Study of i-Line Photosensitive Materials with a Wide Depth of Focus for Fine Pitch Redistribution Layers

Daiki Yukimori, Mei Kunito, N. Ishikawa, A. Sekiguchi, T. Ogata
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引用次数: 1

Abstract

In this study, we investigated the design of photosensitive materials with a wide depth of focus (DOF) for use in fine pitch redistribution layers. First, we developed a photosensitive material having a DOF exceeding 4.0 µm with 0.8-µm line/space (L/S) patterns and that having a DOF of 4.0 µm with $\mathrm{0}.\mathrm{7}-\mu \mathrm{m}$ L/S patterns, at a numerical aperture (NA) of 0.5. Second, we simulated the DOF to match the experimental DOF using lithography simulation software (PROLITH). Subsequently, we simulated the DOF at an NA of 0.24 and obtained a $\mathrm{10}.\mathrm{8}-\mu \mathrm{m}$ DOF with $\mathrm{0}.\mathrm{8}-\mu \mathrm{m}$ L/S patterns and a $\mathrm{6}.\mathrm{8}-\mu \mathrm{m}$ DOF with $\mathrm{0}.\mathrm{7}-\mu \mathrm{m}$ L/S patterns of the photosensitive material. For a detailed insight of the performance at the NA of 0.24, we conducted an aerial image simulation; we also simulated the impact of three dissolution parameters-$-\mathrm{R}_{\text{max}},\ \mathrm{R}_{\text{min}}$, and development time—on the DOF. For the $\mathrm{0}.\mathrm{7}-\mu \mathrm{m}$ L/S patterns, we found that precise $\mathrm{R}_{\text{min}}$ control is essential for a wide DOF. In fact, for an $\mathrm{R}_{\text{max}}$ ranging from 150 to 1000 nm/s, a precise $\mathrm{R}_{\text{min}}$ control of less than 0.4 nm/s is required for a $\mathrm{7}.\mathrm{0}-\mu \mathrm{m}$ DOF.
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细间距重分布层宽聚焦深度i-线光敏材料的研究
在本研究中,我们研究了用于细间距重分布层的具有宽焦深(DOF)的光敏材料的设计。首先,我们开发了一种光敏材料,具有0.8 μ m线/空间(L/S)图案,DOF超过4.0 μ m,并且具有$\ mathm{0}的DOF为4.0 μ m。\mathrm{7}-\mu \mathrm{m}$ L/S模式,数值孔径(NA)为0.5。其次,利用光刻仿真软件(PROLITH)进行了DOF仿真,使之与实验DOF相匹配。随后,我们在NA为0.24的情况下模拟了DOF,得到了$\ mathm{10}。\ mathm {8}-\mu \ mathm {m}$ DOF与$\ mathm{0}。\ mathm {8}-\mu \ mathm {m}$ L/S模式和$\ mathm{6}。\ mathm {8}-\mu \ mathm {m}$ DOF与$\ mathm{0}。\ mathm {7}-\mu \ mathm {m}$ L/S模式的光敏材料。为了详细了解NA为0.24时的性能,我们进行了航空图像模拟;我们还模拟了三个分解参数$-\ mathm {R}_{\text{max}}、\ \ mathm {R}_{\text{min}}$和开发时间对DOF的影响。对于$\ mathm{0}。\mathrm{7}-\mu \mathrm{m}$ L/S模式,我们发现精确的$\mathrm{R}_{\text{min}}$控制对于大自由度是必不可少的。事实上,对于$\mathrm{R}_{\text{max}}$范围从150到1000 nm/s, $\mathrm{R}_{\text{min}}$需要精确控制在小于0.4 nm/s的$\mathrm{R}_{\text}}$。\ mathm {0}-\mu \ mathm {m}$ DOF。
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