{"id":1725,"date":"2008-01-16T17:17:26","date_gmt":"2008-01-16T22:17:26","guid":{"rendered":"https:\/\/engineering.jhu.edu\/magazine-archive\/?p=1725"},"modified":"2014-12-16T17:17:45","modified_gmt":"2014-12-16T22:17:45","slug":"whither-job-market","status":"publish","type":"post","link":"https:\/\/engineering.jhu.edu\/magazine-archive\/2008\/01\/whither-job-market\/","title":{"rendered":"Whither the Job Market?"},"content":{"rendered":"

We tapped a bevy of engineering \u201cforecasters\u201d to find out what fields will be hottest in the decade to come.<\/strong><\/p>\n

Surprising as it may sound, the most common undergraduate degree among today\u2019s CEOs isn\u2019t business or economics. It\u2019s engineering.<\/p>\n

More than ever, engineers are venturing into just about every niche of corporate America. Both Lee Raymond, who runs ExxonMobil, and Jack Welch, the man who famously brought GE back from the edge, have PhDs in chemical engineering. Philip Condit\u2019s combined degrees in mechanical and aeronautical engineering helped him run Boeing from 1996 to 2003, and Gordon Harton, the retired president of the Lee jeans brand, didn\u2019t study fashion design; he earned a degree in industrial engineering. Here at Johns Hopkins, both President William R. Brody and new Provost Kristina Johnson are electrical engineers.<\/p>\n

It would be an understatement to say that the demand for engineers has broadened beyond labs and engineering firms. Without a doubt, engineers will continue to be needed to fill the roles we\u2019ve come to expect\u2014 designing bridges, building robots, creating computer code. But today, the pace at which highly trained engineers are being sought by sectors of America\u2019s non-engineering job market is increasing faster than ever.<\/p>\n

The U.S. Bureau of Labor optimistically predicts a 9 percent to 17 percent increase in engineering jobs between 2004 and 2014 (with the caveat that the boosted job market \u201cvaries by specialty\u201d), while a 2005 report to Congress from members of the National Academies predicts an alarming dearth of American engineers over the next 10 years. All of this comes at a time when U.S. companies, particularly in the fields of manufacturing and engineering, are moving significant portions of their operations overseas\u2014 from their customer help desks to their manufacturing facilities.<\/p>\n

In such a dramatically shifting job market, young engineers collectively scratch their heads and wonder: In 10 years, how many jobs for engineers will exist in the United States, what will those jobs be, and how do we best prepare for them?<\/p>\n

Gusts of Change<\/h4>\n

In 1853, a young man named Daniel Coit Gilman sailed to Europe to serve for two years as attach\u00e9 of the American legation at St. Petersburg. During his time abroad, the newly minted Yale graduate became an arduous observer of the European educational system, visiting colleges in Britain and across Europe. But it was the German institutions that caught his attention, and he found himself attending lectures at the University of Berlin during the cold winter months of 1855.<\/p>\n

The time in Germany had an impact. Gilman, who became Johns Hopkins\u2019 founding president in 1875, built a university on the principles of German education, emphasizing research and scholarly publications. Gilman was a genius for his ability to understand society\u2019s need for scientific study and professional training at an advanced level. Under his guidance, Johns Hopkins became the country\u2019s first research university, setting the course for the development and future success of the university\u2019s School of Engineering.<\/p>\n

\u201cAmerica\u2019s trend toward outsourcing overseas has focused mainly on routine engineering work…meanwhile, the demand for expert thinking has grown.\u201dBill Kelly, American Society for Engineering Education<\/cite><\/p><\/blockquote>\n

When admitting its first engineering students in 1912, Johns Hopkins adhered to its original mission of the pursuit of knowledge through research. For nearly a century, the School of Engineering has continued to fuse advanced scholarship with research and applied technologies, preparing students to think broadly and beyond the narrow constraints of a single field of study.<\/p>\n

But that kind of research-based preparation isn\u2019t the norm among American universities according to Bill Kelly, the manager of public affairs for the American Society for Engineering Education (ASEE). He points a disappointed finger at the \u201cfairly slow\u201d rate at which the majority of American academia has customized the education of engineers to match the rapidly advancing technologies of today\u2019s world.<\/p>\n

Kelly, who before joining the ASEE in 2007 served as dean of the School of Engineering for The Catholic University of America, explains that America\u2019s trend toward outsourcing overseas has focused mainly on routine engineering work and says that, meanwhile, the \u201cdemand for expert thinking has grown.\u201d As the work being performed in the U.S. becomes increasingly sophisticated and technology-dependent, he says that the marketplace will demand more engineers like those from Johns Hopkins who can apply concepts and theory in a highly innovative setting.<\/p>\n

\u201cOverall, change in engineering education is going to have to pick up the pace,\u201d he says. \u201cAdvancing engineering education will require getting undergraduates into faculty labs, into internships and study abroad programs, performing work that isn\u2019t routine, and gaining experience that reflects the type of work happening in the real world.\u201d<\/p>\n