.
- Pharmaceutical & Biotech Manufacturing: High-purity filtration and process separation roles.
- Chemical & Petrochemical Industry: Separation materials and solvent-resistant filtration development.
- Food & Beverage Processing: Process filtration optimization and hygiene-driven filtration systems.
- Air Filtration & HVAC Companies: Advanced particulate capture and antimicrobial filter R&D.
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