Katsuyuki Sakuma

Three-dimensional silicon integration

Three-dimensional (3D) silicon integration of active devices with through-silicon vias (TSVs), thinned silicon, and silicon-to-silicon fine-pitch interconnections offers many product benefits. Advantages of these emerging 3D silicon integration technologies can include the following: power efficiency, performance enhancements, significant product miniaturization, cost reduction, and modular design for improved time to market. IBM research activities are aimed at providing design rules, structures, and processes that make 3D technology manufacturable for chips used in actual products on the basis of data from test-vehicle (i.e., prototype) design, fabrication, and characterization demonstrations. Three-dimensional integration can be applied to a wide range of interconnection densities (<10/cm2 to 108/cm2), requiring new architectures for product optimization and multiple options for fabrication. Demonstration test structures, which are designed, fabricated, and characterized, are used to generate experimental data, establish models and design guidelines, and help define processes for future product consideration. This paper 1) reviews technology integration from a historical perspective, 2) describes industry-wide progress in 3D technology with examples of TSV and silicon-silicon interconnection advancement over the last 10 years, 3) highlights 3D technology from IBM, including demonstration test vehicles used to develop ground rules, collect data, and evaluate reliability, and 4) provides examples of 3D emerging industry product applications that could create marketable systems.

Future system-on-silicon LSI chips

A new three-dimensional (3D) integration technology to achieve system-on-silicon LSIs has been proposed. Several LSI wafers are vertically stacked and glued each other after thinning them in this 3...The development of system-on-silicon large-scale integration (LSI) devices has significantly influenced the demand for higher wiring connectivity within LSI chips. Currently, increasing the number of metal layers in a multilevel metallization as the device size decreases increases wiring connectivity. In the future, however, designers will have difficulty catching up with the rising demand for higher wiring connectivity by merely increasing the number of metal layers. We propose a new three-dimensional integration technology to overcome future wiring connectivity crises. In our solution, several vertically stacked chip layers in 3D LSI chips or 3D multichip modules (MCMs) are fabricated using our new integration technology. More than 10/sup 5/ interconnections per chip form in a vertical direction in these 3D LSI chips or 3D MCMs. Consequently, we can dramatically increase wiring connectivity while reducing the number of long interconnections.

3D silicon integration

Three-dimensional (3D) chip integration may provide a path to miniaturization, high bandwidth, low power, high performance and system scaling. Integration options can leverage stacked die and/or silicon packages depending on applications. The enabling technology elements include: (i) through-silicon-vias (TSV) with thinned silicon wafers, (ii) fine pitch wiring, (iii) fine pitch interconnection between stacked die, (iv) fine pitch test for known-good die, and (v) power delivery, distribution and thermal cooling technology. Applications may range from miniaturization of portable electronics like image sensors and cell phones to power efficient, high performance computing solutions such as servers and super computers. Silicon based packaging and 3D stacked die technologies have been in research studies for more than a decade at IBM and in industry, universities & consortia. IBM research experiments have included test vehicle design, build, characterization and modeling. Robust structures and processes have been developed based on (i) process learning for silicon based structures, (ii) assembly process comparisons for fine pitch chip interconnection, (iii) electrical, mechanical and thermal characterization and (iv) reliability & accelerated stress characterization. TSV technology investigations have included composite, copper and tungsten metallurgies. Wiring demonstrations ranged from sub-micron fine pitch wiring line widths & spaces to larger dimensions. I/O interconnections investigated feature sizes such as 100 I/O / mm2, 400 I/O/mm2, and interconnection features sizes which support 2500 I/O / mm2. In addition, integrated decoupling capacitors of one hundred ten nano-farads per mm2 per layer and assembly of module structures on silicon packages with ceramic or organic base packages were demonstrated. Examples of robust TSV structures and characterization, single die with silicon interposers, multiple die on a silicon package and stacked die assemblies are given along with highlights of characterization including aspects of electrical, mechanical and reliability results. This research paper describes recent advances in industry and reports advancements from IBM in the design, technical challenges and progress toward 3D chip integration structures. In addition, examples of potential applications that may take advantage of 3D integration are discussed.

3D chip-stacking technology with through-silicon vias and low-volume lead-free interconnections

Three-dimensional (3D) integration using through-silicon vias (TSVs) and low-volume lead-free solder interconnects allows the formation of high signal bandwidth, fine pitch, and short-distance interconnections in stacked dies. There are several approaches for 3D chip stacking including chip to chip, chip to wafer, and wafer to wafer. Chip-to-chip integration and chip-to-wafer integration offer the ability to stack known good dies, which can lead to higher yields without integrated redundancy. In the future, with structure and process optimization, wafer-to-wafer integration may provide an ultimate solution for the highest manufacturing throughput assuming a high yield and minimal loss of good dies and wafers. In the near term, chip-to-chip and chip-to-wafer integration may offer high yield, high flexibility, and high performance with added time-to-market advantages. In this work, results are reported for 3D integration after using a chip-to-wafer assembly process using 3D chip-stacking technology and fine-pitch interconnects with lead-free solder. Stacks of up to six dies were assembled and characterized using lead-free solder interconnections that were less than 6 µm in height. The average resistance of the TSV including the lead-free solder interconnect was as low as 21 mΩ.

Intelligent image sensor chip with three dimensional structure

A new three-dimensional (3D) integration technology based on wafer bonding technique has been proposed for intelligent image sensor chip with 3D stacked structure. We have developed key technologies for such 3D integration. A 3D image sensor test chip was fabricated using this 3D integration technology. Basic electric characteristics were evaluated in the 3D image sensor test chip.

New Three-Dimensional Wafer Bonding Technology Using the Adhesive Injection Method

A new three-dimensional (3D) wafer bonding technology using the adhesive injection method has been proposed, in order to realize a real-time micro-vision system and a real shared memory. Several key technologies for 3D LSI, such as deep trench formation for buried interconnection, wafer grinding and chemical-mechanical polishing, wafer alignment and wafer bonding using the adhesive injection method, have been developed.

3D Chip Stacking Technology with Low-Volume Lead-Free Interconnections

In this paper a three-dimensional (3D) chip stacking technology using fine-pitched interconnects with lead-free solder is described. Different interconnect metallurgies such as Cu/Ni/In, Cu/In and Cu/Sn were considered and the bonding conditions to optimize the bonding parameters were determined. The effect of intermetallic compound (IMC) formation on the mechanical properties of the joins is discussed. Unlike standard 100-micron C4 solder balls, very small solder volumes (< 6 microns high) were investigated. The mechanical properties were evaluated by shear and impact shock testing, while scanning electron microscopy (SEM) and optical microscopy were used to study the morphology of the IMC layers in solder joins before and after annealing. It was found that Cu/Ni/In and Cu/In interconnections have slightly lower shear strength per bump. While these values were lower than the Cu/Sn joins, the Cu/Ni/In chips passed the impact shock test for a simulated heat sink mass of 27 g/cm2. The reasons for the differences in reliability of these metallurgies are discussed. 3D chip stacking using two-layers of chips with fine-pitch lead-free interconnects was demonstrated. The resistance of link chains comprising through-vias, lead-free interconnects and Cu links were measured using a 4-point probing method. The average resistance of the through-via including the lead-free interconnect was 21 mOmega.

Development of Three-Dimensional Integration Technology for Highly Parallel Image-Processing Chip

A new three-dimensional (3D) integration technology for realizing a highly parallel image-processing chip has been developed. Several LSI wafers are vertically stacked and glued to each other after thinning them using this new technology. This technology can be considered as both 3D LSI technology and wafer-scale 3D chip-on-chip packaging technology. The effective packaging density can be significantly increased by stacking the chips in a vertical direction. Several key techniques for this 3D integration have been developed. In this paper, we demonstrate the highly parallel image sensor chip with a 3D structure. The 3D image sensor test chip was fabricated using this new 3D integration technology and its basic performance was evaluated.

IMC bonding for 3D interconnection

We performed stacking experiments on Si dies using annular tungsten TSVs (Through Silicon Vias) and Cu studs with low-volume solder micro-bumps. Unlike standard 100-micron C4 (Controlled Collapse Chip Connection) solder balls, very small solder volumes (< 6 microns in height) form IMC (InterMetallic Compounds) in the junctions during the bonding or reflow processes. The two interconnect metallurgies of Cu/Ni/In and Cu/Sn joints were considered for low-volume lead-free solder micro-bumps for 3D integration. A previous study on these metallurgies [5] showed that the Cu/Sn joints form thermally stable intermetallics while in the Cu/Ni/In joints, some indium solder remains unreacted due to the presence of the Ni barriers. The shear testing on the stacked systems showed that the die stacks with Cu/Sn joints exhibit higher shear strengths than those with Cu/Ni/In joints. However the impact shock testing on the systems revealed that the die stacks with Cu/Sn joints are less resistant to mechanical shocks than the systems with Cu/Ni/In joints. This new work focuses on thermal cycle testing of the die stack systems with the Cu/Ni/In and Cu/Sn interconnections. Preliminary thermal cycle testing on the die stack systems with Cu/Ni/In joints showed that the joints are stable against thermal cycle stresses for thousands of cycles. To quickly compare the systems with two metallurgies, we mounted the Si die stacks onto organic substrates to impose additional stresses on the systems. In addition to standard DTC (Deep Thermal Cycle) tests, we also conducted a HAATS (Highly accelerated Air to Air Thermal Shock) test [23] with a short cycle time to reduce the testing time. The DTC and HAATS tests showed that the stacked systems with Cu/Ni/In joints had fewer failures and smaller increases in the electrical resistances of the joints during the tests than the systems with Cu/Sn joints.

3D chip stacking with C4 technology

Three-dimensional (3D) integration technology promises to continue enhancing integrated-circuit system performance with high bandwidth, low latency, low power, and a small form factor for a variety of applications. In this work, conventional C4 (controlled-collapse chip connection) technology is studied for robust interconnection between stacked thin chips. Various solder hierarchies to enable 3D chip stacking and packaging are investigated. Examples are presented to compare stacking schemes with sequential and parallel reflow. Chips as thin as 90 µm are stacked using conventional chip-placement and reflow processes, and the associated process challenges are investigated and discussed. Warpage of the thin chips is measured on various substrates. Rework of the chip stack has also been demonstrated through a temporary chip attachment operation, and the scalability of reworkable C4 is investigated.