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plasma dicing introduction
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Plasma Dicing for Higher Yield and Throughput – More Die for Your $
Ian Wright, Regional Marketing Director-Asia SPTS Technologies
Agenda
•Si DRIE Capability –Bosch Process
•DRIE Benefits Summary
•Integration –Patterning
–Metals
–Process control & notching
•Die Strength
•Summary
Si DRIE for Plasma Dicing •The “Bosch” Process
–Repeating loops
•Polymer dep
•Polymer removal
•Isotropic Si etch
•Fundamental to the Si etch approach are; –Providing a compatible etch structure
–Definition of the Si to be etched
–Majority of challenges relate to test structures
“Scallops” – generated by
isotropic Si etch
Dicing Schemes
‘Standard’ equipment
Partial F/S DRIE
Invert wafer & frame mount
Singulate during B/S grinding
‘Standard’ equipment
Temporarily bond to wafer sized carrier
Singulate during DRIE
Remount die onto tape/frame for pick & place
Frame based equipment
Singulate during DRIE
Drop-in replacement for conventional dicing
DBG – Dice Before Grind
DAG – Dice After Grind (On Carrier)
DAG – Dice After Grind (On Frame)
Mosaic fxP – for DAG
•Mosaic platform –EFEM compatible with tape frames
–Frame and/or wafer alignment
–Simultaneous wafer/frame running
•Rapier-200S –Sized for 200mm wafer tape frames
–Modified handling & ESC
–Same processes as standard Rapier
•Rapier-300S –Sized for 300mm wafer tape frames
–Modified handling & ESC
–Same processes as standard Rapier
–Available Q4,15
Benefits of DRIE for Dicing
•Throughput –Parallel process
–Largely independent of die size
–Cluster approach for higher output/floor area
•Damage –Bosch etch creates clean scallops
–No vibrations, debris, water
–Increased die strength
–Yield improvement
•Die Density –Narrower dicing lanes
–Die shape/location can be varied
SPTS Mosaic Plasma Dicing Examples Die Sizes from <1mm2 to >10mm2
20µm x 100µm >7wph
30µm x 300µm >3wph
10µm x 100µm >7wph
7µm x 120µm >7wph
50µm x 190µm >5.5wph
All throughputs include; process & handling overheads; process times + overetch; wafer-less inter-wafer chamber plasma cleans
Options for Integration Presenting defined & compatible lanes
Layout
Relevant for “blank sheet” designs All options become available;
• Lane width reduction • Die shape & tessellation • Removal of seal rings, etc • Moving of test structures (TEG)
• Especially metals • On-die or in “die” locations • Ensure space around TEG
Process Flow
Adapt main device process flow Remove non-Si features
Additional etch steps after test
structures are used
Options for Integration Processes to define lanes
Lane Definition – Litho/Self-masking
Assumes non-Si is cleared
Litho for additional mask layer •Standard films can be used
PR, PI, Oxide, etc Extending existing layers as
sacrificial mask layers •Cleared during main steps
Applicable for smaller die
Lane Definition – Combine LASER/Blade & Plasma
Use LASER/blade to eliminate non-Si materials and open lane to Si. Complete singulation with DRIE.
Most relevant for larger die.
Combining Plasma & LASER/Blade
•Quality of lane definition not assured –Edges not as “sharp” as litho
–Up to DRIE to manage this case
•Potential that non-Si materials are not completely removed –OK, if they do not bridge lane
–Simply etch around them
*These images contain confidential information belonging to UTAC and is subject to non-disclosure obligations. No distribution or reproduction is permitted.
*(Sample courtesy of UTAC) *(Sample courtesy of UTAC)
Metals
•Backside metal (BSM), Bondpads and solder bumps –All are compatible with DRIE PM
–No apparent risk to chamber condition
•BSM separated prior to pick-and-place –Various options available for this
–Potential use of LASER/blade to open BSM to tape
•No observable damage to bumps/pads post-etch
After customer’s proprietary metal separation
Importance of Process Control EPD & Notch Prevention
•Dicing to tape is parallel to SOI –Risk of notching at interface
–Due to build up of standing charge
•Notching can be problem for die quality –In particular die strength
•Notching can be prevented –Use of pulsed bias RF allows standing charge to dissipate
–SPTS has IP for use of pulsed bias to prevent notching
Die Strength & Notching
•SPTS & DISCO compared die strength behaviour –Comparing the patterning methods; Photo, Blade & LASER
–Notching; With & without EPD/Overetch control
EPD & Bias Pulsing No Notch
No EPD/No Bias Pulsing Large Notch
•Plasma dicing gives approx 2x gain in die strength –Patterning method has minor influence
–Large notch gave worst die strength of all, even c/w blade
–Shows importance of notch control for successful plasma dicing
Die Strength & Notching
•Plasma dicing gives approx 2x gain in die strength –Patterning method has minor influence
–Large notch gave worst die strength of all, even c/w blade
–Shows importance of notch control for successful plasma dicing
Die Strength & Notching
Summary
•Plasma dicing is rapidly becoming an accepted technique –Still early days in the adoption cycle
•Process & Hardware are set & available
•Key issue is integration of plasma etch into this stage –Patterning
–Metals & Dielectrics in the dicing lane
•Variety of options to be considered –Layout & process flow changes
–Additional or Self masking
–Use of LASER/Blade as patterning medium
•Process control through EPD & Notch prevention –Critical for die strength
Thanks to… SPTS Samples & Applications Groups DISCO
©2015 SPTS Technologies - Confidential & Proprietary
www.spts.com
Thank You