Mechanical Engineer; Spector

About Veeco

You probably don’t realize it, but what we do at Veeco touches the lives of every person, every day. It’s a bold statement, but it’s true. From the smartphones in our pockets that access the world’s collective knowledge, to the cloud-based services where all that information lives, to high-speed wireless communication and computing power needed to drive artificial intelligence, augmented and virtual reality, gaming and so much more, our technology is all around us.

We design, develop, manufacture, and service highly complex, cutting‑edge machines used by our customers to create the essential devices that drive the digital age, connect the world, and improve the human experience. Along with the world’s leading technology companies, many of which are household names, we help solve their most difficult material science challenges, enabling technologies for a more connected, sustainable, and convenient world.

We’re looking for material difference‑makers to join our growing team. Interested? Learn more at

Veeco’s Spector ion‑beam deposition platforms are at the center of a major production ramp driven by AI datacenter architectures that demand higher‑performance thin films co sees significant opportunities for growth in ion beam deposition for front‑end semiconductor applications and EUV mask blanks, and in advanced packaging for AI and high‑performance computing.

As a Mechanical Engineer on the Engineering team in Plainview, NY, you will own the design of mechanical components and subsystems — vacuum vessels, wafer fixtures, motion stages, and ion beam source assemblies — for the capital equipment that Veeco’s leading chipmaker customers depend on. This is a hands‑on, full‑life‑cycle role: you will take a concept from first sketch through analysis, prototyping, manufacturing release, and factory floor troubleshooting.

Your work directly affects system throughput, film quality, and the speed at which Veeco delivers tools into a market that is growing faster than the team can build them.

• Design mechanical components and subassemblies for ion beam deposition, ion beam etch, and vapor deposition systems — from initial concept through detailed 3D CAD models, drawings, and manufacturing release — balancing performance, reliability, cost, and manufacturability in every decision.
• Perform engineering analyses — structural finite element analysis (FEA), thermal modeling, vacuum vessel calculations, fluid dynamics, and motion mechanism sizing — to validate designs before committing to hardware and reduce prototype iteration cycles.
• Build and test prototypes
  , authoring design‑of‑experiments (DOE) plans, executing tests, conducting root‑cause analysis, and translating findings into documented engineering changes (ECOs) that move the design toward production readiness.
• Advance deliverables through Product Life Cycle (PLC) phase gates by collaborating with Program Management to ensure your mechanical work packages hit milestones on schedule and with the quality evidence required at each gate.
• Present design rationale, analysis results, and test data in formal design reviews attended by cross‑functional peers, leadership, and — when applicable — external customers and suppliers.
• Coordinate with procurement and manufacturing to ensure that component sourcing, vendor qualification, and assembly sequences support program timelines — stepping onto the factory floor to troubleshoot build issues in real time when needed.
• Define mechanical design specifications from customer requirements and translate them into clear, measurable criteria that guide your design decisions and acceptance testing.

• Bachelor’s degree in Mechanical Engineering with a minimum of 5 years, or a Master’s degree with a minimum of 3 years, of experience designing capital equipment, vacuum systems, mechanical subassemblies, or precision components.
• Proficiency with a 3D CAD platform (Solid Works, Inventor, Creo, or equivalent) used as a primary design tool.
• Hands‑on experience building, assembling, and troubleshooting prototype mechanical hardware in a lab or factory environment.