Scientific Instrumentation

Research-grade
precision.
Nanometer alignments.

UHV-compatible 316L vacuum chambers, 5 µm-tolerance optical mounts, PTFE fluidic manifolds, spectrometer housings. From university research labs to national observatories, our parts ship into the world\'s most demanding measurement systems.

Scientific RFQ Technical consult

01 · Research applications

Where our parts ship.

Vacuum chambers

316L UHV · electropolish

UHV-compatible vacuum chambers to 10^-10 Torr. Polished internal surfaces, conflat flange machining, cryogenic-compatible.

Optical mounts

Al 6061 · ±5 µm

Kinematic optical mounts, beam splitters, mirror holders. Thermal-stable stress-relieved aluminum with precision adjuster interfaces.

Spectrometer housings

Anodized Al · light-tight

Grating monochromator bodies, cuvette holders, sample cell housings. Light-tight anodized interiors, precision entrance slits.

Fluidic manifolds

PTFE · PEEK

HPLC manifolds, microfluidic chip holders, sample handling hardware. Chemically inert PTFE or PEEK bodies.

Microscopy hardware

Stage pieces · ±2 µm

Precision XY stages, objective mounts, condenser brackets. Nanometer-level positioning features.

Fiber-optic fixtures

Steel · ceramic

Single-mode fiber alignment fixtures, ferrule holders, V-groove mounts. Sub-micron positioning for SMF.

Cryogenic hardware

OFC Cu · 316L

Liquid helium and liquid nitrogen dewars, cryostat components, thermal straps. Non-magnetic for sensitive measurements.

Laser mounts

Invar · Al thermal

Laser head mounts with thermal expansion compensation, Invar bases, aluminum adjusters. Pico-radian stability.

MEMS packaging

Ceramic · Kovar

MEMS device packages, hermetic seal flanges, feedthrough housings. Low-leak hermetic assembly.

FAQ

Scientific manufacturing questions.

Depends on the function. Optical mounting and alignment features: ±0.002–0.005 mm (2–5 µm) for single-mode fiber or precision optical systems. Vacuum sealing surfaces: Ra 0.4 µm flatness. Spectrometer slit widths: ±1 µm on slit dimension. Most other instrument housing features: ±0.05 mm is adequate. Critical tolerances tend to be on datum-referenced alignment features.

Yes. UHV-compatible materials: 316L stainless (preferred), OFE copper (C101), 6061 aluminum (specific grade), titanium, Inconel. Machining practices for UHV: avoid lubricants containing sulfur or phosphorus, use water-soluble coolants, avoid tapped blind holes (vent holes required), minimize surface area to reduce outgassing. We can also provide pre-vacuum-baked parts.

Yes, a significant fraction of our scientific work comes from research institutions globally. We understand the different procurement processes, payment terms (often post-delivery), and documentation needs of academic and government customers. NDAs and technology transfer agreements signed as needed.

We machine substrates in aluminum, beryllium, fused silica blanks, and zerodur to ±0.01 mm overall dimensions. The optical polishing and coating is performed by specialty optics partners — we provide the precisely-machined blank ready for diamond turning or polishing. We do not have diamond-turning capability in-house for optical-grade surface accuracy.

Covered by our medical-grade materials (PEEK, 316L, PTFE, titanium) and USP Class VI biocompatible polymers. For cleanroom-handled components, we provide HEPA-filtered cleaning and nylon-wrapped packaging. Fluidic systems with precision flow rates, microfluidic chip manifolds, biosafety cabinet hardware.

Our sweet spot for scientific is 1–50 parts per order. Each piece machined with first-article inspection, dimensional verification, and shipped with traceable documentation. For one-of-a-kind research prototypes, we consult on DFM to ensure the part is buildable and affordable within research budgets.

Research-gradeprecision.Nanometer alignments.