Transcript
LED Packaging 2011 A comprehensive survey of the main LED packaging technologies and market metrics.
OSRAM
OSRAM
45 rue Sainte Geneviève, F-69006 Lyon, France Tel: +33 472 83 01 80 - Fax: +33 472 83 01 83 Web: http://www.yole.fr
Scope of the Report (2): Process Steps This report covers the Back-en level 0 and level 1 of the High Brightness LED manufacturing process Front end Level 0: Epitaxy
Substrate
• Nucleation layer • n type layer • Active layers (MQW) • p-type layer
SiC Sapphire Silicon Bulk GaN Composite substrates
LED epi-wafer
Back-End (Packaging) level 0:
Front-End Level 1: Device Making • Inspection • Masking / Lithography • Etching • Metallization/contacts/mirrors
• Laser Lift-Off (LLO) – Substrate separation - Bonding • Die singulation • Testing and Binning. LED dies-on-wafer
LED dies
Mesa LED structure Flip Chip LED structure Vertical LED structure
Back-End (Packaging) level 1: • Die Attach and interconnect • Phosphor • Encapsulation and optics • Testing and binning Packaged LED
GaN Capacity vs. Demand:
Capacity increase needed: 5.4m TIE/month
Yole Développement © - Updated May 2011
• MOCVD reactors shipment volume is a good metric to gage the overall equipment market. • After the tight supply situation experienced in early 2010 for packaged LEDs, the current equipment investment cycle driven by massive investments in China will l ead to an overcapacity buildup that could take 12-24 months to absorb. • However, our accelerated scenario calls for a minimum 5.4 million of Two Inch Equivalent (TIE) per month reactor additional capacity necessary for the 2012-2015 period. Considering a typical average industry utilization rate of 85%, this number could realistically be up to 7.2m TIE.
Typical Process Flow: Carrier wafer
Carrier wafer Epitaxial substrate
Epiwafer
Die
Lens
Osram Oslon
•
Exact process is product dependant and varies from one manufacturer to another. For example substrate removal and wafer bonding are only used for the manufacturing of vertical LED structures, But some manufacturers of vertical LEDs use technologies that don’t require wafer bonding. Numbers and positions of testing and i nspection steps can also vary.
GaN LED Chip Design Overview: Trends: Structure
Trends
Comment - Standard mesa structures remain the most cost effective solution for applications and design requiring low current densities ( low heat generation)
- Flip chip designs have been widely adopted by Philips Lumileds for all their GaN high power packages that are being increasingly used for general lighting and automotive applications. Other manufacturers are using Flip chip designs on a case per case basis. - Vertical LED structures are being increasingly adopted for a wide gamut of high power applications. Pioneered by Osram and Semileds, the design has now been adopted in many products by Cree, Lumileds, LG and others.
- The only commercial products based on an electrically conductive substrates are CREE chips that are grown on SiC. However, CREE is increasingly adopting vertical LED design where the SiC epitaxial substrate is removed and replaced by a carrier substrate or submount (Silicon)
High Power LED Packaging Overview Substrate
Phosphor
Thermal Management
(White LED only)
Eutectic Bonding
Substrate Only:
Dispersion
Stud bump (Flip chip)
Ceramic, Metal, Silicon
Die Attach
Interconnect
Encapsulation
Encapsulation + 1 or 2 lenses – Silicon or Epoxy
Conformal coating
Epoxy / Conductive Epoxy
Substrate
Ball/Wedge wire bond
(Ceramic, Metal, Silicon)
Ceramic
+ Si Submount
Ribbon Bonding
Remote Phosphor
Via through Die and/or Submount / Ceramic
Wafer Level Packaging High-Power LEDs include one or multiple chips. A very large gamut of packaging technologies is being used for High Power LEDs in order to handle the higher power density and manage the large amount of heat generated by the dice. There are no standard. Each design is unique in its form factor, die and packaging technology, choice of substrate materials, and the way those technology bricks are combined.
Singulation Equipment Market: Volumes
Substrates for mid-power LEDs Trends •
Technologies are well established and relatively standardized for low and mid power LEDs. However, large LCD backlight are driving some changes in the mid power category: Adoption of “Multichip” packages with 2 chips. • Increase of the average power and light output, taking the chips used for this application closer • to high power chips in term of thermal management solutions:
Illustration of 2 die mid power chips (source: Samsung LED)
Example of evolution of lead frame structure for mid power chips used in TV backlight applications (source: Samsung LED)
Picture of 2 die mid power chips (source: Assymtek)
High Power LED Substrate Market Penetration Forecast by substrate type
Yole Développement ©
Note: technology adoption rates for High Power (>1W) LED package only
Interconnections: Flip Chip Layout Principles and Technologies illustration: Lumileds Luxeon Rebel (1)
Contact to upper (p-GaN) level
Contact to lower (n-GaN) level
(a)
(b)
Pictures and drawings are by courtesy of System Plus Consulting (a) x-ray picture of substrate metal layers through LED die and bumps (b) Drawing of LED front (bottom) side layout (c) Drawing of LED cross-section with contacts (d) Picture of LED die front side
Bump
(c)
Silicon Substrate and WLP for high power LEDs Main actors by wafer sizes (R&D or production) • •
Only a handful of players are currently working on silicon substrates, either on 6 or on 8 inch wafers. We expect silicon substrates to gain momentum as more operations are done at the wafer level, and on larger wafers. Thisway, silicon substrates will enable low cost assembly of high power LEDs. 6 inch wafers
Unknown wafer size
8 inch wafers
?
Silicon Substrates
Other WLP operations
neopac
12 inch wafers
Silicon Substrates and WLP Example: VisEra technology (TW) •
TSMC and subsidiaries VisEra technologies and Xintec technologies announced a High-Power LED packaging technology based on XX inch wafers
•
Technology blends MEMS process and proprietary TSV techniques with wafer-level phosphor conformal coating and lens molding.
•
Main Features: – Mass production (low cost) Current capacity > XX M units/month – Low thermal resistance (as low as 2°C/W) – CTE compatible
•
Currently available as a foundry service, TSMC might leverage on the platform to speed up its entrance into the LED industry.
Courtesy of VisEra
Silicon in high power LED Packages various uses Component level
Package level
ESD/TVS Protection diode
LED
As epitaxy base substrate (emerging in R&D)
Protection diode
LED
As replacing substrate of sapphire for vertical diodes
lens
Discrete component (most frequent case)
Protection diode
LED
Silicon package substrate (Visera, LG Innotek, tMt)
Silicon Silicon submount (Cree, submount Lumileds)
lens Protection diode, submount
LED lens
Protection diode
LED
substrate substrate
substrate substrate
In red: silicon parts
lens