Hacker Fab is an open-source initiative that provides blueprints, build instructions, and process knowledge for making nanofabrication machines and using them to create integrated circuits. Over IAP, join us for our course consisting of very brief lectures + guided build sessions, in which we will construct a photolithography stepper, spin coater, magnetron sputterer, and work towards the fabrication of diodes and transistors from scratch. The final build session will feature a short lecture and guidance from BreakingTaps!Hacker Fab will be sticking around at MIT after IAP, and is looking for student leaders that would be interested in taking ownership of project directions into the academic year.Please join the Hacker Fab Discord here and assign yourself a role as an MIT student: https://discord.gg/zfssVDC9

Monday, January 27-Friday, January 31, 2025 9:00 am - 1:00 pm ET each day (5 classes) Location: 3-133 Register by Saturday, January 25. Email Pablo Duenas (pduenas@mit.edu)For the 16th consecutive year, this five-session hands-on learning experience continues to evolve, delving into mathematical modeling to understand and accelerate the transition toward net-zero targets. With a primary focus on electricity systems, the course examines their pivotal role in a carbon-constrained economy. Participants will address critical challenges, such as the deployment of renewable energy resources, the surge in active demand response and electric vehicle integration, the synergies between electricity and hydrogen to support deep decarbonization, and the pending expansion of energy access in non-electrified areas of Africa, Latin America, and Asia. These challenges require advanced mathematical models for optimizing and analyzing complex decision-making processes. In addition to theoretical insights, the course offers practical tools, enabling participants to run case studies and explore the impact of different mathematical formulations. Real-world applications will be showcased to underscore the power to inform key stakeholders and public opinion, providing a robust foundation for driving collective action toward a net-zero future.No prior experience is required, although basic familiarity with Python and Julia programming can be helpful. Participants are welcome to attend individual sessions.Monday, January 27Part 0: How mathematical models contribute to achieving the net-zero target on timeCarbon emitters, decarbonization solutions, and the pivotal role of electricityLeveraging models to inform policymakers, stakeholders, and public opinionIntroduction to fundamentals on optimization techniquesPart 1: Removing carbon emissions at the community levelScheduling a decarbonized Home Energy Management System (HEMS)Energy communities and enabling active participation of buildingsTuesday, January 28Part 2: Removing carbon emissions from daily electricity productionUnit-Commitment (UC): daily dispatch of electricity generation unitsManaging uncertainty through stochastic optimization of UCWednesday, January 29Part 3: Removing carbon emissions from annual electricity productionMedium-term operation planningManaging uncertainty through stochastic hydro-thermal coordinationPart 4: The network as the backbone of electric systemsUnderstanding the role of the electricity networkManaging network constraints with Locational Marginal PricingThursday, January 30Part 5: Models for informing utility-scale investmentsBasic concepts: optimal mix problem by screening curvesDOLPHYN: an expansion model for studying low-carbon energy futuresFriday, January 31Part 6: Electrification and energy transition: openTEPES, REM, DECARBopenTEPES: informing infrastructure needs across AfricaREM: developing national electrification plans worldwideDECARB: is the distribution grid ready for wide electrification?InstructorsPablo Duenas, Research Scientist, MIT Energy Initiative (pduenas@mit.edu)Andres Ramos, Professor, Universidad Pontificia Comillas (arght@mit.edu)Javier Garcia-Gonzalez, Professor, Universidad Pontificia Comillas (javiergg@mit.edu)Ruaridh Macdonald, Energy Systems Research Lead, MIT Energy Initiative (rmacd@mit.edu)Yifu Ding, Postdoctoral Associate, MIT Energy Initiative (yifuding@mit.edu)Invited speakersGraham Turk, Deputy Director of Utility Regulation, Connecticut Public Utilities Regulatory Authority

Do you sometimes feel overwhelmed when you sit down to write? Are you ever immobilized by the thought of all the work that’s before you? This writing retreat will transform your writing sessions by teaching you how to quickly clarify what needs to be done, what to do first, and how much to do. In the Ready, Set, Flow Writing Retreat, you will:Understand why it’s so hard to figure out where to startLearn a proven strategy for jumpstarting every writing sessionQuiet your doubts so you can write with focusExperience the boost in motivation that comes from writing with othersBy the end of the retreat, you’ll have made significant progress on your manuscript. And you’ll have a powerful tool you can use to boost your productivity--every time you sit down to write.About Your FacilitatorReady, Set, Flow is facilitated by Michelle Boyd, PhD., Founder and Director of InkWell Academic Writing Retreats. Michelle is an award-winning writer, scholar, and former tenured associate professor from the University of Illinois at Chicago (UIC). She has been leading retreats since 2012, when she co-founded and coached her first retreat at UIC. Three years later, she left faculty life to create InkWell, where she helps scholars who dread writing develop a sustainable, satisfying, productive writing practice.This event is open to SHASS faculty, senior lecturers, graduate students, post-docs, and pre-docs.

Telltales of Tide and Terra is a participatory art project addressing the climate crisis through collaborative art making, public data visualization, and installations, which include shading structures and giant community meals. Upcycled textiles and its patterns transform complex climate data into accessible, emotionally engaging visual experiences that inspire climate action. The project is produced though collaborative screen printing and cyanotype workshops, for an exhibition at the MIT Art Festival (March 1-16, 2025) and the Venice Biennale of Architecture (May '25).You will learn cyanotype and screen printing. Everyone will be listed and credited in these exhibitions.Sign up by 1/20/2025 by emailing Merve Akdogan.

Organzied by the 11-6 (Urban Science and Planning with Computer Science) program, this workshop builds on the urban-related 6.100B problem sets (network routing, recursion and Monte Carlo simulation) but focuses on real-world contexts and decision-making cases. You will look into why these problems matter and who make the decisions - from the access and control of local roads, to mandatory insurance policy for coastal development, to locating essential public services, and hone your innovative problem-solving ability by designing and testing alternative problem formulations and exercising Python programming skills.11.085 | 1-0-1 Units for registered students. Audits welcomed.Schedule (All sessions from 10AM-12PM and will be held in 9-255):Monday, January 27 (Socio-technical Perspectives on Path Optimization Problems)Wednesday, January 29 (Stakeholders’ Interests and Risks in Public Policy Making)Friday, January 31 (Polling Places Locations, Closures and Where to Provide Essential Public Services)

The Art and Science of PCB Design is an introductory course into the fundamental aspects of developing electronic systems on printed circuit boards (PCBs). This course will heavily focus on providing hands-on labs with electronic design tools actively used in industry towards designing a primary course project resulting with the physical assembly of a PCB-based device. Students will gain experience in designing systems, conducting SPICE simulations, drawing schematics, and creating a PCB layout. Complex topics in electrical and PCB design will be explored, including from guest speakers and through advanced simulations. This class is intended for students of all skill-levels but at a minimum requires a basic understanding of circuit analysis, which will be applied towards learning how to implement real devices.Prerequisites: Understanding of basic circuit analysis provided in 6.200, 2.678, or equivalent. Prospective students who have not taken 6.200, 2.678, or an equivalent class will be required to pass a staff-created open-book pretest, prior to the start of IAP, that covers required circuit knowledge for the course. Prospective students should fill out the interest form located at: pcb.mit.edu.Lectures: MWF10, room 2-190Labs: 2-hour lab section on Tuesdays and Thursdays, room 38-530 (times TBD)Office hours: MWF 8a-10a, 11a-1p; TTh 5-7p, room 36-144Once accepted, please register for credit under EC.S03 or 6.S092, 6 units, p/d/f