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Ormet Circuits, Inc. Technology Overview Presentation
Ormet Circuits Confidential
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Mission Ormet Circuits provides conductive pastes and inks that enable electrical interconnection and thermal management in electronic substrates, components and assemblies.
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Opportunity Industry currently uses 3 technologies to form electronic interconnections Copper Plating Printed circuit boards Time consuming with poor yield for new designs Solder IC packaging for power devices High temperature processes reduce reliability Environmental concerns Conductive Adhesives Used as an alternate to solder in some applications Limited electrical and thermal properties There are three areas where the market is benefited Ormet’s materials. Is it our objective to work closely with customers to develop applications where these existing technologies have limitations, and a new interconnect material is desired. Copper Plating Copper plating is the standard technology for PCB manufacturing. In today’s designs, customers are looking to save space and increase interconnect density in their PCBs by removing through-holes. Ormet’s technology is used as an alternative to plating in micro-vias and through-holes to provide electrical interconnection and thermal management. Solder Replacement The transition from SnPb solder to Pb-free solder resulted in higher temperatures being used in electronics assembly. Still today, some power electronics applications use Pb-based solders due to problems with Pb-free materials. Ormet circuits is an alternative to solder paste in Pb-free applications where solders have temperature or processing related issues. Ormet has electrical and thermal properties of solder paste materials, but can be processed at lower temperatures than solder. Of course, Ormet’s products are green. Conductive adhesives can sometimes be used as an alternative to solder paste. Unfortunately, adhesives are not as electrically stable over time as solders, and typically contain expensive silver filler. Ormet’s materials are electrically and thermally superior to silver filled paste adhesives with much more stable electrical resistance over time. Overall, Ormet’s properties are like solder paste, with the processing benefits of conductive adhesives.
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Ormet Circuits Technology
Ormet Circuits Confidential Ormet Circuits Technology The illustration depicts a Transient Liquid Phase Sintered Paste which is formulated with an fluxing epoxy resin system, a tin-bismuth alloy and copper particles in the uncured paste. During cure (When heated or reacted above 140C) the tin-bismuth alloy melts. The tin would rather form an intermetallic with the copper than remain with the bismuth. During the cure profile the tin forms an intermetallic network that sinters the copper powder into a solid network and sinters to any adjacent solder ready surface. The colors in the picture are: Black: Polymer network light Gray: bismuth Medium gray: tin-copper intermetallic Dark gray: copper Copper and alloy particles in a liquid organic formulation Sintered metal network Proprietary Organics, Metal Powders and Alloys using Transient Liquid Phase Sintering Process (TLPS)
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DSC Analysis of Ormet 700 Lead Free Composition
Ormet® materials do not remelt - Transient Liquid Phase Sintering (TLPS) DSC Analysis of Ormet 700 Lead Free Composition First thermal cycle Ormet uses Differential Scanning Calorimetry (DSC analysis) in studying the reaction of our materials. During the cure cycle, the first charted DSC scan points out the alloy melt (about 138ºC), followed by the intermetallic formation up to 190C. This indicates that the tin has left the bismuth and is sintering/fusing the copper particles. The epoxy cures simultaneous to the alloy melting, and has been specifically developed to aid the intermetallic formation above the alloy melt temperature. The second scan demonstrates that the material will not re-melt when subjected to a second heat profiles. The first melt observed is that of bismuth at 267C, which is above the peak temperature of Pb-solder reflow profiles (260C) A generic formulation for our products: Uncured state: 6% epoxy, 4% solvent, 90% metal loaded Cured State: 5-6% organic, 94% metal, no residual solvent Second thermal cycle, no re-melt below 265ºc. 5/2/08 Ormet Circuits Confidential
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Ormet Paste Before Cure
This slide shows the typical particle size of the SnBi allot and the copper powders. We typically formulate with alloy powders in the 5-15 micron size range, and copper particles of size in the 1 micron, 3 micron, and 8 micron ranges. We typically use combinations of these powders to meet the processing needs of our customers. We can tailor a formulation to the customer’s needs. Point Copper Tin Bismuth 1 98.48 1.52 2 100 3 Formulated with Copper and Tin/Bismuth powders
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Ormet Technology After Cure
Point Copper Tin Bismuth 1 52 47 2 70 29 3 54 45 4 71 28 5 100 After cure the SEM/EDX scan displays the intermetallic network and the typical copper-tin compositions. As is seen in the picture it is possible to see the core of some of the copper particles, but overall the alloy has melted, and the tin has formed a continuous structure that has sintered to customer’s copper pad. Bismuth is only in the formulation as a means to create the liquid phase in order for sintering to occur. Sintered Copper/Tin intermetallic network after cure
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Ormet Materials Final Reactants
Bismuth Melt 267° C ~16% of total matrix Copper Melt 1085° C Cu3Sn intermetallic Melt 640° C Cu6Sn5 intermetallic Melt 415° C This graphic depicts the composition of the material after cure, specifically showing the melting points of the various metals. Before cure the tin-bismuth alloy melted at 140C, now after cure the lowest melting point is 267C. This is the transient liquid phase sintering effect. Direction of tin migration
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Value Proposition of Ormet Technology
Low temperature metallic joining Processing temperatures between C Compatible with Pb-free solder reflow profiles Thermally stable up to 265C Superior shear strength versus conductive adhesives Metallic joining 25% higher strength versus adhesives The value as seen through the eyes of our customers is its ability to offer a low metal joining temperature, lead free, faster curing as compared to conductive adhesives, higher shear strength and its ability to be lower cost in volume as compared to Ag conductive pastes relative to raw material costs. Ormet Circuits Confidential
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Properties Comparison
12-16 (x,y) 72-85 (z) FR4 1 =46 : 2 240 100 Epoxy / Silver 20 25-58 20-40 Ormet 22 35 25 Solder 16 400 Copper Coefficient of Thermal Expansion (ppm/ C ) Thermal Conductivity (w/mK) Electrical Resistivity (micro ohm cm) Material Everybody asks, “What is Ormet? What can you compare it to?” Ormet offers a simple chart with known metals, alloys and conductive adhesives. (Silver Epoxy) While Ormet most closely matches solder in its physical attributes, it stands apart versus a silver epoxy. Thermal data is on the next slide. Ormet Circuits Confidential
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Thermal Properties CMC data to explore range of thermal properties in commercial products Measured by laser flash in free standing film and 3- layer structures Ormet has products ranging from 25 W/mK to 58 W/mK Unovis Data to explore thermal conductivity vs sintering temperature in Ormet 700 Ormet’s thermal conductivity is a compelling part of the reason to choose Ormet for die attach. Ormet has had thermal conductivity tested by 2 outside laboratories, and shown a consistent: 58 W/mk for Ormet 802 25 W/mK for Ormet 700 25 W/mK for Ormet 260C The data is robust versus curing condition. Ormet is continuing to test the properties of our material over time at 150C.
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Commercial Applications
Current product line used in fabrication of high complexity PCBs for server, mainframe and defense applications Core via-fill & z-axis interconnection Yield, reliability and performance drivers Ormet is being used in the commercial and military markets today making interconnections between layers of PCBs. By using Ormet in this way the has improved product yield, with better reliability through the reduced use of plated-through holes. Ormet allows the customer to place microvias only where they are needed in the board. This approach can reduce the number of layers required in the board, resulting in a board with improved electrical signal performance, and greater potential for thermal management solutions Ormet Circuits Confidential
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Ormet Interconnects in PCB Applications
Filled Via Ormet® Interconnect Copper Plated Via Pyralux Adhesive Layer The picture displays a high density built up Cu layer being attached to a multilayer sub assembly core. The b-staged Adhesive layer is applied to the sub-assembly core with a polyester coverlay sheet, and laser drilled. The coverlay sheet acts as a stencil, and the Ormet paste is printed into the holes. The coverlay sheet is then removed and the HDI layer is laminated to the core. The Ormet paste sinters to the copper pads of both layers, thus providing improved electrical/thermal resistance versus other paste solutions. Source: Endicott Interconnect Technologies Ormet Circuits Confidential
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X-Sections of Filled Vias
8 mil diameter 93 mil depth 50µm Diameter 400µm Depth Ormet has the ability to metallize holes where plating is becoming process challenged and expensive. Industry standard fill equipment is able to fill Ormet materials in a wide range of applications. These images show large via structures found in large back plane PCBs and small but high aspect ratio vias used in microelectronic substrates as an alternative to copper plating. Ormet Circuits Confidential
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Die Attach Development
7/23/08
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Objective Assess new products for die attach application
Confidential Objective Assess new products for die attach application Target is to provide alternative to high Lead solders Approach Investigate patented Liquid Phase Sintering Technology Investigate alternative cure profiles
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Test conditions Confidential Room temperature die shear (post-cure)
260C die shear (post-cure) 260C die shear (post 85/85 for 24hrs) Room temperature die shear (post 85/85 for 24hrs C solder reflow profiles) Test Vehicle 4x4mm copper die on Ag plated copper leadframe Bondline thickness microns
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Cure Conditions Condition 1: Condition 2: Condition 3: Condition 4:
Confidential Cure Conditions Condition 1: 30 min ramp to 170C C Condition 2: 30 min ramp to 170C C Condition 3: 30 min ramp to 190C C Condition 4: 30 min ramp to 205C C Condition 5: 30 min ramp to 205C C
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Test Results: Room Temperature DSS
Confidential Test Results: Room Temperature DSS Post Cure Post 85/ C
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Test Results: 260C Die Shear
Confidential Test Results: 260C Die Shear Post Cure Post 85/85
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Die Shear Observations
Confidential Die Shear Observations Failure mode was 100% cohesive Small voiding observed Strong effect of high cure temperature Compare condition #1 vs condition #4 Compare condition #2 vs condition #5 Longer cure time also will increase adhesion Compare condition #1 vs condition #2 Compare condition #4 vs condition #5 554 performance was improved through cure profile optimization Compare condition #3 vs #’s 4 & 5 RD256 has notably better results than other formulations Being sampled to beta sites as Ormet 555 Silver version being sampled as Ormet 580
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Cross Section Analysis: RD256
Confidential Cross Section Analysis: RD256 Post Cure Post 85/ C Excellent metallic bonding to surfaces and throughout material. No signs of delamination after reliability testing
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Confidential Void Free Attach 61m 25m
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Beta Site Testing Test Vehicle: Output Reliability Testing
Confidential Beta Site Testing Test Vehicle: 3x3mm Si die with Ag back-side plating Ag-plated lead frame Output Electrical resistance (RDSON) Thermal resistance (dVSD) Reliability Testing 0hr After MSL1 after MSL1 + UHST (96hr, 121C, 100% RH) after MSL1 and TMCL (500cycles, -65C/+150C)
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New Trials: Power & RF Modules
Provide 1 material solution Replace solders for passives Replace conductive adhesives for metal-backed IC’s, copper clips Initial Beta Site Sampling
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Die Attach Summary Confidential
Ormet is in beta site evaluation with new formulations for die attach Focus is for High –Pb solder replacement Die size target is <1x1mm to 4x4mm Viscosity is well suited to screen printing Low viscosity in development (RP-016) Very high 260C adhesion after moisture exposure to bare copper Customer reliability results look very promising Advance applications in development B-stage paste
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Confidential Wirebond Replacement
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Wire-bond Replacement Application Detail
Confidential Wire-bond Replacement Application Detail Mold Compound Ormet Memory Chips IC Substrate Photos courtesy of VCI Ormet’s technology is superior in T-cycling to conductive adhesive materials due to sintering to the bond pad and within the paste.
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16 Flash Memory Die Stack Innovative solution to advanced die stacking applications 100 micron lines 250 micron pitch Smaller form factor with lower assembly cost High electrical performance In collaboration with Asymtek and Vertical Circuits, Inc.
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Excellent Reliability Results
Confidential Excellent Reliability Results Proven Reliability at 2 major Flash Memory OEMs PRETEST 60'C 90'C RH THB CTH -A TCB HAST - HTS 150’C Source Lot# Live Die after reflow 504hr 1008hr 72hr 250Cyc 500Cyc 750Cyc 1000Cyc 96hr BD4S2YG.11 2 0/320 0/34 0/30 0/67 0/62 0/138 0/71 BDZS2YG.11 4 0/160 0/33 0/35 0/31 0/22 BD2PMWG.11 0/143 0/20 0/32 NA Data courtesy of VCI 8 die stack flash memory CSP
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Confidential Staggered Die Stack 1 2 3 4 5 6 7 8 Staggered die stack in development with Vertical Circuits
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Ormet Circuits Product Line Overview
Application Product Lead Free Process Viscosity Thermal Conductivity Cure Via Fill & Z-axis Interconnection Ormet 701 A copper-based conductive paste used to form Z-axis interconnects by filling microvias in multilayer boards and substrates Yes Screen Print / Dispense KCPS 25 W/mK Lamination Press Autoclave Vacuum Bag Ormet 701AG A silver-based conductive paste used to form Z-axis interconnects by filling microvias in multilayer boards and substrates Ormet A lead- based conductive paste used to form Z-axis interconnects by filling microvias in multilayer boards and substrates No Die Attach Ormet 555: A copper-based dispensable, or screen printable, electrically and thermally conductive paste for discrete, IC, and LED die attach applications. KCPS Box Oven with Nitrogen Atmosphere Ormet 580 A silver-based dispensable, or screen printable, electrically and thermally conductive paste for discrete, IC, and LED die attach applications. Conductive lines and traces Ormet 260 A screen printable, electrically conductive paste used for signal circuit creation and jumper wire repair. KCPS Reflow or Box Oven with Nitrogen Atmosphere Ormet 260C A dispensable or screen printable, non slumping, electrically conductive paste used for creating conductive lines down to 80 microns. Ormet 2600 A lead based screen printable, electrically conductive paste used for signal circuit creation and jumper wire repair. Solder Replacement Ormet 400 A screen printable conductive paste used as an alternative to solder paste. PTH fill Ormet 802 A conductive paste used for plugging thermal vias and copper through holes. Pneumatic Pressure Fill KCPS 58 W/mK
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Summary Ormet’s TLPS is in HVM to form high performance PCB interconnections Provides Pb-free compatibility with low temperature assembly Ongoing work to assess technology for electronics assembly applications We are continuing to develop our TLPS technology, and willing to collaborate with customers, universities and other external groups. Our current development efforts are focused on IC packaging, solar cell assembly, and PCB fabrication. Ormet Circuits Confidential
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