BEGIN:VCALENDAR
VERSION:2.0
PRODID:-//PHD in Industrial Engineering - ECPv6.15.20//NONSGML v1.0//EN
CALSCALE:GREGORIAN
METHOD:PUBLISH
X-WR-CALNAME:PHD in Industrial Engineering
X-ORIGINAL-URL:https://academics.dii.unipd.it/phd
X-WR-CALDESC:Events for PHD in Industrial Engineering
REFRESH-INTERVAL;VALUE=DURATION:PT1H
X-Robots-Tag:noindex
X-PUBLISHED-TTL:PT1H
BEGIN:VTIMEZONE
TZID:UTC
BEGIN:STANDARD
TZOFFSETFROM:+0000
TZOFFSETTO:+0000
TZNAME:UTC
DTSTART:20250101T000000
END:STANDARD
END:VTIMEZONE
BEGIN:VEVENT
DTSTART;TZID=UTC:20260513T100000
DTEND;TZID=UTC:20260513T130000
DTSTAMP:20260503T220426
CREATED:20260422T151422Z
LAST-MODIFIED:20260422T151422Z
UID:3362-1778666400-1778677200@academics.dii.unipd.it
SUMMARY:Biomedical Imaging with MEMS -day1
DESCRIPTION:Course unit contentsThis course explores Micro-Electro-Mechanical Systems (MEMS) for biomedical imaging and their integration into next-generation diagnostic systems\, focusing on ultrasound and Terahertz (THz) radiation. The curriculum provides the analytical and methodological tools required to design\, model\, and characterize MEMS-based transducers for ultrasound imaging and Terahertz imaging for clinical applications. \nThe course introduces biomedical imaging techniques\, describing the primary role of MEMS devices in both traditional and emerging imaging modalities. The program covers MEMS technology\, discussing different modeling approaches and describing the microfabrication processes that transform Silicon into 3D resonating microstructures. Proposed MEMS transducers modeling methodologies include analytical models based on linear systems theory\, lumped-parameter equivalent circuits\, and Finite Element Method (FEM) simulations. \nLearning goalsBy the end of the course\, participants will have acquired a comprehensive understanding of MEMS operating principles in the biomedical field. Students will develop advanced skills in creating circuital models for micro-electro-mechanical resonators\, as well as multiphysics FEM models featuring electro-mechano-acoustic and thermos-opto-mechanical coupling. Additionally\, attendees will understand the primary figures of merit necessary to evaluate the performance of MEMS-based systems in ultrasound and Terahertz imaging applications. \nSuggested readingsBrenner\, K.; Ergun\, A.S.; Firouzi\, K.; Rasmussen\, M.F.; Stedman\, Q.; Khuri–Yakub\, B. Advances in Capacitive Micromachined Ultrasonic Transducers. Micromachines 2019\, 10\, 152. https://doi.org/10.3390/mi10020152 \nA. Lohfink and P. C. Eccardt\, “Linear and nonlinear equivalent circuit modeling of CMUTs\,” in IEEE Transactions on Ultrasonics\, Ferroelectrics\, and Frequency Control\, vol. 52\, no. 12\, pp. 2163-2172\, Dec. 2005. https://doi.org/10.1109/TUFFC.2005.1563260 \nG. G. Yaralioglu\, S. A. Ergun and B. T. Khuri-Yakub\, “Finite-element analysis of capacitive micromachined ultrasonic transducers\,” in IEEE Transactions on Ultrasonics\, Ferroelectrics\, and Frequency Control\, vol. 52\, no. 12\, pp. 2185-2198\, Dec. 2005. https://doi.org/10.1109/TUFFC.2005.1563262 \nXiang Yang\, Xiang Zhao\, Ke Yang\, Yueping Liu\, Yu Liu\, Weiling Fu\, Yang Luo\, Biomedical Applications of Terahertz Spectroscopy and Imaging\, Trends in Biotechnology\, Volume 34\, Issue 10\, 2016\, Pages 810-824\, ISSN 0167-7799. https://doi.org/10.1016/j.tibtech.2016.04.008 \nVicarelli\, L.; Tredicucci\, A.; Pitanti\, A. Micromechanical Bolometers for Subterahertz Detection at Room Temperature\, ACS Photonics 2022\, 9\, 2\, 360–367. https://doi.org/10.1021/acsphotonics.1c01273
URL:https://academics.dii.unipd.it/phd/event/biomedical-imaging-with-mems-day1/
LOCATION:On-line
CATEGORIES:Event
ATTACH;FMTTYPE=image/png:https://academics.dii.unipd.it/phd/wp-content/uploads/sites/58/2026/04/BIM_2025-2026.png
ORGANIZER;CN="PhD Course in Industrial Engineering":MAILTO:dottorato.dii@unipd.it
END:VEVENT
BEGIN:VEVENT
DTSTART;TZID=UTC:20260519T090000
DTEND;TZID=UTC:20260519T173000
DTSTAMP:20260503T220426
CREATED:20260413T133919Z
LAST-MODIFIED:20260421T151833Z
UID:3242-1779181200-1779211800@academics.dii.unipd.it
SUMMARY:Introduction to Model Order Reduction
DESCRIPTION:Course contentsModel Order Reduction (MOR) is a key technique for decreasing the computational complexity of mathematical models in numerical simulations. This course explores the relationship between MOR and metamodeling\, highlighting its versatile applications across all areas of mathematical modeling and engineering where high-fidelity simulations are required. \nThe curriculum introduces the main numerical approaches used to perform Model Order Reduction\, with a detailed focus on the Proper Orthogonal Decomposition (POD). Students will examine the theoretical foundations of the POD algorithm and its practical implementation. The course features a hands-on component where the POD algorithm is applied to accelerate time-domain simulations of thermal problems using MATLAB\, demonstrating the real-world impact of MOR on large-scale numerical simulations. \nLearning goalsUpon completion of the course\, participants will acquire a comprehensive understanding of the primary numerical techniques for Model Order Reduction. Specifically\, PhD students will develop the ability to apply these methods to dynamic models\, enhancing computational efficiency while maintaining high accuracy in simulation results. \nSuggested readings\nBenner P.\, Grivet-Talocia S.\, Quarteroni A.\, Rozza G.\, Schilders W.\, Magdeburg L. M. S. Model Order Reduction. Three volumes. Doi: 10.1515/9783110499001\nBenner\, P.\, Feng\, L. (2014). A Robust Algorithm for Parametric Model Order Reduction Based on Im- plicit Moment Matching. In: Quarteroni\, A.\, Rozza\, G. (eds)\nReduced Order Methods for  Modeling  and Computational Reduction. MS&A – Modeling\, Simulation and Applications\, vol 9. Springer\, Cham. https://doi.org/10.1007/978-3-319-02090-7_6\nFeng\, L.\, Yue\, Y.\, Banagaaya\, N. et al. Parametric modeling and model order reduction for (electro-)thermal analysis of nanoelectronic structures. J.Math.Industry 6\, 10 (2016).\nY. Liang\, H. Lee\, S. Lim\, W. Lin\, K. Lee\, and C. Wu. Proper orthogonal decomposition and its applica- tions—part i: Theory. Journal of Sound and Vibration\, vol. 252\, no. 3\, pp. 527–544\, 2002\nS. Brunton\, J. Nathan Kutz\, Data-Driven Science and Engineering. Doi: https://doi.org/10.1017/9781108380690
URL:https://academics.dii.unipd.it/phd/event/introduction-to-model-order-reduction/
LOCATION:Sede-V\, via Venezia 1\, Padova\, Padova\, 35131\, Italy
CATEGORIES:Event
ATTACH;FMTTYPE=image/jpeg:https://academics.dii.unipd.it/phd/wp-content/uploads/sites/58/2026/04/CDII_model_1-scaled.jpeg
ORGANIZER;CN="PhD Course in Industrial Engineering":MAILTO:dottorato.dii@unipd.it
END:VEVENT
BEGIN:VEVENT
DTSTART;TZID=UTC:20260520T100000
DTEND;TZID=UTC:20260520T130000
DTSTAMP:20260503T220426
CREATED:20260422T151505Z
LAST-MODIFIED:20260422T151505Z
UID:3361-1779271200-1779282000@academics.dii.unipd.it
SUMMARY:Biomedical Imaging with MEMS -day2
DESCRIPTION:Course unit contentsThis course explores Micro-Electro-Mechanical Systems (MEMS) for biomedical imaging and their integration into next-generation diagnostic systems\, focusing on ultrasound and Terahertz (THz) radiation. The curriculum provides the analytical and methodological tools required to design\, model\, and characterize MEMS-based transducers for ultrasound imaging and Terahertz imaging for clinical applications. \nThe course introduces biomedical imaging techniques\, describing the primary role of MEMS devices in both traditional and emerging imaging modalities. The program covers MEMS technology\, discussing different modeling approaches and describing the microfabrication processes that transform Silicon into 3D resonating microstructures. Proposed MEMS transducers modeling methodologies include analytical models based on linear systems theory\, lumped-parameter equivalent circuits\, and Finite Element Method (FEM) simulations. \nLearning goalsBy the end of the course\, participants will have acquired a comprehensive understanding of MEMS operating principles in the biomedical field. Students will develop advanced skills in creating circuital models for micro-electro-mechanical resonators\, as well as multiphysics FEM models featuring electro-mechano-acoustic and thermos-opto-mechanical coupling. Additionally\, attendees will understand the primary figures of merit necessary to evaluate the performance of MEMS-based systems in ultrasound and Terahertz imaging applications. \nSuggested readingsBrenner\, K.; Ergun\, A.S.; Firouzi\, K.; Rasmussen\, M.F.; Stedman\, Q.; Khuri–Yakub\, B. Advances in Capacitive Micromachined Ultrasonic Transducers. Micromachines 2019\, 10\, 152. https://doi.org/10.3390/mi10020152 \nA. Lohfink and P. C. Eccardt\, “Linear and nonlinear equivalent circuit modeling of CMUTs\,” in IEEE Transactions on Ultrasonics\, Ferroelectrics\, and Frequency Control\, vol. 52\, no. 12\, pp. 2163-2172\, Dec. 2005. https://doi.org/10.1109/TUFFC.2005.1563260 \nG. G. Yaralioglu\, S. A. Ergun and B. T. Khuri-Yakub\, “Finite-element analysis of capacitive micromachined ultrasonic transducers\,” in IEEE Transactions on Ultrasonics\, Ferroelectrics\, and Frequency Control\, vol. 52\, no. 12\, pp. 2185-2198\, Dec. 2005. https://doi.org/10.1109/TUFFC.2005.1563262 \nXiang Yang\, Xiang Zhao\, Ke Yang\, Yueping Liu\, Yu Liu\, Weiling Fu\, Yang Luo\, Biomedical Applications of Terahertz Spectroscopy and Imaging\, Trends in Biotechnology\, Volume 34\, Issue 10\, 2016\, Pages 810-824\, ISSN 0167-7799. https://doi.org/10.1016/j.tibtech.2016.04.008 \nVicarelli\, L.; Tredicucci\, A.; Pitanti\, A. Micromechanical Bolometers for Subterahertz Detection at Room Temperature\, ACS Photonics 2022\, 9\, 2\, 360–367. https://doi.org/10.1021/acsphotonics.1c01273
URL:https://academics.dii.unipd.it/phd/event/biomedical-imaging-with-mems-day2/
LOCATION:On-line
CATEGORIES:Event
ATTACH;FMTTYPE=image/png:https://academics.dii.unipd.it/phd/wp-content/uploads/sites/58/2026/04/BIM_2025-2026.png
ORGANIZER;CN="PhD Course in Industrial Engineering":MAILTO:dottorato.dii@unipd.it
END:VEVENT
BEGIN:VEVENT
DTSTART;TZID=UTC:20260527T100000
DTEND;TZID=UTC:20260527T120000
DTSTAMP:20260503T220426
CREATED:20260422T151553Z
LAST-MODIFIED:20260422T151707Z
UID:3360-1779876000-1779883200@academics.dii.unipd.it
SUMMARY:Biomedical Imaging with MEMS -day3
DESCRIPTION:Course unit contentsThis course explores Micro-Electro-Mechanical Systems (MEMS) for biomedical imaging and their integration into next-generation diagnostic systems\, focusing on ultrasound and Terahertz (THz) radiation. The curriculum provides the analytical and methodological tools required to design\, model\, and characterize MEMS-based transducers for ultrasound imaging and Terahertz imaging for clinical applications. \nThe course introduces biomedical imaging techniques\, describing the primary role of MEMS devices in both traditional and emerging imaging modalities. The program covers MEMS technology\, discussing different modeling approaches and describing the microfabrication processes that transform Silicon into 3D resonating microstructures. Proposed MEMS transducers modeling methodologies include analytical models based on linear systems theory\, lumped-parameter equivalent circuits\, and Finite Element Method (FEM) simulations. \nLearning goalsBy the end of the course\, participants will have acquired a comprehensive understanding of MEMS operating principles in the biomedical field. Students will develop advanced skills in creating circuital models for micro-electro-mechanical resonators\, as well as multiphysics FEM models featuring electro-mechano-acoustic and thermos-opto-mechanical coupling. Additionally\, attendees will understand the primary figures of merit necessary to evaluate the performance of MEMS-based systems in ultrasound and Terahertz imaging applications. \nSuggested readingsBrenner\, K.; Ergun\, A.S.; Firouzi\, K.; Rasmussen\, M.F.; Stedman\, Q.; Khuri–Yakub\, B. Advances in Capacitive Micromachined Ultrasonic Transducers. Micromachines 2019\, 10\, 152. https://doi.org/10.3390/mi10020152 \nA. Lohfink and P. C. Eccardt\, “Linear and nonlinear equivalent circuit modeling of CMUTs\,” in IEEE Transactions on Ultrasonics\, Ferroelectrics\, and Frequency Control\, vol. 52\, no. 12\, pp. 2163-2172\, Dec. 2005. https://doi.org/10.1109/TUFFC.2005.1563260 \nG. G. Yaralioglu\, S. A. Ergun and B. T. Khuri-Yakub\, “Finite-element analysis of capacitive micromachined ultrasonic transducers\,” in IEEE Transactions on Ultrasonics\, Ferroelectrics\, and Frequency Control\, vol. 52\, no. 12\, pp. 2185-2198\, Dec. 2005. https://doi.org/10.1109/TUFFC.2005.1563262 \nXiang Yang\, Xiang Zhao\, Ke Yang\, Yueping Liu\, Yu Liu\, Weiling Fu\, Yang Luo\, Biomedical Applications of Terahertz Spectroscopy and Imaging\, Trends in Biotechnology\, Volume 34\, Issue 10\, 2016\, Pages 810-824\, ISSN 0167-7799. https://doi.org/10.1016/j.tibtech.2016.04.008 \nVicarelli\, L.; Tredicucci\, A.; Pitanti\, A. Micromechanical Bolometers for Subterahertz Detection at Room Temperature\, ACS Photonics 2022\, 9\, 2\, 360–367. https://doi.org/10.1021/acsphotonics.1c01273
URL:https://academics.dii.unipd.it/phd/event/biomedical-imaging-with-mems-day3/
LOCATION:On-line
CATEGORIES:Event
ATTACH;FMTTYPE=image/png:https://academics.dii.unipd.it/phd/wp-content/uploads/sites/58/2026/04/BIM_2025-2026.png
ORGANIZER;CN="PhD Course in Industrial Engineering":MAILTO:dottorato.dii@unipd.it
END:VEVENT
BEGIN:VEVENT
DTSTART;TZID=UTC:20260528T100000
DTEND;TZID=UTC:20260528T120000
DTSTAMP:20260503T220426
CREATED:20260413T132502Z
LAST-MODIFIED:20260421T152225Z
UID:3237-1779962400-1779969600@academics.dii.unipd.it
SUMMARY:Green Chemistry and Technology - day 1
DESCRIPTION:Course contentsThis course explores the fundamental principles of sustainable chemistry and engineering\, focusing on the design of products and processes that minimize environmental impact. The programme bridges theoretical foundations with industrial applications\, providing doctoral candidates with the methodologies required to evaluate and implement “green” innovation in chemical production. \nThe curriculum provides an introduction to green chemistry and sustainable technology\, examining the relationship between chemical engineering and environmental preservation. Key topics include the principles of green nanotechnology—focusing on nanomaterials derived from green sources—and sustainable approaches to energy production\, such as fuel cells. A significant portion of the programme is dedicated to Life Cycle Assessment (LCA) and the use of green metrics to evaluate the environmental performance of chemical processes. Through laboratory sessions\, students will gain hands-on experience in calculating the “greenness” of products\, ensuring they are equipped with the quantitative tools necessary to support sustainable industrial workflows. \nLearning goalsBy the conclusion of the course\, students will master the core principles of green chemistry and engineering. Participants will acquire the analytical capability to perform preliminary assessments of the “greenness” of materials and processes. The goal is to develop a critical understanding of sustainable development\, enabling future researchers to design chemical systems that are both functionally optimized and environmentally responsible. \nReadingsAnastas\, P. T.; Warner\, J. C.; Green Chemistry: Theory and Practice; Oxford University Press: New York\, 2000 (available at Biblioteca Centrale di Ingegneria) \nLancaster\, M.; Green Chemistry: an introductory text; Royal Society of Chemistry: Cambridge\, 2010 (available at Biblioteca Centrale di Ingegneria) \nJiménez-González\, C.C.; Constable\, D.; Green chemistry and engineering: a practical design approach; Wiley: Hoboken\, New Jersey\, 2011 (available online at https://galileodiscovery.unipd.it) \nBenvenuto\, Mark A.\, editor.; Ruger\, George\, editor; Green chemistry and technology; 2021; Berlin; Boston: De Gruyter (available online at https://galileodiscovery.unipd.it) \nMcKeag\, Thomas\, Green chemistry in practice: greener material and chemical innovation through collaboration\, 2023; Kidlington\, England; Cambridge\, MA: Elsevier (available online at https://galileodiscovery.unipd.it) \nTiwari\, Vinod K.\, Tiwari\, Vinod K.\, Green chemistry: introduction\, application and scope\, 2022; 1st ed. 2022; Singapore: Springer (available online at https://galileodiscovery.unipd.it) \nThe lectures’ slides will be made available to all the participants.
URL:https://academics.dii.unipd.it/phd/event/green-chemistry-and-technology/
LOCATION:On-line
CATEGORIES:Event
ATTACH;FMTTYPE=image/jpeg:https://academics.dii.unipd.it/phd/wp-content/uploads/sites/58/2026/04/CDII_green_1-scaled.jpeg
ORGANIZER;CN="PhD Course in Industrial Engineering":MAILTO:dottorato.dii@unipd.it
END:VEVENT
BEGIN:VEVENT
DTSTART;TZID=UTC:20260603T100000
DTEND;TZID=UTC:20260603T120000
DTSTAMP:20260503T220426
CREATED:20260413T120245Z
LAST-MODIFIED:20260422T151641Z
UID:3192-1780480800-1780488000@academics.dii.unipd.it
SUMMARY:Biomedical Imaging with MEMS -day4
DESCRIPTION:Course unit contentsThis course explores Micro-Electro-Mechanical Systems (MEMS) for biomedical imaging and their integration into next-generation diagnostic systems\, focusing on ultrasound and Terahertz (THz) radiation. The curriculum provides the analytical and methodological tools required to design\, model\, and characterize MEMS-based transducers for ultrasound imaging and Terahertz imaging for clinical applications. \nThe course introduces biomedical imaging techniques\, describing the primary role of MEMS devices in both traditional and emerging imaging modalities. The program covers MEMS technology\, discussing different modeling approaches and describing the microfabrication processes that transform Silicon into 3D resonating microstructures. Proposed MEMS transducers modeling methodologies include analytical models based on linear systems theory\, lumped-parameter equivalent circuits\, and Finite Element Method (FEM) simulations. \nLearning goalsBy the end of the course\, participants will have acquired a comprehensive understanding of MEMS operating principles in the biomedical field. Students will develop advanced skills in creating circuital models for micro-electro-mechanical resonators\, as well as multiphysics FEM models featuring electro-mechano-acoustic and thermos-opto-mechanical coupling. Additionally\, attendees will understand the primary figures of merit necessary to evaluate the performance of MEMS-based systems in ultrasound and Terahertz imaging applications. \nSuggested readingsBrenner\, K.; Ergun\, A.S.; Firouzi\, K.; Rasmussen\, M.F.; Stedman\, Q.; Khuri–Yakub\, B. Advances in Capacitive Micromachined Ultrasonic Transducers. Micromachines 2019\, 10\, 152. https://doi.org/10.3390/mi10020152 \nA. Lohfink and P. C. Eccardt\, “Linear and nonlinear equivalent circuit modeling of CMUTs\,” in IEEE Transactions on Ultrasonics\, Ferroelectrics\, and Frequency Control\, vol. 52\, no. 12\, pp. 2163-2172\, Dec. 2005. https://doi.org/10.1109/TUFFC.2005.1563260 \nG. G. Yaralioglu\, S. A. Ergun and B. T. Khuri-Yakub\, “Finite-element analysis of capacitive micromachined ultrasonic transducers\,” in IEEE Transactions on Ultrasonics\, Ferroelectrics\, and Frequency Control\, vol. 52\, no. 12\, pp. 2185-2198\, Dec. 2005. https://doi.org/10.1109/TUFFC.2005.1563262 \nXiang Yang\, Xiang Zhao\, Ke Yang\, Yueping Liu\, Yu Liu\, Weiling Fu\, Yang Luo\, Biomedical Applications of Terahertz Spectroscopy and Imaging\, Trends in Biotechnology\, Volume 34\, Issue 10\, 2016\, Pages 810-824\, ISSN 0167-7799. https://doi.org/10.1016/j.tibtech.2016.04.008 \nVicarelli\, L.; Tredicucci\, A.; Pitanti\, A. Micromechanical Bolometers for Subterahertz Detection at Room Temperature\, ACS Photonics 2022\, 9\, 2\, 360–367. https://doi.org/10.1021/acsphotonics.1c01273
URL:https://academics.dii.unipd.it/phd/event/biomedical-imaging-with-mems/
LOCATION:On-line
CATEGORIES:Event
ATTACH;FMTTYPE=image/png:https://academics.dii.unipd.it/phd/wp-content/uploads/sites/58/2026/04/BIM_2025-2026.png
ORGANIZER;CN="PhD Course in Industrial Engineering":MAILTO:dottorato.dii@unipd.it
END:VEVENT
BEGIN:VEVENT
DTSTART;TZID=UTC:20260604T100000
DTEND;TZID=UTC:20260604T120000
DTSTAMP:20260503T220426
CREATED:20260421T152127Z
LAST-MODIFIED:20260421T152155Z
UID:3327-1780567200-1780574400@academics.dii.unipd.it
SUMMARY:Green Chemistry and Technology – day 2
DESCRIPTION:Course contentsThis course explores the fundamental principles of sustainable chemistry and engineering\, focusing on the design of products and processes that minimize environmental impact. The programme bridges theoretical foundations with industrial applications\, providing doctoral candidates with the methodologies required to evaluate and implement “green” innovation in chemical production. \nThe curriculum provides an introduction to green chemistry and sustainable technology\, examining the relationship between chemical engineering and environmental preservation. Key topics include the principles of green nanotechnology—focusing on nanomaterials derived from green sources—and sustainable approaches to energy production\, such as fuel cells. A significant portion of the programme is dedicated to Life Cycle Assessment (LCA) and the use of green metrics to evaluate the environmental performance of chemical processes. Through laboratory sessions\, students will gain hands-on experience in calculating the “greenness” of products\, ensuring they are equipped with the quantitative tools necessary to support sustainable industrial workflows. \nLearning goalsBy the conclusion of the course\, students will master the core principles of green chemistry and engineering. Participants will acquire the analytical capability to perform preliminary assessments of the “greenness” of materials and processes. The goal is to develop a critical understanding of sustainable development\, enabling future researchers to design chemical systems that are both functionally optimized and environmentally responsible. \nReadingsAnastas\, P. T.; Warner\, J. C.; Green Chemistry: Theory and Practice; Oxford University Press: New York\, 2000 (available at Biblioteca Centrale di Ingegneria) \nLancaster\, M.; Green Chemistry: an introductory text; Royal Society of Chemistry: Cambridge\, 2010 (available at Biblioteca Centrale di Ingegneria) \nJiménez-González\, C.C.; Constable\, D.; Green chemistry and engineering: a practical design approach; Wiley: Hoboken\, New Jersey\, 2011 (available online at https://galileodiscovery.unipd.it) \nBenvenuto\, Mark A.\, editor.; Ruger\, George\, editor; Green chemistry and technology; 2021; Berlin; Boston: De Gruyter (available online at https://galileodiscovery.unipd.it) \nMcKeag\, Thomas\, Green chemistry in practice: greener material and chemical innovation through collaboration\, 2023; Kidlington\, England; Cambridge\, MA: Elsevier (available online at https://galileodiscovery.unipd.it) \nTiwari\, Vinod K.\, Tiwari\, Vinod K.\, Green chemistry: introduction\, application and scope\, 2022; 1st ed. 2022; Singapore: Springer (available online at https://galileodiscovery.unipd.it) \nThe lectures’ slides will be made available to all the participants.
URL:https://academics.dii.unipd.it/phd/event/green-chemistry-and-technology-day-2/
LOCATION:On-line
CATEGORIES:Event
ATTACH;FMTTYPE=image/jpeg:https://academics.dii.unipd.it/phd/wp-content/uploads/sites/58/2026/04/CDII_green_1-scaled.jpeg
ORGANIZER;CN="PhD Course in Industrial Engineering":MAILTO:dottorato.dii@unipd.it
END:VEVENT
BEGIN:VEVENT
DTSTART;TZID=UTC:20260611T100000
DTEND;TZID=UTC:20260611T120000
DTSTAMP:20260503T220426
CREATED:20260421T152319Z
LAST-MODIFIED:20260421T152319Z
UID:3329-1781172000-1781179200@academics.dii.unipd.it
SUMMARY:Green Chemistry and Technology – day 3
DESCRIPTION:Course contentsThis course explores the fundamental principles of sustainable chemistry and engineering\, focusing on the design of products and processes that minimize environmental impact. The programme bridges theoretical foundations with industrial applications\, providing doctoral candidates with the methodologies required to evaluate and implement “green” innovation in chemical production. \nThe curriculum provides an introduction to green chemistry and sustainable technology\, examining the relationship between chemical engineering and environmental preservation. Key topics include the principles of green nanotechnology—focusing on nanomaterials derived from green sources—and sustainable approaches to energy production\, such as fuel cells. A significant portion of the programme is dedicated to Life Cycle Assessment (LCA) and the use of green metrics to evaluate the environmental performance of chemical processes. Through laboratory sessions\, students will gain hands-on experience in calculating the “greenness” of products\, ensuring they are equipped with the quantitative tools necessary to support sustainable industrial workflows. \nLearning goalsBy the conclusion of the course\, students will master the core principles of green chemistry and engineering. Participants will acquire the analytical capability to perform preliminary assessments of the “greenness” of materials and processes. The goal is to develop a critical understanding of sustainable development\, enabling future researchers to design chemical systems that are both functionally optimized and environmentally responsible. \nReadingsAnastas\, P. T.; Warner\, J. C.; Green Chemistry: Theory and Practice; Oxford University Press: New York\, 2000 (available at Biblioteca Centrale di Ingegneria) \nLancaster\, M.; Green Chemistry: an introductory text; Royal Society of Chemistry: Cambridge\, 2010 (available at Biblioteca Centrale di Ingegneria) \nJiménez-González\, C.C.; Constable\, D.; Green chemistry and engineering: a practical design approach; Wiley: Hoboken\, New Jersey\, 2011 (available online at https://galileodiscovery.unipd.it) \nBenvenuto\, Mark A.\, editor.; Ruger\, George\, editor; Green chemistry and technology; 2021; Berlin; Boston: De Gruyter (available online at https://galileodiscovery.unipd.it) \nMcKeag\, Thomas\, Green chemistry in practice: greener material and chemical innovation through collaboration\, 2023; Kidlington\, England; Cambridge\, MA: Elsevier (available online at https://galileodiscovery.unipd.it) \nTiwari\, Vinod K.\, Tiwari\, Vinod K.\, Green chemistry: introduction\, application and scope\, 2022; 1st ed. 2022; Singapore: Springer (available online at https://galileodiscovery.unipd.it) \nThe lectures’ slides will be made available to all the participants.
URL:https://academics.dii.unipd.it/phd/event/green-chemistry-and-technology-day-3/
LOCATION:On-line
CATEGORIES:Event
ATTACH;FMTTYPE=image/jpeg:https://academics.dii.unipd.it/phd/wp-content/uploads/sites/58/2026/04/CDII_green_1-scaled.jpeg
ORGANIZER;CN="PhD Course in Industrial Engineering":MAILTO:dottorato.dii@unipd.it
END:VEVENT
BEGIN:VEVENT
DTSTART;TZID=UTC:20260618T100000
DTEND;TZID=UTC:20260618T120000
DTSTAMP:20260503T220426
CREATED:20260421T152411Z
LAST-MODIFIED:20260421T152411Z
UID:3331-1781776800-1781784000@academics.dii.unipd.it
SUMMARY:Green Chemistry and Technology – day 4
DESCRIPTION:Course contentsThis course explores the fundamental principles of sustainable chemistry and engineering\, focusing on the design of products and processes that minimize environmental impact. The programme bridges theoretical foundations with industrial applications\, providing doctoral candidates with the methodologies required to evaluate and implement “green” innovation in chemical production. \nThe curriculum provides an introduction to green chemistry and sustainable technology\, examining the relationship between chemical engineering and environmental preservation. Key topics include the principles of green nanotechnology—focusing on nanomaterials derived from green sources—and sustainable approaches to energy production\, such as fuel cells. A significant portion of the programme is dedicated to Life Cycle Assessment (LCA) and the use of green metrics to evaluate the environmental performance of chemical processes. Through laboratory sessions\, students will gain hands-on experience in calculating the “greenness” of products\, ensuring they are equipped with the quantitative tools necessary to support sustainable industrial workflows. \nLearning goalsBy the conclusion of the course\, students will master the core principles of green chemistry and engineering. Participants will acquire the analytical capability to perform preliminary assessments of the “greenness” of materials and processes. The goal is to develop a critical understanding of sustainable development\, enabling future researchers to design chemical systems that are both functionally optimized and environmentally responsible. \nReadingsAnastas\, P. T.; Warner\, J. C.; Green Chemistry: Theory and Practice; Oxford University Press: New York\, 2000 (available at Biblioteca Centrale di Ingegneria) \nLancaster\, M.; Green Chemistry: an introductory text; Royal Society of Chemistry: Cambridge\, 2010 (available at Biblioteca Centrale di Ingegneria) \nJiménez-González\, C.C.; Constable\, D.; Green chemistry and engineering: a practical design approach; Wiley: Hoboken\, New Jersey\, 2011 (available online at https://galileodiscovery.unipd.it) \nBenvenuto\, Mark A.\, editor.; Ruger\, George\, editor; Green chemistry and technology; 2021; Berlin; Boston: De Gruyter (available online at https://galileodiscovery.unipd.it) \nMcKeag\, Thomas\, Green chemistry in practice: greener material and chemical innovation through collaboration\, 2023; Kidlington\, England; Cambridge\, MA: Elsevier (available online at https://galileodiscovery.unipd.it) \nTiwari\, Vinod K.\, Tiwari\, Vinod K.\, Green chemistry: introduction\, application and scope\, 2022; 1st ed. 2022; Singapore: Springer (available online at https://galileodiscovery.unipd.it) \nThe lectures’ slides will be made available to all the participants.
URL:https://academics.dii.unipd.it/phd/event/green-chemistry-and-technology-day-4/
LOCATION:On-line
CATEGORIES:Event
ATTACH;FMTTYPE=image/jpeg:https://academics.dii.unipd.it/phd/wp-content/uploads/sites/58/2026/04/CDII_green_1-scaled.jpeg
ORGANIZER;CN="PhD Course in Industrial Engineering":MAILTO:dottorato.dii@unipd.it
END:VEVENT
BEGIN:VEVENT
DTSTART;TZID=UTC:20260623T140000
DTEND;TZID=UTC:20260623T170000
DTSTAMP:20260503T220426
CREATED:20260422T135254Z
LAST-MODIFIED:20260422T135254Z
UID:3353-1782223200-1782234000@academics.dii.unipd.it
SUMMARY:From the Energy Simulation of Buildings to the Environmental Certification Protocols -day2
DESCRIPTION:Course contentsThis course focuses on the thermal and energy performance of the built environment\, addressing the urgent need for decarbonization in the building sector. The programme investigates the energy dynamics of building envelopes and plant systems\, providing doctoral candidates with the methodologies to conduct detailed energy audits\, simulations\, and environmental assessments. \nThe curriculum begins with an introduction to the thermal and energy properties of building envelopes\, establishing the boundary conditions necessary for rigorous design and energy analysis. Detailed modules cover the performance of building components and technical devices\, exploring the energy dynamics of the entire structure. A significant portion of the course is dedicated to regulatory frameworks and sustainability standards\, specifically examining the differences between mandatory energy certification and voluntary environmental protocols. Additionally\, the programme emphasizes the practical use of advanced simulation tools for the energy modeling of buildings and plants. Students will learn to implement dynamic simulations to perform high-fidelity energy audits\, identifying strategies for reducing energy consumption and carbon emissions. The course also addresses the broader environmental impacts of the building field\, analyzing how the application of global protocols influences ecology\, transport\, and pollution mitigation to ensure holistic sustainability. \nLearning goalsBy the end of the course\, students will be able to analyze complex energy challenges within the building sector\, understanding the global impact of construction on the CO2 footprint. Participants will master the procedures for energy certification in Italy and gain a comprehensive knowledge of international sustainability protocols such as GBC\, Itaca\, and BREEAM. Furthermore\, the course sviluppa proficiency in using dynamic simulation tools to evaluate energy-saving potential and to assess the benefits of environmental protocols across various domains\, including indoor well-being\, material selection\, and waste management. \nSuggested readings\nAshrae Standard 90.1-2022—Energy Standard for Sites and Buildings Except Low-Rise Residential Buildings\nFatma S. Hafez et al. (2023) Energy Efficiency in Sustainable Buildings: A Systematic Review with Taxonomy\, Challenges\, Motivations\, Methodological Aspects\, Recommendations\, and Pathways for Future Research. Energy Strategy Reviews Volume 45\, January 2023\, 101013\nZhihang Zheng et al. (2024) Review of the building energy performance gap from simulation and building lifecycle perspectives: Magnitude\, causes and solutions. Developments in the Built Environment Volume 17\, March 2024\, 100345.
URL:https://academics.dii.unipd.it/phd/event/from-the-energy-simulation-of-buildings-to-the-environmental-certification-protocols-day2/
LOCATION:Sede-V\, via Venezia 1\, Padova\, Padova\, 35131\, Italy
CATEGORIES:Event
ATTACH;FMTTYPE=image/jpeg:https://academics.dii.unipd.it/phd/wp-content/uploads/sites/58/2026/04/CDII_buildings-scaled.jpeg
ORGANIZER;CN="PhD Course in Industrial Engineering":MAILTO:dottorato.dii@unipd.it
END:VEVENT
BEGIN:VEVENT
DTSTART;TZID=UTC:20260625T100000
DTEND;TZID=UTC:20260625T120000
DTSTAMP:20260503T220426
CREATED:20260421T152504Z
LAST-MODIFIED:20260421T152504Z
UID:3333-1782381600-1782388800@academics.dii.unipd.it
SUMMARY:Green Chemistry and Technology – day 5
DESCRIPTION:Course contentsThis course explores the fundamental principles of sustainable chemistry and engineering\, focusing on the design of products and processes that minimize environmental impact. The programme bridges theoretical foundations with industrial applications\, providing doctoral candidates with the methodologies required to evaluate and implement “green” innovation in chemical production. \nThe curriculum provides an introduction to green chemistry and sustainable technology\, examining the relationship between chemical engineering and environmental preservation. Key topics include the principles of green nanotechnology—focusing on nanomaterials derived from green sources—and sustainable approaches to energy production\, such as fuel cells. A significant portion of the programme is dedicated to Life Cycle Assessment (LCA) and the use of green metrics to evaluate the environmental performance of chemical processes. Through laboratory sessions\, students will gain hands-on experience in calculating the “greenness” of products\, ensuring they are equipped with the quantitative tools necessary to support sustainable industrial workflows. \nLearning goalsBy the conclusion of the course\, students will master the core principles of green chemistry and engineering. Participants will acquire the analytical capability to perform preliminary assessments of the “greenness” of materials and processes. The goal is to develop a critical understanding of sustainable development\, enabling future researchers to design chemical systems that are both functionally optimized and environmentally responsible. \nReadingsAnastas\, P. T.; Warner\, J. C.; Green Chemistry: Theory and Practice; Oxford University Press: New York\, 2000 (available at Biblioteca Centrale di Ingegneria) \nLancaster\, M.; Green Chemistry: an introductory text; Royal Society of Chemistry: Cambridge\, 2010 (available at Biblioteca Centrale di Ingegneria) \nJiménez-González\, C.C.; Constable\, D.; Green chemistry and engineering: a practical design approach; Wiley: Hoboken\, New Jersey\, 2011 (available online at https://galileodiscovery.unipd.it) \nBenvenuto\, Mark A.\, editor.; Ruger\, George\, editor; Green chemistry and technology; 2021; Berlin; Boston: De Gruyter (available online at https://galileodiscovery.unipd.it) \nMcKeag\, Thomas\, Green chemistry in practice: greener material and chemical innovation through collaboration\, 2023; Kidlington\, England; Cambridge\, MA: Elsevier (available online at https://galileodiscovery.unipd.it) \nTiwari\, Vinod K.\, Tiwari\, Vinod K.\, Green chemistry: introduction\, application and scope\, 2022; 1st ed. 2022; Singapore: Springer (available online at https://galileodiscovery.unipd.it) \nThe lectures’ slides will be made available to all the participants.
URL:https://academics.dii.unipd.it/phd/event/green-chemistry-and-technology-day-5/
LOCATION:On-line
CATEGORIES:Event
ATTACH;FMTTYPE=image/jpeg:https://academics.dii.unipd.it/phd/wp-content/uploads/sites/58/2026/04/CDII_green_1-scaled.jpeg
ORGANIZER;CN="PhD Course in Industrial Engineering":MAILTO:dottorato.dii@unipd.it
END:VEVENT
BEGIN:VEVENT
DTSTART;TZID=UTC:20260626T140000
DTEND;TZID=UTC:20260626T170000
DTSTAMP:20260503T220426
CREATED:20260422T135345Z
LAST-MODIFIED:20260422T135345Z
UID:3352-1782482400-1782493200@academics.dii.unipd.it
SUMMARY:From the Energy Simulation of Buildings to the Environmental Certification Protocols -day3
DESCRIPTION:Course contentsThis course focuses on the thermal and energy performance of the built environment\, addressing the urgent need for decarbonization in the building sector. The programme investigates the energy dynamics of building envelopes and plant systems\, providing doctoral candidates with the methodologies to conduct detailed energy audits\, simulations\, and environmental assessments. \nThe curriculum begins with an introduction to the thermal and energy properties of building envelopes\, establishing the boundary conditions necessary for rigorous design and energy analysis. Detailed modules cover the performance of building components and technical devices\, exploring the energy dynamics of the entire structure. A significant portion of the course is dedicated to regulatory frameworks and sustainability standards\, specifically examining the differences between mandatory energy certification and voluntary environmental protocols. Additionally\, the programme emphasizes the practical use of advanced simulation tools for the energy modeling of buildings and plants. Students will learn to implement dynamic simulations to perform high-fidelity energy audits\, identifying strategies for reducing energy consumption and carbon emissions. The course also addresses the broader environmental impacts of the building field\, analyzing how the application of global protocols influences ecology\, transport\, and pollution mitigation to ensure holistic sustainability. \nLearning goalsBy the end of the course\, students will be able to analyze complex energy challenges within the building sector\, understanding the global impact of construction on the CO2 footprint. Participants will master the procedures for energy certification in Italy and gain a comprehensive knowledge of international sustainability protocols such as GBC\, Itaca\, and BREEAM. Furthermore\, the course sviluppa proficiency in using dynamic simulation tools to evaluate energy-saving potential and to assess the benefits of environmental protocols across various domains\, including indoor well-being\, material selection\, and waste management. \nSuggested readings\nAshrae Standard 90.1-2022—Energy Standard for Sites and Buildings Except Low-Rise Residential Buildings\nFatma S. Hafez et al. (2023) Energy Efficiency in Sustainable Buildings: A Systematic Review with Taxonomy\, Challenges\, Motivations\, Methodological Aspects\, Recommendations\, and Pathways for Future Research. Energy Strategy Reviews Volume 45\, January 2023\, 101013\nZhihang Zheng et al. (2024) Review of the building energy performance gap from simulation and building lifecycle perspectives: Magnitude\, causes and solutions. Developments in the Built Environment Volume 17\, March 2024\, 100345.
URL:https://academics.dii.unipd.it/phd/event/from-the-energy-simulation-of-buildings-to-the-environmental-certification-protocols-day3/
LOCATION:Sede-V\, via Venezia 1\, Padova\, Padova\, 35131\, Italy
CATEGORIES:Event
ATTACH;FMTTYPE=image/jpeg:https://academics.dii.unipd.it/phd/wp-content/uploads/sites/58/2026/04/CDII_buildings-scaled.jpeg
ORGANIZER;CN="PhD Course in Industrial Engineering":MAILTO:dottorato.dii@unipd.it
END:VEVENT
BEGIN:VEVENT
DTSTART;TZID=UTC:20260630T140000
DTEND;TZID=UTC:20260630T170000
DTSTAMP:20260503T220426
CREATED:20260422T135430Z
LAST-MODIFIED:20260422T135430Z
UID:3351-1782828000-1782838800@academics.dii.unipd.it
SUMMARY:From the Energy Simulation of Buildings to the Environmental Certification Protocols -day4
DESCRIPTION:Course contentsThis course focuses on the thermal and energy performance of the built environment\, addressing the urgent need for decarbonization in the building sector. The programme investigates the energy dynamics of building envelopes and plant systems\, providing doctoral candidates with the methodologies to conduct detailed energy audits\, simulations\, and environmental assessments. \nThe curriculum begins with an introduction to the thermal and energy properties of building envelopes\, establishing the boundary conditions necessary for rigorous design and energy analysis. Detailed modules cover the performance of building components and technical devices\, exploring the energy dynamics of the entire structure. A significant portion of the course is dedicated to regulatory frameworks and sustainability standards\, specifically examining the differences between mandatory energy certification and voluntary environmental protocols. Additionally\, the programme emphasizes the practical use of advanced simulation tools for the energy modeling of buildings and plants. Students will learn to implement dynamic simulations to perform high-fidelity energy audits\, identifying strategies for reducing energy consumption and carbon emissions. The course also addresses the broader environmental impacts of the building field\, analyzing how the application of global protocols influences ecology\, transport\, and pollution mitigation to ensure holistic sustainability. \nLearning goalsBy the end of the course\, students will be able to analyze complex energy challenges within the building sector\, understanding the global impact of construction on the CO2 footprint. Participants will master the procedures for energy certification in Italy and gain a comprehensive knowledge of international sustainability protocols such as GBC\, Itaca\, and BREEAM. Furthermore\, the course sviluppa proficiency in using dynamic simulation tools to evaluate energy-saving potential and to assess the benefits of environmental protocols across various domains\, including indoor well-being\, material selection\, and waste management. \nSuggested readings\nAshrae Standard 90.1-2022—Energy Standard for Sites and Buildings Except Low-Rise Residential Buildings\nFatma S. Hafez et al. (2023) Energy Efficiency in Sustainable Buildings: A Systematic Review with Taxonomy\, Challenges\, Motivations\, Methodological Aspects\, Recommendations\, and Pathways for Future Research. Energy Strategy Reviews Volume 45\, January 2023\, 101013\nZhihang Zheng et al. (2024) Review of the building energy performance gap from simulation and building lifecycle perspectives: Magnitude\, causes and solutions. Developments in the Built Environment Volume 17\, March 2024\, 100345.
URL:https://academics.dii.unipd.it/phd/event/from-the-energy-simulation-of-buildings-to-the-environmental-certification-protocols-day4/
LOCATION:Sede-V\, via Venezia 1\, Padova\, Padova\, 35131\, Italy
CATEGORIES:Event
ATTACH;FMTTYPE=image/jpeg:https://academics.dii.unipd.it/phd/wp-content/uploads/sites/58/2026/04/CDII_buildings-scaled.jpeg
ORGANIZER;CN="PhD Course in Industrial Engineering":MAILTO:dottorato.dii@unipd.it
END:VEVENT
BEGIN:VEVENT
DTSTART;TZID=UTC:20260710T140000
DTEND;TZID=UTC:20260710T170000
DTSTAMP:20260503T220426
CREATED:20260422T135201Z
LAST-MODIFIED:20260422T135514Z
UID:3354-1783692000-1783702800@academics.dii.unipd.it
SUMMARY:From the Energy Simulation of Buildings to the Environmental Certification Protocols -day5
DESCRIPTION:Course contentsThis course focuses on the thermal and energy performance of the built environment\, addressing the urgent need for decarbonization in the building sector. The programme investigates the energy dynamics of building envelopes and plant systems\, providing doctoral candidates with the methodologies to conduct detailed energy audits\, simulations\, and environmental assessments. \nThe curriculum begins with an introduction to the thermal and energy properties of building envelopes\, establishing the boundary conditions necessary for rigorous design and energy analysis. Detailed modules cover the performance of building components and technical devices\, exploring the energy dynamics of the entire structure. A significant portion of the course is dedicated to regulatory frameworks and sustainability standards\, specifically examining the differences between mandatory energy certification and voluntary environmental protocols. Additionally\, the programme emphasizes the practical use of advanced simulation tools for the energy modeling of buildings and plants. Students will learn to implement dynamic simulations to perform high-fidelity energy audits\, identifying strategies for reducing energy consumption and carbon emissions. The course also addresses the broader environmental impacts of the building field\, analyzing how the application of global protocols influences ecology\, transport\, and pollution mitigation to ensure holistic sustainability. \nLearning goalsBy the end of the course\, students will be able to analyze complex energy challenges within the building sector\, understanding the global impact of construction on the CO2 footprint. Participants will master the procedures for energy certification in Italy and gain a comprehensive knowledge of international sustainability protocols such as GBC\, Itaca\, and BREEAM. Furthermore\, the course sviluppa proficiency in using dynamic simulation tools to evaluate energy-saving potential and to assess the benefits of environmental protocols across various domains\, including indoor well-being\, material selection\, and waste management. \nSuggested readings\nAshrae Standard 90.1-2022—Energy Standard for Sites and Buildings Except Low-Rise Residential Buildings\nFatma S. Hafez et al. (2023) Energy Efficiency in Sustainable Buildings: A Systematic Review with Taxonomy\, Challenges\, Motivations\, Methodological Aspects\, Recommendations\, and Pathways for Future Research. Energy Strategy Reviews Volume 45\, January 2023\, 101013\nZhihang Zheng et al. (2024) Review of the building energy performance gap from simulation and building lifecycle perspectives: Magnitude\, causes and solutions. Developments in the Built Environment Volume 17\, March 2024\, 100345.
URL:https://academics.dii.unipd.it/phd/event/from-the-energy-simulation-of-buildings-to-the-environmental-certification-protocols-day1/
LOCATION:Sede-V\, via Venezia 1\, Padova\, Padova\, 35131\, Italy
CATEGORIES:Event
ATTACH;FMTTYPE=image/jpeg:https://academics.dii.unipd.it/phd/wp-content/uploads/sites/58/2026/04/CDII_buildings-scaled.jpeg
ORGANIZER;CN="PhD Course in Industrial Engineering":MAILTO:dottorato.dii@unipd.it
END:VEVENT
BEGIN:VEVENT
DTSTART;TZID=UTC:20260721T140000
DTEND;TZID=UTC:20260721T180000
DTSTAMP:20260503T220426
CREATED:20260413T122306Z
LAST-MODIFIED:20260421T152731Z
UID:3211-1784642400-1784656800@academics.dii.unipd.it
SUMMARY:Eco-informed Materials Choice – day1
DESCRIPTION:Course contentsThis course presents advanced strategies for materials selection\, integrating technical functionality with environmental sustainability. The programme focuses on the definition of performance indices and the analysis of the material life cycle\, providing doctoral candidates with the tools needed to optimize component design while minimizing ecological impact. \nThe curriculum introduces the fundamental principles of materials selection through the definition of performance indices\, such as the optimization of component lightness based on density and mechanical properties. Using material property charts\, students will learn rapid selection techniques and extend these methodologies to environmental studies through the definition of ecological performance indices. A significant portion of the course is dedicated to the materials life cycle\, analyzing ecological data sources\, precision\, and values. Through various case studies involving thermal and mechanical properties\, students will explore the practical application of eco-audit tools and specialized software. These modules aim to clarify the complexities of the materials cycle\, emphasizing the critical role of recycling and sustainable energy management in modern engineering design. \nLearning goalsThe primary objective is to provide students with the methodologies required for eco-informed materials selection\, balancing structural requirements with environmental constraints. Participants will gain a deep understanding of the materials life cycle\, with a specific focus on recycling procedures and the realization of tangible energy and emission savings. By the end of the course\, students will be able to implement rigorous eco-audits to support sustainable industrial innovation. \nSuggested readingsCourse slides\, provided by the lecturer \nM.F. Ashby\, Materials and the Environment\, Butterworth Heinemann\, Oxford\, UK (excerpts\, provided by the lecturer) \nM.F. Ashby\, Materials Selection in Mechanical Design\, Butterworth Heinemann\, Oxford\, UK (excerpts\, provided by the lecturer)
URL:https://academics.dii.unipd.it/phd/event/eco-informed-materials-choice/
LOCATION:Sede-V\, via Venezia 1\, Padova\, Padova\, 35131\, Italy
CATEGORIES:Event
ATTACH;FMTTYPE=image/jpeg:https://academics.dii.unipd.it/phd/wp-content/uploads/sites/58/2026/04/CDII_materials_1-scaled.jpeg
ORGANIZER;CN="PhD Course in Industrial Engineering":MAILTO:dottorato.dii@unipd.it
END:VEVENT
BEGIN:VEVENT
DTSTART;TZID=UTC:20260723T140000
DTEND;TZID=UTC:20260723T180000
DTSTAMP:20260503T220426
CREATED:20260421T152618Z
LAST-MODIFIED:20260421T152631Z
UID:3335-1784815200-1784829600@academics.dii.unipd.it
SUMMARY:Eco-informed Materials Choice -day2
DESCRIPTION:Course contentsThis course presents advanced strategies for materials selection\, integrating technical functionality with environmental sustainability. The programme focuses on the definition of performance indices and the analysis of the material life cycle\, providing doctoral candidates with the tools needed to optimize component design while minimizing ecological impact. \nThe curriculum introduces the fundamental principles of materials selection through the definition of performance indices\, such as the optimization of component lightness based on density and mechanical properties. Using material property charts\, students will learn rapid selection techniques and extend these methodologies to environmental studies through the definition of ecological performance indices. A significant portion of the course is dedicated to the materials life cycle\, analyzing ecological data sources\, precision\, and values. Through various case studies involving thermal and mechanical properties\, students will explore the practical application of eco-audit tools and specialized software. These modules aim to clarify the complexities of the materials cycle\, emphasizing the critical role of recycling and sustainable energy management in modern engineering design. \nLearning goalsThe primary objective is to provide students with the methodologies required for eco-informed materials selection\, balancing structural requirements with environmental constraints. Participants will gain a deep understanding of the materials life cycle\, with a specific focus on recycling procedures and the realization of tangible energy and emission savings. By the end of the course\, students will be able to implement rigorous eco-audits to support sustainable industrial innovation. \nSuggested readingsCourse slides\, provided by the lecturer \nM.F. Ashby\, Materials and the Environment\, Butterworth Heinemann\, Oxford\, UK (excerpts\, provided by the lecturer) \nM.F. Ashby\, Materials Selection in Mechanical Design\, Butterworth Heinemann\, Oxford\, UK (excerpts\, provided by the lecturer)
URL:https://academics.dii.unipd.it/phd/event/eco-informed-materials-choice-day2/
LOCATION:Sede-V\, via Venezia 1\, Padova\, Padova\, 35131\, Italy
CATEGORIES:Event
ATTACH;FMTTYPE=image/jpeg:https://academics.dii.unipd.it/phd/wp-content/uploads/sites/58/2026/04/CDII_materials_1-scaled.jpeg
ORGANIZER;CN="PhD Course in Industrial Engineering":MAILTO:dottorato.dii@unipd.it
END:VEVENT
BEGIN:VEVENT
DTSTART;TZID=UTC:20260727T140000
DTEND;TZID=UTC:20260727T180000
DTSTAMP:20260503T220426
CREATED:20260421T152840Z
LAST-MODIFIED:20260421T152840Z
UID:3339-1785160800-1785175200@academics.dii.unipd.it
SUMMARY:Eco-informed Materials Choice -day3
DESCRIPTION:Course contentsThis course presents advanced strategies for materials selection\, integrating technical functionality with environmental sustainability. The programme focuses on the definition of performance indices and the analysis of the material life cycle\, providing doctoral candidates with the tools needed to optimize component design while minimizing ecological impact. \nThe curriculum introduces the fundamental principles of materials selection through the definition of performance indices\, such as the optimization of component lightness based on density and mechanical properties. Using material property charts\, students will learn rapid selection techniques and extend these methodologies to environmental studies through the definition of ecological performance indices. A significant portion of the course is dedicated to the materials life cycle\, analyzing ecological data sources\, precision\, and values. Through various case studies involving thermal and mechanical properties\, students will explore the practical application of eco-audit tools and specialized software. These modules aim to clarify the complexities of the materials cycle\, emphasizing the critical role of recycling and sustainable energy management in modern engineering design. \nLearning goalsThe primary objective is to provide students with the methodologies required for eco-informed materials selection\, balancing structural requirements with environmental constraints. Participants will gain a deep understanding of the materials life cycle\, with a specific focus on recycling procedures and the realization of tangible energy and emission savings. By the end of the course\, students will be able to implement rigorous eco-audits to support sustainable industrial innovation. \nSuggested readingsCourse slides\, provided by the lecturer \nM.F. Ashby\, Materials and the Environment\, Butterworth Heinemann\, Oxford\, UK (excerpts\, provided by the lecturer) \nM.F. Ashby\, Materials Selection in Mechanical Design\, Butterworth Heinemann\, Oxford\, UK (excerpts\, provided by the lecturer)
URL:https://academics.dii.unipd.it/phd/event/eco-informed-materials-choice-day3/
LOCATION:Sede-V\, via Venezia 1\, Padova\, Padova\, 35131\, Italy
CATEGORIES:Event
ATTACH;FMTTYPE=image/jpeg:https://academics.dii.unipd.it/phd/wp-content/uploads/sites/58/2026/04/CDII_materials_1-scaled.jpeg
ORGANIZER;CN="PhD Course in Industrial Engineering":MAILTO:dottorato.dii@unipd.it
END:VEVENT
BEGIN:VEVENT
DTSTART;TZID=UTC:20260729T140000
DTEND;TZID=UTC:20260729T170000
DTSTAMP:20260503T220426
CREATED:20260421T152952Z
LAST-MODIFIED:20260421T152952Z
UID:3341-1785333600-1785344400@academics.dii.unipd.it
SUMMARY:Eco-informed Materials Choice -day4
DESCRIPTION:Course contentsThis course presents advanced strategies for materials selection\, integrating technical functionality with environmental sustainability. The programme focuses on the definition of performance indices and the analysis of the material life cycle\, providing doctoral candidates with the tools needed to optimize component design while minimizing ecological impact. \nThe curriculum introduces the fundamental principles of materials selection through the definition of performance indices\, such as the optimization of component lightness based on density and mechanical properties. Using material property charts\, students will learn rapid selection techniques and extend these methodologies to environmental studies through the definition of ecological performance indices. A significant portion of the course is dedicated to the materials life cycle\, analyzing ecological data sources\, precision\, and values. Through various case studies involving thermal and mechanical properties\, students will explore the practical application of eco-audit tools and specialized software. These modules aim to clarify the complexities of the materials cycle\, emphasizing the critical role of recycling and sustainable energy management in modern engineering design. \nLearning goalsThe primary objective is to provide students with the methodologies required for eco-informed materials selection\, balancing structural requirements with environmental constraints. Participants will gain a deep understanding of the materials life cycle\, with a specific focus on recycling procedures and the realization of tangible energy and emission savings. By the end of the course\, students will be able to implement rigorous eco-audits to support sustainable industrial innovation. \nSuggested readingsCourse slides\, provided by the lecturer \nM.F. Ashby\, Materials and the Environment\, Butterworth Heinemann\, Oxford\, UK (excerpts\, provided by the lecturer) \nM.F. Ashby\, Materials Selection in Mechanical Design\, Butterworth Heinemann\, Oxford\, UK (excerpts\, provided by the lecturer)
URL:https://academics.dii.unipd.it/phd/event/eco-informed-materials-choice-day4/
LOCATION:Sede-V\, via Venezia 1\, Padova\, Padova\, 35131\, Italy
CATEGORIES:Event
ATTACH;FMTTYPE=image/jpeg:https://academics.dii.unipd.it/phd/wp-content/uploads/sites/58/2026/04/CDII_materials_1-scaled.jpeg
ORGANIZER;CN="PhD Course in Industrial Engineering":MAILTO:dottorato.dii@unipd.it
END:VEVENT
BEGIN:VEVENT
DTSTART;TZID=UTC:20260828T090000
DTEND;TZID=UTC:20260828T120000
DTSTAMP:20260503T220426
CREATED:20260413T151034Z
LAST-MODIFIED:20260422T060451Z
UID:3263-1787907600-1787918400@academics.dii.unipd.it
SUMMARY:Principles and Applications of Life Cycle Assessment of Energy Systems -day1
DESCRIPTION:Course contentsThis course provides an advanced exploration of Life Cycle Assessment (LCA) methodologies\, following the international standards ISO 14040 and 14044. The programme focuses on the environmental evaluation of energy systems\, providing doctoral candidates with the analytical tools to monitor and improve the sustainability performance of products and services throughout their entire life cycle. \nThe curriculum covers the four fundamental stages of LCA: goal and scope definition\, inventory analysis\, impact assessment\, and interpretation. Students will examine the most widely used models and updated databases for inventory analysis\, specifically focusing on the proper evaluation of reference systems for electricity and heat production. The course also explores the role of LCA within the context of environmental labeling systems. Through several case studies\, the programme highlights the critical importance of defining functional units\, system boundaries\, and data quality requirements. Significant attention is given to allocation methods and the selection of appropriate impact categories. The course concludes with a hands-on module using SimaPro\, a professional tool for monitoring sustainability performance. Students will apply the software to conduct a complete Life Cycle Analysis of a Renewable Plant\, bridging theoretical knowledge with practical industrial application. \nLearning goalsBy the conclusion of the course\, PhD students will master the fundamental knowledge and principles required to conduct a rigorous Life Cycle Assessment. Participants will develop advanced capabilities to perform basic LCA analyses\, interpreting complex environmental data to support sustainable decision-making. Furthermore\, students will gain proficiency in using professional sustainability tools to assess energy systems and renewable plants. \nSuggested readings\nStoppato A.\, Benato A.\, De Vanna F. (2021)\, “Environmental impact of energy systems integrated with electrochemical accumulators and powered by renewable energy sources in a life-cycle perspective”\, Applied Sciences\, Volume 11\, Issue 62.\nStoppato A. and Benato A. (2020)\, “Life cycle assessment of a commercially available organic Rankine cycle unit coupled with a biomass boiler”\, Energies 13(7)\,1835.\nCavallin Toscani A.\, Stoppato A.\, Benato A. (2019)\, “LCA of a concert: Evaluation of the Carbon footprint and of Cumulative energy demand”\, ECOS 2019 – Proceedings of the 32nd International Conference on Efficiency\, Cost\, Optimization\, Simulation and Environmental Impact of Energy Systems pp. 3203-3213.\nFantinato\, D.\, Stoppato A.\, Benato A. (2019)\, “LCA analysis of a low-energy residential building”\, ECOS 2019 – Proceedings of the 32nd International Conference on Efficiency\, Cost\, Optimization\, Simulation and Environmental Impact of Energy Systems pp. 3153-3165.\nStougie\, L.\, Giustozzi\, N.\, van der Kooi\, H.\, Stoppato\, A. (2018)\, “Environmental\, economic and exergetic sustainability assessment of power generation from fossil and renewable energy sources”\, International Journal of Energy Research 42(9)\, pp. 2916-2926.\nStoppato A. (2008)\, “Life cycle assessment of photovoltaic electricity generation”\, Energy 33(2)\, pp. 224-232.
URL:https://academics.dii.unipd.it/phd/event/principles-and-applications-of-life-cycle-assessment-of-energy-systems/
LOCATION:Sede-V\, via Venezia 1\, Padova\, Padova\, 35131\, Italy
CATEGORIES:Event
ATTACH;FMTTYPE=image/jpeg:https://academics.dii.unipd.it/phd/wp-content/uploads/sites/58/2026/04/CDII_LCA-scaled.jpeg
ORGANIZER;CN="PhD Course in Industrial Engineering":MAILTO:dottorato.dii@unipd.it
END:VEVENT
BEGIN:VEVENT
DTSTART;TZID=UTC:20260904T090000
DTEND;TZID=UTC:20260904T120000
DTSTAMP:20260503T220426
CREATED:20260422T060139Z
LAST-MODIFIED:20260422T060430Z
UID:3344-1788512400-1788523200@academics.dii.unipd.it
SUMMARY:Principles and Applications of Life Cycle Assessment of Energy Systems -day2
DESCRIPTION:Course contentsThis course provides an advanced exploration of Life Cycle Assessment (LCA) methodologies\, following the international standards ISO 14040 and 14044. The programme focuses on the environmental evaluation of energy systems\, providing doctoral candidates with the analytical tools to monitor and improve the sustainability performance of products and services throughout their entire life cycle. \nThe curriculum covers the four fundamental stages of LCA: goal and scope definition\, inventory analysis\, impact assessment\, and interpretation. Students will examine the most widely used models and updated databases for inventory analysis\, specifically focusing on the proper evaluation of reference systems for electricity and heat production. The course also explores the role of LCA within the context of environmental labeling systems. Through several case studies\, the programme highlights the critical importance of defining functional units\, system boundaries\, and data quality requirements. Significant attention is given to allocation methods and the selection of appropriate impact categories. The course concludes with a hands-on module using SimaPro\, a professional tool for monitoring sustainability performance. Students will apply the software to conduct a complete Life Cycle Analysis of a Renewable Plant\, bridging theoretical knowledge with practical industrial application. \nLearning goalsBy the conclusion of the course\, PhD students will master the fundamental knowledge and principles required to conduct a rigorous Life Cycle Assessment. Participants will develop advanced capabilities to perform basic LCA analyses\, interpreting complex environmental data to support sustainable decision-making. Furthermore\, students will gain proficiency in using professional sustainability tools to assess energy systems and renewable plants. \nSuggested readings\nStoppato A.\, Benato A.\, De Vanna F. (2021)\, “Environmental impact of energy systems integrated with electrochemical accumulators and powered by renewable energy sources in a life-cycle perspective”\, Applied Sciences\, Volume 11\, Issue 62.\nStoppato A. and Benato A. (2020)\, “Life cycle assessment of a commercially available organic Rankine cycle unit coupled with a biomass boiler”\, Energies 13(7)\,1835.\nCavallin Toscani A.\, Stoppato A.\, Benato A. (2019)\, “LCA of a concert: Evaluation of the Carbon footprint and of Cumulative energy demand”\, ECOS 2019 – Proceedings of the 32nd International Conference on Efficiency\, Cost\, Optimization\, Simulation and Environmental Impact of Energy Systems pp. 3203-3213.\nFantinato\, D.\, Stoppato A.\, Benato A. (2019)\, “LCA analysis of a low-energy residential building”\, ECOS 2019 – Proceedings of the 32nd International Conference on Efficiency\, Cost\, Optimization\, Simulation and Environmental Impact of Energy Systems pp. 3153-3165.\nStougie\, L.\, Giustozzi\, N.\, van der Kooi\, H.\, Stoppato\, A. (2018)\, “Environmental\, economic and exergetic sustainability assessment of power generation from fossil and renewable energy sources”\, International Journal of Energy Research 42(9)\, pp. 2916-2926.\nStoppato A. (2008)\, “Life cycle assessment of photovoltaic electricity generation”\, Energy 33(2)\, pp. 224-232.
URL:https://academics.dii.unipd.it/phd/event/principles-and-applications-of-life-cycle-assessment-of-energy-systems-day2/
LOCATION:Sede-V\, via Venezia 1\, Padova\, Padova\, 35131\, Italy
CATEGORIES:Event
ATTACH;FMTTYPE=image/jpeg:https://academics.dii.unipd.it/phd/wp-content/uploads/sites/58/2026/04/CDII_LCA-scaled.jpeg
ORGANIZER;CN="PhD Course in Industrial Engineering":MAILTO:dottorato.dii@unipd.it
END:VEVENT
BEGIN:VEVENT
DTSTART;TZID=UTC:20260911T090000
DTEND;TZID=UTC:20260911T130000
DTSTAMP:20260503T220426
CREATED:20260422T060303Z
LAST-MODIFIED:20260422T060349Z
UID:3349-1789117200-1789131600@academics.dii.unipd.it
SUMMARY:Principles and Applications of Life Cycle Assessment of Energy Systems -day3
DESCRIPTION:Course contentsThis course provides an advanced exploration of Life Cycle Assessment (LCA) methodologies\, following the international standards ISO 14040 and 14044. The programme focuses on the environmental evaluation of energy systems\, providing doctoral candidates with the analytical tools to monitor and improve the sustainability performance of products and services throughout their entire life cycle. \nThe curriculum covers the four fundamental stages of LCA: goal and scope definition\, inventory analysis\, impact assessment\, and interpretation. Students will examine the most widely used models and updated databases for inventory analysis\, specifically focusing on the proper evaluation of reference systems for electricity and heat production. The course also explores the role of LCA within the context of environmental labeling systems. Through several case studies\, the programme highlights the critical importance of defining functional units\, system boundaries\, and data quality requirements. Significant attention is given to allocation methods and the selection of appropriate impact categories. The course concludes with a hands-on module using SimaPro\, a professional tool for monitoring sustainability performance. Students will apply the software to conduct a complete Life Cycle Analysis of a Renewable Plant\, bridging theoretical knowledge with practical industrial application. \nLearning goalsBy the conclusion of the course\, PhD students will master the fundamental knowledge and principles required to conduct a rigorous Life Cycle Assessment. Participants will develop advanced capabilities to perform basic LCA analyses\, interpreting complex environmental data to support sustainable decision-making. Furthermore\, students will gain proficiency in using professional sustainability tools to assess energy systems and renewable plants. \nSuggested readings\nStoppato A.\, Benato A.\, De Vanna F. (2021)\, “Environmental impact of energy systems integrated with electrochemical accumulators and powered by renewable energy sources in a life-cycle perspective”\, Applied Sciences\, Volume 11\, Issue 62.\nStoppato A. and Benato A. (2020)\, “Life cycle assessment of a commercially available organic Rankine cycle unit coupled with a biomass boiler”\, Energies 13(7)\,1835.\nCavallin Toscani A.\, Stoppato A.\, Benato A. (2019)\, “LCA of a concert: Evaluation of the Carbon footprint and of Cumulative energy demand”\, ECOS 2019 – Proceedings of the 32nd International Conference on Efficiency\, Cost\, Optimization\, Simulation and Environmental Impact of Energy Systems pp. 3203-3213.\nFantinato\, D.\, Stoppato A.\, Benato A. (2019)\, “LCA analysis of a low-energy residential building”\, ECOS 2019 – Proceedings of the 32nd International Conference on Efficiency\, Cost\, Optimization\, Simulation and Environmental Impact of Energy Systems pp. 3153-3165.\nStougie\, L.\, Giustozzi\, N.\, van der Kooi\, H.\, Stoppato\, A. (2018)\, “Environmental\, economic and exergetic sustainability assessment of power generation from fossil and renewable energy sources”\, International Journal of Energy Research 42(9)\, pp. 2916-2926.\nStoppato A. (2008)\, “Life cycle assessment of photovoltaic electricity generation”\, Energy 33(2)\, pp. 224-232.
URL:https://academics.dii.unipd.it/phd/event/principles-and-applications-of-life-cycle-assessment-of-energy-systems-day3/
LOCATION:Sede-V\, via Venezia 1\, Padova\, Padova\, 35131\, Italy
CATEGORIES:Event
ATTACH;FMTTYPE=image/jpeg:https://academics.dii.unipd.it/phd/wp-content/uploads/sites/58/2026/04/CDII_LCA-scaled.jpeg
ORGANIZER;CN="PhD Course in Industrial Engineering":MAILTO:dottorato.dii@unipd.it
END:VEVENT
END:VCALENDAR