Hampshire ran on a simple premise. Students learn more when they direct their own education. No required courses, no grades, narrative evaluations instead of transcripts. It produced Ken Burns, among a long list of graduates who learned to frame problems from scratch. Then it ran out of money. At $29,683 per semester, with 625 students and a $26.5 million endowment, the finances were never going to hold.
The finances failed. The pedagogy did not.
Engineering education runs on the opposite assumption. Students cannot be trusted to direct their own learning until they survive two years of calculus sequences, physics surveys, and weed-out courses designed less to teach than to filter. ABET accreditation requires programs to demonstrate prescribed curricular coverage across a fixed sequence, and schools optimize for compliance. Roughly half of engineering students switch majors or drop out, most citing the culture of years one and two. The students who make it through are good at structured problem sets. Whether they can identify a problem worth solving is a separate question the curriculum rarely addresses. The NAE's analysis of engineering education and workforce pathways has long flagged a gap between what programs produce and what employers actually need: graduates with strong professional and problem-framing skills alongside technical ones.
A Hampshire-style engineering school would look different. Students identify a technical challenge in the first semester and spend four years building toward a solution, pulling in mathematics, circuits, materials, software, and fabrication as the work demands. Faculty serve as advisors. Credentialing comes from demonstrated competency, not accumulated credit hours. The model produces engineers who can operate without a defined rubric, which is the actual job description for most engineers after around year three. Olin College of Engineering in Needham, Massachusetts has run a version of this since 2002 and its graduates are consistently sought after. The model exists and it works.
The timing matters. AI handles the structured problem set. Tools like Gemini and Claude write the code, run the simulation, and check the math. The irreplaceable skill is knowing what problem to run. Engineers who are excellent inside a defined problem space and lost outside it are the engineers whose value will compress fastest. Quantum, biotech, and climate tech all require graduates who can work across disciplines without a map. The standard curriculum produces the wrong graduate for all three.
The objections are real: accreditation, licensure, employer acceptance. All solvable, given enough will. The campus infrastructure is already there, sitting on several hundred acres in the Pioneer Valley. Hampshire's library, labs, and residential buildings are not going anywhere quickly. The harder problem is finding people with the will to try something genuinely different rather than build another school that looks exactly like the others.
Hampshire believed every student was capable of running their own education, even if they occasionally used that freedom poorly. Engineering education has never believed that. Maybe we should try.
