MEMS Process Resource

Spin Coat vs. Spray Coat Photoresist for MEMS

Two ways to apply photoresist, one built for flat wafers and one built for topography. This guide explains how each method works, compares their characteristics, and gives practical guidance for choosing the right coating method for your device.

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Photoresist spin coater and spray coater for MEMS wafer processing

Spin coating and spray coating are the two primary methods used to apply photoresist during MEMS fabrication, sensor manufacturing, and semiconductor wafer processing. In MEMS, photoresist often must cover deep cavities, trenches, and other three dimensional features rather than only flat wafers, which makes the coating method a real process decision. Both lay down a resist film for lithography, but they apply it in fundamentally different ways. Spin coating spreads liquid resist across a spinning wafer by centrifugal force, while spray coating atomizes the resist into fine droplets and sprays it onto the surface. That difference determines how well the resist covers topography, how uniform the film is, how efficiently resist is used, which wafers can be coated, and where each method belongs within a MEMS fabrication flow.

Choosing the right coating method is a practical lithography decision that affects feature quality, yield, and the ability to pattern three-dimensional structures. This guide explains how each method works, compares their characteristics, and provides practical guidance for selecting the appropriate coating method for MEMS and related microfabrication applications.

Two Ways to Apply Photoresist

Both methods produce a photoresist (also called resist) layer ready for exposure, so the distinction is how the resist reaches the wafer and how it behaves over surface features. Spin coating relies on rotation to fling resist outward into a thin, highly uniform film, which works beautifully on a flat wafer but struggles where the surface rises and falls. Spray coating builds the film from a mist of droplets that settle onto every surface, including the walls and floors of deep features. Nearly every practical difference that follows, from uniformity to topography coverage, traces back to that distinction.

How Spin Coating Works

Spin coating begins by holding the wafer on a vacuum chuck and dispensing liquid photoresist onto its center. The wafer is then spun at high speed, and centrifugal force spreads the resist outward into a thin, even film while the solvent begins to evaporate. A soft bake afterward drives off the remaining solvent and stabilizes the film. The final thickness is set primarily by the spin speed and the resist viscosity, which makes spin coating highly repeatable on planar wafers.

Spin coatingResist is dispensed at the center of a wafer held on a vacuum chuck, and high speed rotation spreads it into a thin, uniform film while excess resist spins off.Spin coatingResist dispensedat the centerThin, uniform filmspreads outwardExcess resist spun offVacuum chuckHigh speed rotationSilicon wafer
Centrifugal spreading. Rotation flings the dispensed resist outward into a thin, highly uniform film on a planar wafer, while most of the resist spins off the edge.

Spin coating delivers excellent thickness uniformity, a smooth surface, and the highest resolution, which is why it is the standard method for planar lithography. Its limitations appear when the wafer is not flat. Over deep trenches, cavities, or other high topography, the resist thins on raised areas and pools in recesses, and it cannot coat steep sidewalls conformally. Spin coating also produces an edge bead and wastes a large fraction of the dispensed resist, most of which is spun off the wafer.

How Spray Coating Works

Spray coating applies photoresist as a fine mist. A spray nozzle atomizes the resist into small droplets that are deposited across the wafer in one or more passes, building up the film thickness gradually. Because the droplets settle onto every exposed surface, spray coating produces a conformal layer that follows topography, coating the sidewalls and floors of features that spin coating cannot reach.

Spray coatingA scanning nozzle atomizes resist into fine droplets that settle onto every surface, building a conformal layer over topography.Spray coatingNozzle scans the waferAtomized resistdropletsConformal resist overwalls and floorsSiliconWafer with topography
A film built from mist. Droplets settle onto every exposed surface, so the resist follows the topography into and out of deep features.

This conformal behavior makes spray coating the better choice for high aspect ratio features, allowing several microns of photoresist over three-dimensional structures such as V-grooves, deep trenches, silicon cavities, and through silicon vias (TSVs). Spray coating also uses resist efficiently, with little waste, and can coat fragile or perforated wafers that would not survive high speed spinning. The tradeoff is that thickness uniformity on a flat surface is not as high as spin coating, and the surface is slightly rougher.

How the Two Methods Differ

Application mechanism. Spin coating spreads resist by centrifugal force on a spinning wafer. Spray coating atomizes resist into droplets and sprays it onto the surface.
Topography coverage. Spin coating cannot coat high topography conformally. Spray coating covers steep sidewalls, deep trenches, cavities, and through silicon vias.
Thickness uniformity. Spin coating gives excellent uniformity on planar wafers. Spray coating gives good coverage everywhere but is less uniform than spin coating on a flat surface.
Material efficiency. Spin coating wastes most of the dispensed resist, which is spun off the wafer. Spray coating uses resist efficiently with little waste.
Wafer compatibility. Spin coating suits robust, planar wafers. Spray coating also handles fragile, perforated, and cavity wafers.
Resolution and surface. Spin coating produces the smoothest surface and the highest resolution. Spray coating offers good resolution with a slightly rougher surface.
Process stage. Spin coating fits planar steps and blanket coating. Spray coating fits steps that come after topography has been created, such as patterning over etched features.

Coverage Over Topography

Topography is the decisive factor between the two methods. On a flat wafer, spin coating is hard to beat for uniformity and resolution. Once the wafer has deep trenches, silicon cavities, V-grooves, or through silicon vias, spin coating leaves resist too thin on raised edges and too thick in recesses, and it cannot protect steep sidewalls. Spray coating solves this by depositing a conformal layer that follows the surface into and out of features, which is why it is the preferred method for patterning three-dimensional MEMS structures and for coating wafers after deep silicon etching.

Spin coated resist over a trenchSpin coated resist thins at the trench edges, pools at the bottom, and leaves the sidewalls bare.Spin coatThins at edges, pools in recessesThins at the edgePools belowBare sidewallSilicon
Non-conformal. Over topography the spun film thins at raised edges, pools in the recess, and leaves steep sidewalls unprotected.
Spray coated resist over a trenchSpray coated resist follows the surface conformally, coating the trench walls and floor with an even layer.Spray coatConformal over the same trenchSidewall coatedEven layer onwalls and floorSilicon
Conformal. The sprayed film follows the surface into and out of the trench, keeping an even thickness on walls and floor.

Thickness, Uniformity, and Resolution

Spin coating offers the finest control of a thin, uniform film and the highest resolution, set by spin speed and resist viscosity. Spray coating controls thickness through the number of passes and can build several microns of resist over topography, trading some flatness and resolution for coverage. For the finest planar features, spin coating remains the better choice; for reliable coverage over rugged topography, spray coating is the better choice.

Material Efficiency and Wafer Compatibility

Spin coating dispenses far more resist than ends up on the wafer, since most is spun off, and it requires a wafer robust enough to withstand high speed rotation. Spray coating uses resist efficiently and applies gentle forces, so it can coat fragile, thin, perforated, or already micromachined wafers that would be difficult or risky to spin. These advantages matter most in MEMS flows where wafers carry deep features or released structures.

Process Integration

Many production flows use both methods at different steps. Spin coating handles planar lithography and blanket surface protection early in the flow, while spray coating takes over once deep features have been etched and conformal resist coverage is required. Selecting the right method for each step lets engineers match the coating approach to the wafer surface, the feature depth, and the resolution needed, rather than forcing a single method across the whole process.

Spin Coat vs. Spray Coat at a Glance

PropertySpin CoatSpray Coat
Application methodResist spread by centrifugal force on a spinning waferResist atomized into fine droplets and sprayed onto the wafer
Topography coveragePoor over high topographyConformal over high aspect ratio features
Thickness uniformityExcellent on planar wafersGood; less uniform than spin on flat surfaces
Thickness controlSpin speed and photoresist viscosityNumber of spray passes
Surface finishVery smoothSlightly rougher
ResolutionHighestGood
Material efficiencyLow; much resist is spun offHigh; little resist wasted
Edge beadPresentMinimal
Wafer compatibilityRobust planar wafersAlso fragile, perforated, and cavity wafers
Coats 3D featuresNoYes; sidewalls, trenches, cavities, TSVs
Best stagePlanar steps and blanket coatingAfter etch or over existing topography
Typical applicationsStandard front side lithography, blanket protectionDeep trenches, silicon cavities, V-grooves, TSVs

Rogue Valley Microdevices Resist Coating Options

  • Spin coat: thin, uniform photoresist in positive, negative, lift-off, and polyimide chemistries, ideal when a few microns of resist or blanket surface protection is needed.
  • Spray coat: conformal photoresist over high aspect ratio features, coating several microns over three-dimensional structures such as V-grooves, deep trenches, silicon cavities, and through silicon vias (TSVs).
  • Both methods are available on 100mm, 150mm, and 200mm substrates.
  • Either method can be run as part of process development or applied as a blanket film with a soft bake.
  • Resist coating is supported by in-house photolithography, including front to back alignment for double sided and topographic devices.

Typical Applications

Spin Coat

  • Standard front side lithography on planar wafers
  • Thin, uniform resist layers of a few microns
  • Blanket surface protection
  • Fine, high-resolution features
  • Positive, negative, lift-off, and polyimide resists

Spray Coat

  • Coating over deep trenches and silicon cavities
  • Through silicon vias (TSVs)
  • V-grooves and three-dimensional MEMS structures
  • High aspect ratio features after DRIE
  • Fragile, perforated, or cavity wafers
  • Conformal resist for topographic patterning

Application Examples

ApplicationTypical Coating Strategy
Planar front side lithographySpin coat for a thin, uniform, high resolution layer.
Blanket surface protectionSpin coat with a soft bake.
Patterning over deep DRIE trenchesSpray coat for conformal coverage of sidewalls and floors.
Through silicon vias and cavitiesSpray coat to reach into 3D features.
Fragile or perforated wafersSpray coat to avoid the stresses of spinning.

Choosing the Right Method

Choose spin coat when the wafer surface is essentially planar, when the highest uniformity and resolution are required, or when only a few microns of resist or blanket protection is needed. Choose spray coat when the wafer has deep trenches, silicon cavities, V-grooves, through silicon vias, or other high aspect ratio features that require conformal coverage, or when the wafer is fragile, perforated, or already micromachined.

A Simple Selection Workflow

  1. Is the wafer surface essentially planar? Spin coat gives the most uniform, highest resolution layer.
  2. Does the wafer have deep trenches, cavities, TSVs, or other high aspect ratio features? Choose spray coat for conformal coverage.
  3. Do you only need a few microns of resist or blanket protection? Spin coat is the simplest route.
  4. Is the wafer fragile, perforated, or already etched into three dimensional structures? Choose spray coat.
  5. Remember that many flows use spin coat for planar steps and spray coat after topography is created.

Frequently Asked Questions

What is the difference between spin coat and spray coat?

Spin coating spreads photoresist across a spinning wafer by centrifugal force, giving an excellent uniform film on planar wafers. Spray coating atomizes the resist into droplets and sprays it on, giving conformal coverage over topography.

When should I use spray coat instead of spin coat?

Use spray coat when the wafer has high aspect ratio features such as deep trenches, silicon cavities, V-grooves, or through silicon vias that spin coating cannot cover conformally, or when the wafer is fragile or perforated.

Which method gives better thickness uniformity?

Spin coating, on planar wafers. Spray coating trades some uniformity for the ability to coat three-dimensional features.

Which method uses resist more efficiently?

Spray coating, because little resist is wasted. In spin coating, most of the dispensed resist is spun off the wafer.

Can both methods be used in the same flow?

Yes. Many flows use spin coat for planar lithography and spray coat once deep features have been etched.

Talk to a MEMS Foundry

Have a device in development or a process you want to outsource? Rogue Valley Microdevices is a pure play MEMS foundry offering wafer services, thin films, photolithography, metal deposition, and silicon etching on 100mm, 150mm, and 200mm substrates. Contact us to discuss your project and find the right process for your device.