†Institute for Molecular Engineering, University of Chicago, 5747 South Ellis Avenue, Chicago, Illinois 60637, United States.
§Center for Nanoscale Science and Technology, National Institute of Standards and Technology, 100 Bureau Drive, Gaithersburg, Maryland 20899, United States.
ACS Nano. 2015 May 26;9(5):5333-47. doi: 10.1021/acsnano.5b01013. Epub 2015 May 12.
Understanding and controlling the three-dimensional structure of block copolymer (BCP) thin films is critical for utilizing these materials for sub-20 nm nanopatterning in semiconductor devices, as well as in membranes and solar cell applications. Combining an atomic layer deposition (ALD)-based technique for enhancing the contrast of BCPs in transmission electron microscopy (TEM) together with scanning TEM (STEM) tomography reveals and characterizes the three-dimensional structures of poly(styrene-block-methyl methacrylate) (PS-b-PMMA) thin films with great clarity. Sequential infiltration synthesis (SIS), a block-selective technique for growing inorganic materials in BCPs films in an ALD tool and an emerging technique for enhancing the etch contrast of BCPs, was harnessed to significantly enhance the high-angle scattering from the polar domains of BCP films in the TEM. The power of combining SIS and STEM tomography for three-dimensional (3D) characterization of BCP films was demonstrated with the following cases: self-assembled cylindrical, lamellar, and spherical PS-b-PMMA thin films. In all cases, STEM tomography has revealed 3D structures that were hidden underneath the surface, including (1) the 3D structure of defects in cylindrical and lamellar phases, (2) the nonperpendicular 3D surface of grain boundaries in the cylindrical phase, and (3) the 3D arrangement of spheres in body-centered-cubic (BCC) and hexagonal-closed-pack (HCP) morphologies in the spherical phase. The 3D data of the spherical morphologies was compared to coarse-grained simulations and assisted in validating the simulations' parameters. STEM tomography of SIS-treated BCP films enables the characterization of the exact structure used for pattern transfer and can lead to a better understating of the physics that is utilized in BCP lithography.
理解和控制嵌段共聚物(BCP)薄膜的三维结构对于在半导体器件中利用这些材料进行亚 20nm 纳米图案化,以及在膜和太阳能电池应用中具有重要意义。结合原子层沉积(ALD)技术增强透射电子显微镜(TEM)中 BCP 的对比度,以及扫描透射电子显微镜(STEM)断层扫描技术,清晰地揭示和描述了聚(苯乙烯-嵌段-甲基丙烯酸甲酯)(PS-b-PMMA)薄膜的三维结构。顺序渗透合成(SIS)是一种在 ALD 工具中选择性生长无机材料的嵌段共聚物薄膜的技术,也是增强 BCP 刻蚀对比度的新兴技术,用于显著增强 TEM 中 BCP 薄膜的极性畴的高角度散射。通过 SIS 和 STEM 断层扫描相结合进行 BCP 薄膜三维(3D)表征的能力,在以下情况下得到了证明:自组装圆柱形、层状和球形 PS-b-PMMA 薄膜。在所有情况下,STEM 断层扫描都揭示了隐藏在表面以下的 3D 结构,包括:1)圆柱形和层状相缺陷的 3D 结构,2)圆柱形相晶粒边界的非垂直 3D 表面,以及 3)体心立方(BCC)和六方最密堆积(HCP)形态中球体的 3D 排列。球形形态的 3D 数据与粗粒化模拟进行了比较,并有助于验证模拟的参数。SIS 处理的 BCP 薄膜的 STEM 断层扫描能够对用于图案转移的精确结构进行表征,并有助于更好地理解 BCP 光刻中利用的物理原理。
