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http://dx.doi.org/10.3740/MRSK.2007.17.7.347

Overview of High Performance 3D-WLP  

Kim, Eun-Kyung (Department of Nano-IT Engineering, Graduate School of Energy & Environment Seoul National University of Technology)
Publication Information
Korean Journal of Materials Research / v.17, no.7, 2007 , pp. 347-351 More about this Journal
Abstract
Vertical interconnect technology called 3D stacking has been a major focus of the next generation of IC industries. 3D stacked devices in the vertical dimension give several important advantages over conventional two-dimensional scaling. The most eminent advantage is its performance improvement. Vertical device stacking enhances a performance such as inter-die bandwidth improvements, RC delay mitigation and geometrical routing and placement advantages. At present memory stacking options are of great interest to many industries and research institutes. However, these options are more focused on a form factor reduction rather than the high performance improvements. In order to improve a stacked device performance significantly vertical interconnect technology with wafer level stacking needs to be much more progressed with reduction in inter-wafer pitch and increases in the number of stacked layers. Even though 3D wafer level stacking technology offers many opportunities both in the short term and long term, the full performance benefits of 3D wafer level stacking require technological developments beyond simply the wafer stacking technology itself.
Keywords
Wafer Level packaging; 3D Packaging; Wafer Stacking;
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