Immersion Lithography Ready for 45 nm Manufacturing and Beyond

Owa, Soichi; Nakano, K.; Nagasaka, Hiroyuki; Fujiwara, Tomoharu; Matsuyama, Tomoyuki; Ohmura, Yasuhiro; Magoona, H.

doi:10.1109/asmc.2007.375108

Cited by 7 publications

(2 citation statements)

References 5 publications

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“…Unfortunately, sub-wavelength lithography results in severe distortions of the layout patterns [1] due to optical diffraction and interference. Many innovative techniques have been developed to reduce/compensate for these distortions that include, for example, optical proximity correction (OPC) [2], phase-shift mask (PSM) [3], immersion lithography [4], and double-patterning [5]. OPC modifies the geometric features in the design layout itself in order to compensate for the distortions.…”

Section: Chapter 1 Introductionmentioning

confidence: 99%

Physically-Aware Analysis of Systematic Defects in Integrated Circuits

Tam¹,

Blanton

2012

IEEE Des. Test. Comput.

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In the integrated circuit (IC) industry, all products must go through three phases before they are available in the market, namely design, manufacturing, and testing. Design, obviously, refers to the process of converting the early concepts of the product into a precise description of its implementation. Manufacturing then uses this description to fabricate the product, where the design is physically materialized onto the silicon wafer and later packaged into the product. If design and manufacturing are perfect, then every fabricated IC is completely functional, thereby obliterating the need for testing. Unfortunately, both design and manufacturing are not ideal; therefore every manufactured IC must be subject to stringent testing procedures to ensure that most bad ICs are identified and prevented from shipping to the end-users.ICs are deemed bad when they contain certain defects that cause the ICs to fail the specifications.Defects are unintended structural and/or material changes of the IC due to design/manufacturing imperfections.These physical changes may alter the electrical characteristics of the circuit, which are sometimes severe enough to lead to a failure (i.e., violation of one or more design specifications). Common defects in IC manufacturing can be caused by contaminations in the process, variations of the process conditions, or simply the difficulty to fabricate certain features of the design. The last issue is the focus of this dissertation. Defects that arise due to certain aspects of the design being sensitive to the manufacturing process with an elevated likelihood of failure are known as systematic defects. This dissertation addresses the issues related to the prevention and identification of systematic defects by analyzing a large amount of manufactured ICs that have failed testing.For systematic-defect prevention, one common approach is to use design-for-manufacturability (DFM) rules to communicate hard-to-manufacture features to designers so that these features can be minimized in the iii design. Obviously, different rules describe different features and thus their violation/adherence will have different impact on the manufacturability of the product. It is therefore desirable to measure the relative importance of the rules and how they affect product yield. To address this issue, a method called RADAR (Rule Assessment of Defect-Affected Regions) has been developed for measuring the effectiveness of DFM rules in preventing systematic defects. RADAR analyzes a large amount of test data of failed ICs to draw statistical conclusion.Taking preventive measures, such as enforcing DFM rules, is necessary to ensure sufficient product yield. Unfortunately, the amount of resource (circuit area, designer's time, etc.) dedicated to DFM can be quite limited. It is therefore impractical to anticipate and prevent every possible hard-to-manufacture design features before the product is manufactured. Thus, systematic defects can still exist. Therefore, a mechanism is required to identify systematic ...

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Section: Chapter 1 Introductionmentioning

confidence: 99%

Physically-Aware Analysis of Systematic Defects in Integrated Circuits

Tam¹,

Blanton

2012

IEEE Des. Test. Comput.

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“…Several scaling down technology such as double patterning [1], immersion photo lithography [2] and new device structure with low resistance gate stack [3], high-k material [4] and charge trap devices [5] are considered for the next flash memory era. However scaling-down requires high cost lithography process, and the conventional floating gate has some limitation to be overcome [4].…”

Section: Introductionmentioning

confidence: 99%

16-Gigabit, 8-level NAND flash memory with 51nm 44-cell string technology

Kim

Chang

Hong

et al. 2008

ESSDERC 2008 - 38th European Solid-State Device Research Conference

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Eight-level NAND flash memories with 51nm design rule and 44-cell string floating gate technology have been successfully developed for the first time. 44-cell string with floating poly silicon and tungsten silicide (WSi) gate structure reduced the cell area per bit and improved chip cost efficiency. 44-cell string structure shows acceptable cell current and the results of endurance and interference are quite comparable to the conventional 32-cell string structure.

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