Chris Staudt is studying electromechanical engineering technology at Columbus State Community College. He is helping with semiconductor research at Ohio State鈥檚 Nanotech West Labs and hopes to have a career in the semiconductor industry.
鈥淪o, I like a lot of the, like, flow sciences and a lot of the things that deal with effectively the way logic flows,鈥 Staudt said. He pointed to the way water flows through a stream, or the way electricity flows through a semiconductor.
A semiconductor is exactly what its name suggests 鈥 it鈥檚 material that is sometimes but not always conductive, and thus able to control the flow of energy. The semiconductors, commonly called chips, that researchers create at Nanotech West are more complex and involve many components and multiple processes to create them, said Dave Hollingshead, manager of research operations.
The ones that tech giant Intel will manufacture at two new fab plants at a mega-site in New Albany will be even more complex, he said.
The chip plants, described by Intel as a , are under construction and could begin production as soon as 2025. Intel has said they will create 3,000 company tech jobs.
But industry experts have raised the question: will there be enough skilled workers to fill them?
Workforce shortage
A by financial advisor Deloitte estimates the U.S. semiconductor workforce will be short by 70,000 to 90,000 people in the coming years. The takes a more conservative approach in saying the expanding supply chain will create upwards of 40,000 new jobs, but that鈥檚 still a lot of help wanted signs.
鈥淚 think that the concern for the workforce is a very fair commentary,鈥 said Peter Mohler, interim executive vice president at Ohio State鈥檚 , or ERIK. It brings together all of OSU鈥檚 colleges to work on complex challenges, which includes bolstering the semiconductor workforce.
Around 70% of semiconductor production jobs are going to be technical and will likely require an education from a technical school or community college, Mohler said. The other 30% will require a bachelor, master, or PhD engineering degree.
So, the effort to raise a workforce, Mohler said, involves a growing number of partnerships between large research universities, community colleges and technical schools.
"The semiconductor fabrication itself requires many different disciplines. It requires chemistry, physics and chemical engineering, mechanical automation and of course, electrical and computer engineering."Siddharth Rajan, Ohio State professor
Collaborative effort
More than 30 institutions in Ohio, Illinois, Indiana, Kentucky, and Michigan are now a part of the OSU-led , which is focused on collaboration and sharing information.
鈥淚t's not just a bunch of academic institutions guessing what is going to be necessary, but having direct lines of communication with the Intel's or other leading manufacturers,鈥 Mohler said.
Intel was not immediately available to comment on whether it's concerned about having a ready workforce. But last year the company over the next decade to 鈥渁ddress immediate semiconductor manufacturing technical challenges and workforce shortages.鈥
Half of the funding is set to go directly to Ohio higher education.
Currently, seven associations of colleges and universities in the state are developing curriculum specifically designed to support the semiconductor industry, Ohio Department of Higher Education Director of Communications Jeff Robinson said.
He said Ohio鈥檚 colleges and universities are expanding existing curriculum and creating short-term boot camps for workers interested in a career change, one-year certificates for entry into the industry as a technician, and additional bachelor's and graduate degree programs.
Opening doors
Siddharth Rajan, a professor of electrical and computer engineering and material science and engineering at Ohio State has been helping revamp OSU's curriculum for semiconductor production.
"We had to sort of increase by almost an order of magnitude the number of students we were putting through these,鈥 Rajan said, acknowledging the talk in the semiconductor industry about worker shortages.
Rajan said the University has upgraded its laboratories and repackaged classes to create a range of programs from undergraduate programs to graduate certificates and specialized master鈥檚 degrees. While some new courses will start in the fall and next spring, Rajan said the main goal is to make existing programs accessible to more students, in part by changing requirements for some courses.
"The semiconductor fabrication itself requires many different disciplines. It requires chemistry, physics and chemical engineering, mechanical automation and of course, electrical and computer engineering,鈥 he said. 鈥淎nd so, all of these disciplines are needed in a fab. So, all this expertise is needed."
Fostering interest
Of course, the programs and funding will only work if there鈥檚 interest in the industry.
Back at Nanotech West, Hollingshead said that semiconductor research has always been conducted at the roughly 20-year-old nanofabrication facility on Kinnear Road, but it鈥檚 grown 鈥渜uite a bit.鈥
鈥淭he interest has ramped up since the Intel announcement,鈥 Hollingshead said.
In addition to researching new materials for semiconductors 鈥 silicon has long been the standard choice 鈥 Nanotech West鈥檚 cleanroom facilities serve as a safe environment for students like Staudt and fellow Columbus State attendee Zachary Reese to learn.
Both from Galloway, Staudt and Reese said they are likely to stay in Ohio now that Intel is on it鈥檚 way in.
Staudt said he knows other people who are interested in semiconductor production.
鈥淎 lot of people tend towards the software now, though. But I think interest in hardware is still out there,鈥 Staudt said.
鈥淔or me, it feels like I'm really the only one.鈥 Reese said. 鈥淚 mean, [Staudt] lives like five minutes away, but I know nobody that is into this stuff. So, it's like all my friends think I'm like, so cool with this gown on in the clean room, and I'm like an outsider.鈥