TSV reveal is one of the highest-risk sequences in advanced packaging, thinning an already-processed wafer to within micrometres of buried copper vias. Our complete reveal flow uses temporary carrier bonding for mechanical safety, controlled plasma etch for precise Cu tip exposure, SiN/SiO₂ passivation, CMP, and continues directly to RDL, UBM, and C4 bumping, all without inter-vendor wafer transfer.
After TSV fabrication, the copper vias are fully enclosed inside the silicon wafer. TSV reveal is the sequence of steps that thins the wafer from the backside and exposes the Cu tips, creating the backside electrical contacts needed for 3D-IC stacking and flip-chip bumping.
Each step builds on the previous, and each requires thin-wafer-adapted process conditions that differ from standard wafer processing.
The device wafer, active surface facing down, is bonded to a rigid glass or silicon carrier wafer using a releasable temporary adhesive film or spin-coated adhesive layer. The carrier provides the mechanical support that makes all subsequent thinning and processing steps safe. Adhesive material is selected based on the maximum temperature the subsequent PECVD deposition will reach, the debond method (thermal, UV, or mechanical), and the solvent compatibility with the device wafer's surface materials. Bond quality is inspected by acoustic microscopy or optical imaging before the stack enters the grinder. The carrier remains bonded throughout grinding, reveal etch, passivation deposition, and CMP, it is only released after the backside is fully processed.
The bonded stack is loaded into the backside grinder, the carrier wafer provides rigid support during aggressive grinding. A coarse diamond wheel removes the bulk of the silicon, approaching the TSV tips from the backside. The grinding stops several micrometres above the Cu tip depth, leaving a thin silicon skin that protects the vias during the grinding step (Cu is softer than Si and would smear under grinding conditions). Target wafer thickness is typically in the range of 50–100µm depending on TSV depth and via pitch, controlled to ±2µm within-wafer uniformity. After coarse grinding, a fine-polish or stress-relief CMP step removes the sub-surface damage layer created by the grinding wheel, this is critical because the damage layer would create fracture initiation points if left in the thinned wafer.
A controlled SF₆-based plasma etch selectively removes the remaining thin silicon skin above the Cu TSV tips. This is the most critical and precision-demanding step in the entire reveal flow. The etch must: (a) selectively remove Si without attacking Cu, (b) stop uniformly across all vias on the wafer within 1–2µm of the Cu surface, and (c) not create Cu protrusion non-uniformity that would prevent subsequent passivation step coverage. Optical Emission Spectroscopy (OES) monitors characteristic emission lines during the etch, the signal change when Cu is reached serves as the endpoint signal to terminate the etch. The Cu protrusion height after reveal is measured by profilometry across the wafer before proceeding to passivation deposition.
After Cu tip exposure, the entire backside, exposed Si, via sidewalls, and protruding Cu tips, must be electrically insulated and protected. PECVD SiN (silicon nitride) and/or SiO₂ layers are deposited conformally at low temperature (<300°C, compatible with the temporary adhesive) over the entire backside surface. The passivation serves three functions: electrical isolation between adjacent vias and the Si substrate; mechanical protection of the delicate revealed structure; and copper oxidation prevention. The deposition must achieve conformal coverage around the Cu protrusions without creating voids or shadow regions that would leave exposed Si between the Cu tip and the passivation layer.
The PECVD passivation covers everything, including the tops of the Cu vias. CMP removes the passivation selectively from the Cu via tops using eddy current endpoint detection: the sensor detects the Cu within the vias and signals stop when the Cu tops are clean. The surrounding passivation remains intact, providing the dielectric surface for RDL deposition. Post-CMP, the wafer surface presents clean Cu contact pads flush with the surrounding SiN/SiO₂ dielectric, the contacts for subsequent RDL metallisation. Surface roughness, Cu recess depth, and passivation thickness are measured and reported. The carrier wafer remains bonded throughout this step.
With clean Cu TSV contacts on the backside, the wafer proceeds to redistribution layer (RDL) fabrication, without any wafer transfer to another facility. RDL lithography and Cu electroplating or polymer passivation routes the TSV contacts from via pitch to bump pitch. Under Bump Metallisation (UBM), ENIG (electroless Ni immersion Au) or ENEPIG (electroless Ni electroless Pd immersion Au), is then deposited on the RDL pads to provide solder wetting, adhesion, and diffusion barrier in the final bump interface. C4 (Controlled Collapse Chip Connection) SnAg solder balls are then formed by electroplating through a photoresist mask, self-aligning during reflow. The carrier wafer is debonded only after the last of these steps, when the wafer has regained mechanical rigidity from the RDL metal layers.
At 50µm thickness, a silicon wafer has the mechanical rigidity of a sheet of paper. It shatters at the slightest uneven pressure. Every subsequent process step, PECVD deposition, CMP, lithography, must be adapted for thin-wafer conditions with a carrier substrate providing rigid support throughout. One missed step without carrier support and the wafer is lost.
After backgrinding, a thin silicon skin remains over the Cu via tips. The plasma reveal etch must remove exactly this skin, stopping within 1–2µm of the Cu surface. Too little etch leaves vias buried; too much damages the Cu and creates protrusion non-uniformity that prevents reliable bonding. Optical emission endpoint detection monitors the etch in real time and stops at the Cu interface.
After reveal and CMP, the wafer has clean Cu contacts on its backside, but this is not yet a finished product. RDL fabrication reroutes the via contacts to the required bump pitch; UBM provides the solder-wettable surface; C4 bumping forms the final flip-chip interconnects. All three steps continue in the same coordinated project without wafer transfer.
Share your process requirements, substrate, and production volume, A Nanosystems JP Inc. engineer will respond within 1 business day. Full quote typically within 7–10 business days, subject to project complexity and NDA requirements.