High-brightness LEDs of big chip size on multi-layer interconnects with optimized thermal dissipation and optical performance

2014 ◽  
Vol 2014 (1) ◽  
pp. 000877-000881
Author(s):  
Liang Wang ◽  
Gabe Guevara ◽  
Grant Villavicencio ◽  
Roseann Alatorre ◽  
Hala Shaba ◽  
...  
Keyword(s):  
Flip Chip ◽  
Wavelength Conversion ◽  
Light Output ◽  
Light Extraction ◽  
Thermal Dissipation ◽  
High Yield ◽  
Wafer Level ◽  
High Brightness ◽  
Aperture Ratio ◽  
Chip Size

The market share of high-brightness LEDs in general lighting has been rapidly expanding mainly owing to the continued technological advances on internal quantum efficiency, light extraction and wavelength conversion. In spite of these promising advances, there remain some key breakthroughs to be made before LED lighting technology can be fully adopted into the broad market, with emphasis on efficient thermal dissipation, higher efficacy at high brightness, and low manufacturing cost. Higher brightness requires LEDs to be operated at higher current density which results in efficacy degradation due to droop behavior and thus higher power loss into heat and shorter lifetime. Therefore a highly efficient mechanism of thermal dissipation is needed for timely conduction of heat away from the high-power LED chip. For general lighting at high brightness, a large chip size is preferable. More importantly, with larger chip size, higher brightness can be achieved at much lower current density which leads to less degradation of efficacy. However simply increasing the die size of LEDs in wafer fabrication causes significant yield loss and thus hinders the adoption of big-chip LEDs. In this paper we propose a scalable approach to enable larger chip sizes for manufacturing high efficacy & high brightness LEDs at high yield and low cost. The metric of lower cost per lumen is necessary for LEDs to be competitive to traditional light sources like fluorescent lights in the consumer market segment. About 50% of the total LED production cost is consumed by the packaging processes after the emissive device stack being fabricated. Also given the minimal thickness of the device stack, the key bottleneck for thermal dissipation resides in the packaging structure and its interface to the device stack. We address these two key challenges with a novel wafer-level packaging structure of metal contacts forming a perimeter that is integrated into the device stack, which optimizes the thermal dissipation rate from the active device stack to substrate while allowing high aperture ratio and improved light output. Our approach applies a wafer-level batch process starting from LED fabrication to packaging for internal and external light extraction as well as wavelength conversion, in order to achieve high throughput and high yield in a scalable and inexpensive manner. To improve the overall power efficiency, different materials have been selected for ohmic contacts and high reflectivity at p and n electrodes, and further developments continue to be implemented, including a current-spreading layer, large-area light extraction structure and integrated phosphor material. Flip chip packaging is chosen due to its advantage of full front-side emission, maximized aperture ratio, compact form factor, higher integration density and ease of wafer level processing. The substrates for flip chip packaging of LED chips are made of Si which was selected due to its relatively high thermal conductivity (149 W/m/K) and ease of fabrication with standard semiconductor processes. Multi-layer interconnects are patterned over the Si substrate with solder bumps built over the passivation openings for flip-chip assembly of multiple LED dies. The multi-layer dielectric stack of the substrate is designed to form dielectric mirror maximizing the reflection of emitted light back into the LED side for improved light output.

Wafer level packaging for high-brightness LED lighting with optimized thermal dissipation and optical performance

2014 ◽  
Vol 2014 (DPC) ◽  
pp. 001787-001817
Author(s):  
Liang Wang ◽  
Gabe Guevara ◽  
Rey Co ◽  
Ron Zhang ◽  
Roseann Alatorre
Keyword(s):  
Power Efficiency ◽  
Wavelength Conversion ◽  
Bonding Process ◽  
Light Extraction ◽  
Thermal Dissipation ◽  
Wafer Level ◽  
High Brightness ◽  
Led Lighting ◽  
Wafer Level Packaging ◽  
Packaging Structure

High-brightness LED lighting has gained high attention in the industry and its market share for general lighting has been rapidly expanding upon the continued progress on improving internal quantum efficiency, light extraction and wavelength conversion. In spite of these promising advances, some key breakthroughs must be made before this technology can be fully adopted into the broad market, such as efficient thermal dissipation and low manufacturing cost. A lion share of cost of an LED module is incurred during the packaging processes after the emissive device stack has been fabricated. Also given the thin thickness of device stack, the packaging structure remains the bottleneck for thermal dissipation. We address these two key challenges with a novel wafer-level packaging structure integrated into the device stack, which enables maximal thermal dissipation rate from active device stack to substrate while allowing high aperture ratio and optimized light output. Our approach applies full wafer-level batch process from epitaxial growth all the way down to packaging for internal and external light extraction as well as wavelength conversion, in order to achieve high throughput and high yield in a scalable and inexpensive manner. Initial prototypes of GaN based blue LED with big chip size have been fabricated without selective electrodes for minimal contact resistance, exhibiting high brightness at relatively low drive voltage (3.5V). As one key step in wafer level packaging, the wafer bonding process was characterized with Moire patterning and Topography and Deformation Measurement to understand the warpage profile and varying temperatures along both heat up and cool down paths, with simulation performed in guidance to final solution for compensating the warpage profile along the bonding process and afterwards. Different approaches were applied in learning the most effective bonding technique for this packaging structure. Further development is ongoing to improve the overall power efficiency and color quality, including optimal materials for ohmic contacts at both electrodes, current-spreading layer, large-area light extraction structure, and integrated phosphor material. This wafer-level packaging technology is scalable to large wafer size for high-throughput and low-cost manufacturing, to achieve both superior thermal management and optimized power efficiency.

Solutions for Wafer-Level Packaging of High Brightness LEDs

2011 ◽  
Vol 2011 (DPC) ◽  
pp. 001418-001442
Author(s):  
Thomas Uhrmann ◽  
B. Kim ◽  
T. Matthias ◽  
P. Lindner
Keyword(s):  
Form Factor ◽  
Light Output ◽  
High Volume ◽  
Performance Ratio ◽  
High Yield ◽  
Light Sources ◽  
Wafer Level ◽  
Process Step ◽  
High Brightness ◽  
The Cost

High brightness LEDs (HB-LEDs) carry a high prospect for general lighting applications. Competing with the cost/performance ratio of current light sources demands an increase of the overall efficiency as well as the reduction of the device cost. Since packaging accounts for 30%–50% of the cost of HB LED manufacturing, moving from die- level to wafer-level processes is one likely potential solution for reducing cost per lumen. Silicon-based WLP, using the established processing technology of the MEMS and IC industry, offers high fabrication reliability, high yield and the direct integration of the driver IC in the package. The already small form factor of WLP can be further reduced using Through-Silicon-Vias (TSV), increasing the maximum amount of chips per wafer. Silicon WLP also offers superior thermal management, with the relatively high thermal conductance of silicon. Redistributing LED dies on silicon wafer submounts, with metal bonding and copper TSVs, further improves the heat conductance away from the active region of the chip, resulting in increased device performance. Wafer-level optics can further improve performance and reduce packaging costs. Wafer-level lens molding based on imprint lithography is in high volume manufacture for cell phone camera modules. It allows creation of spherical and a-spherical lenses as well as lens stacks with minimized form factor. In contrast to the currently applied drop dispensing technique for LED lens fabrication, the shape of the lens can be accurately tailored and the decrease of the lens size results in lower absorption and higher light output. Most of these technologies are already in high volume production in other sectors. We will discuss the field proven solutions at each process step, from the formation of the silicon interposer, through the chip-to-wafer bonding, to the final imprinting of the wafer-level optics.

DEVELOPMENT OF AN ULTRA THIN DIE-TO-WAFER FLIP CHIP STACKING PROCESS FOR 2.5D INTEGRATION

2013 ◽  
Vol 2013 (1) ◽  
pp. 000516-000522 ◽  
Author(s):  
G. Parès ◽  
A. Attard ◽  
F. Dosseul ◽  
A. N'Hari ◽  
O. Boillon ◽  
...  
Keyword(s):  
Flip Chip ◽  
Transient Liquid Phase ◽  
High Yield ◽  
Integration Scheme ◽  
Wafer Level ◽  
Release Process ◽  
Process Improvements ◽  
Low Profile ◽  
Stress Release Process ◽  
Tin Silver Copper

3D integration relying on novel vertical interconnection technologies opens the gate to powerful microelectronic systems in ultra-thin packages answering the demand of the mobile market. Among these, die-to-wafer stacking is a key enabling technology for 2.5D as well as for 3D with technological challenges driven by, in one hand, the increase of the die surface and the number of I/Os and, on the other hand, the reduction of the vertical dimensions. In our integration scheme we have achieved flip chip stacking (or Face to Face) of 35 μm ultra-thin dies with low stand-off (< 15 μm) copper micro-bumps and tin-silver-copper solders (SAC). Ultra-thin dies are prepared using dicing before grinding (DBG) technique. After DBG, plasma stress release process is applied to the backside of the singulated chips. Copper μbump technology is challenging with this very low profile stacking since the current flip chip process is no longer adapted to this geometry and that the die flatness tolerance become very critical to obtain a high soldering yield. Process improvements have been achieved on the copper pillar fabrication itself with several metallurgy stack configurations as well as new processes using damascene techniques. Furthermore, innovative technologies have been deployed on the pick and place and collective soldering processes. Intermetallic formation during reflow process is achieved through transient liquid phase (TLP) reaction leading to thorough consumption of the tin layer and to the formation of Cu6Sn5 and Cu3Sn compounds. Capillary underfill is finally successfully applied in the narrow die-to-wafer gap by jetting technique. After optimization, electrical tests show a very high yield close to 100% over a representative number of fully populated wafers. Reliability tests have also been carried out at wafer level exhibiting no significant resistance increase or yield loss over 1000 thermal cycles between −40 and +125°C.

scholarly journals Enhanced Light Extraction of Flip-Chip Mini-LEDs with Prism-Structured Sidewall

Nanomaterials ◽  
2019 ◽  
Vol 9 (3) ◽  
pp. 319 ◽  
Author(s):  
Bin Tang ◽  
Jia Miao ◽  
Yingce Liu ◽  
Hui Wan ◽  
Ning Li ◽  
...  
Keyword(s):  
Total Internal Reflection ◽  
Flip Chip ◽  
Extraction Efficiency ◽  
Light Output ◽  
Cost Effective ◽  
Light Extraction ◽  
Light Extraction Efficiency ◽  
Light Output Power ◽  
Light Emitting ◽  
Air Interface

Current solutions for improving the light extraction efficiency of flip-chip light-emitting diodes (LEDs) mainly focus on relieving the total internal reflection at sapphire/air interface, but such methods hardly affect the epilayer mode photons. We demonstrated that the prism-structured sidewall based on tetramethylammonium hydroxide (TMAH) etching is a cost-effective solution for promoting light extraction efficiency of flip-chip mini-LEDs. The anisotropic TMAH etching created hierarchical prism structure on sidewall of mini-LEDs for coupling out photons into air without deteriorating the electrical property. Prism-structured sidewall effectively improved light output power of mini-LEDs by 10.3%, owing to the scattering out of waveguided light trapped in the gallium nitride (GaN) epilayer.

Wafer Level Chip Size Packaging Technology for Bulk Acoustic Wave Filters

2007 ◽  
Vol 990 ◽  
Author(s):  
Hajime Yamada ◽  
Naoko Aizawa ◽  
Hiroyuki Fujino ◽  
Yoshihiro Koshido ◽  
Yukio Yoshino
Keyword(s):  
Acoustic Wave ◽  
Flip Chip ◽  
Bulk Acoustic Wave ◽  
Wafer Level ◽  
Copper Electroplating ◽  
Solder Bumps ◽  
Hermetic Seal ◽  
Via Holes ◽  
Chip Size ◽  
Wave Filters

ABSTRACTWafer level chip size packages (WL-CSP) have been successfully fabricated for bulk acoustic wave (BAW) filters. WL-CSP has been completed at the wafer level prior to dicing. Two silicon wafers are used as a die and a lid for chip size packaging. Both device and lid wafers have the same expansion coefficient and the package is strong enough to withstand the thermal stress. The package has a hermetic seal with copper-tin intermetallic bonding. The bonded wafers are then thinned by grinding. Via holes are formed by reactive ion etching (RIE) and filled by copper electroplating. The package has solder bumps on each terminal, ready for flip-chip assembly. We have succeeded to produce CSP-BAW filters with a hermetically sealed cavity, which is 840 micrometers squared and 280 micrometers in height including solder bumps.

Design and fabrication of MEMS-type compliant overhang flip-chip interconnect for RF applications

2015 ◽  
Vol 2015 (DPC) ◽  
pp. 002082-002094
Author(s):  
Pingye Xu ◽  
Michael C. Hamilton
Keyword(s):  
Solder Ball ◽  
Flip Chip ◽  
Coefficient Of Thermal Expansion ◽  
Organic Substrate ◽  
Process Temperature ◽  
High Yield ◽  
Wafer Level ◽  
Micro Fabrication ◽  
Compliant Interconnect ◽  
Sac Solder

With the increase of I/O density and scaling of interconnects, conventional solder ball interconnects are required to be made smaller. As a result, the reliability of the conventional solder ball flip-chip interconnects worsens. One method to mitigate this issue is by using underfill. However, underfill undermines the reworkability of the solder joints and is challenging to apply when the gap between chip and substrate is small. Another approach to enhance the reliability is to use taller solder ball interconnects, which is however usually more costly. Instead of using conventional solder ball interconnects, compliant interconnects have also been researched in the past few decades to mitigate the reliability issue. The use of compliant structures can compensate for the coefficient of thermal expansion (CTE) mismatch between a Si chip and an organic substrate. In this work, we present the design and fabrication of MEMS-type compliant overhang flip-chip interconnects. The structures are placed at the end of a coplanar waveguide (CPW) as interconnects between CPWs to research their performance at radio frequency (RF). A micro-fabrication process was adopted to build the interconnects. The CPWs are fabricated using conventional e-beam deposition followed by photolithography and then copper electroplating. The compliant overhangs were fabricated on top of a dome of reflowed photoresist on the CPWs to form a curved shape. The reflow and hard bake of the photoresist requires a process temperature of above 220 °C, which is similar to the reflow temperature of a Sn-Ag-Cu (SAC) solder. Therefore we believe our process is compatible with SAC solder processing infrastructures in terms of process temperature. The fabricated structures show high yield and uniformity. Due to the use of a micro-fabrication based process, the structures have the potential to be scaled and be compatible to wafer level packaging. The CPWs were then flip-chip bonded with the compliant interconnect as transitions. The RF performance of the interconnects up to 50 GHz will be presented.

No Flow Underfill Process Development for Fine Pitch Flip Chip Silicon to Silicon Wafer Level Integration

2010 ◽  
Vol 2010 (DPC) ◽  
pp. 000708-000735 ◽  
Author(s):  
Zhaozhi Li ◽  
John L. Evans ◽  
Paul N. Houston ◽  
Brian J. Lewis ◽  
Daniel F. Baldwin ◽  
...  
Keyword(s):  
High Performance ◽  
Flip Chip ◽  
Process Development ◽  
Low Cost ◽  
Three Dimensional ◽  
High Yield ◽  
Process Time ◽  
Assembly Process ◽  
Wafer Level ◽  
Fine Pitch

The industry has witnessed the adoption of flip chip for its low cost, small form factor, high performance and great I/O flexibility. As the Three Dimensional (3D) packaging technology moves to the forefront, the flip chip to wafer integration, which is also a silicon to silicon assembly, is gaining more and more popularity. Most flip chip packages require underfill to overcome the CTE mismatch between the die and substrate. Although the flip chip to wafer assembly is a silicon to silicon integration, the underfill is necessary to overcome the Z-axis thermal expansion as well as the mechanical impact stresses that occur during shipping and handling. No flow underfill is of special interest for the wafer level flip chip assembly as it can dramatically reduce the process time as well as bring down the average package cost since there is a reduction in the number of process steps and the dispenser and cure oven that would be necessary for the standard capillary underfill process. Chip floating and underfill outgassing are the most problematic issues that are associated with no flow underfill applications. The chip floating is normally associated with the size/thickness of the die and volume of the underfill dispensed. The outgassing of the no flow underfill is often induced by the reflow profile used to form the solder joint. In this paper, both issues will be addressed. A very thin, fine pitch flip chip and 2x2 Wafer Level CSP tiles are used to mimic the assembly process at the wafer level. A chip floating model will be developed in this application to understand the chip floating mechanism and define the optimal no flow underfill volume needed for the process. Different reflow profiles will be studied to reduce the underfill voiding as well as improve the processing yield. The no flow assembly process developed in this paper will help the industry understand better the chip floating and voiding issues regarding the no flow underfill applications. A stable, high yield, fine pitch flip chip no flow underfill assembly process that will be developed will be a very promising wafer level assembly technique in terms of reducing the assembly cost and improving the throughput.

Development of Wafer Level Chip Size Packaging Process and its Application to the CMOS Image Sensor Module for Medical Device

2017 ◽  
Vol 137 (2) ◽  
pp. 48-58
Author(s):  
Noriyuki Fujimori ◽  
Takatoshi Igarashi ◽  
Takahiro Shimohata ◽  
Takuro Suyama ◽  
Kazuhiro Yoshida ◽  
...  
Keyword(s):  
Medical Device ◽  
Cmos Image Sensor ◽  
Image Sensor ◽  
Wafer Level ◽  
Packaging Process ◽  
Sensor Module ◽  
Chip Size
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