Transmission Helium Ion Microscopy

透射氦离子显微镜

• 批准号: RGPIN-2019-05086
• 负责人: Kavanagh, Karen
• 金额: $ 4.44万
• 依托单位: Simon Fraser University
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 财政年份: 2019
• 资助国家: 加拿大
• 起止时间: 2019-01-01 至 2020-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=691089
• 关键词: Transmission; Helium; Ion; Microscopy

Electronic systems continue to evolve towards smaller sizes, with increased capabilities, while reducing cost and power requirements. One-dimensional device geometries, atomically-thin, two-dimensional, materials, and unusual semiconductors have entered the field. Single electron or photon detectors, emitters, and switches are increasingly reported. A new information bit has developed called a qubit resulting from the quantum size of these new devices. These intriguing new capabilities are not only scientifically fascinating, but are enabling new industries by their application in novel electronic designs.******Every development in electronics has occurred in parallel with, or because of, new types of fabrication, imaging and characterization capabilities. Electron microscopy have steadily improved our capabilities for "seeing" complex structures at the atomic scale. Atomic profiling via high-energy helium ion beams, one of the oldest characterization techniques (Rutherford backscattering), was a pivotal tool during the early development of silicon chips for computers and continues to evolve for larger area processing. Liquid metal sources for focussed ion beams of almost any element have revolutionized the fine milling and patterning industry. A single atom tip source for helium ions, combined with a stable focussing column, is providing new opportunities for novel characterization.******The aim of this research program is to establish Transmission Helium Ion Microscopy (THIM), for the characterization of the atomic composition and thickness of very thin materials. The HIM ion source emits ions from a tiny volume (one tungsten atom). Accelerated helium atoms easily pass in between the atoms in a solid but begin to slow down rapidly from electrostatic forces. The ability to steer a He ion via rows of atoms (channeling) will be applied to quantify layer thickness and atomic composition from scattering intensities. The presence of contaminants and impurities may be detected by their effects on the energy and phase of the beam. Their detection after passing through a thin sample can tell us much about the sample. ******To carry out THIM better cameras will be needed. We will be working with Canadian industry towards future products and manufacturing opportunities. The application of THIM to materials characterization will benefit the Canadian and global electronics industry in general through their need for smaller and more efficient active device properties. The research will likely enable higher resolution detection of electrical properties critical to lasers, light emitting diodes and solar cell applications. The training of personnel in the new advanced techniques proposed here will help Canadian society stay with or ahead of the global community in understanding and designing the next generation of critical electronic materials and devices. Our ability to devise new solutions and create new devices will improve our quality of life. **

电子系统继续朝着更小的尺寸发展，具有增加的能力，同时降低成本和功率要求。一维器件几何形状，原子薄，二维材料和不寻常的半导体已经进入该领域。单电子或光子探测器、发射器和开关的报道越来越多。一种新的信息比特已经开发出来，称为量子比特，这是由这些新设备的量子尺寸产生的。这些有趣的新功能不仅在科学上令人着迷，而且通过在新颖的电子设计中的应用，使新的行业成为可能。电子学的每一次发展都是与新型的制造、成像和表征能力并行发生的，或者是因为这些能力。电子显微镜已经稳步提高了我们在原子尺度上“看到”复杂结构的能力。通过高能氦离子束的原子轮廓，最古老的表征技术之一（卢瑟福背散射），是早期开发计算机硅芯片的关键工具，并继续发展为更大面积的处理。用于几乎任何元素的聚焦离子束的液态金属源已经彻底改变了精细铣削和图案化工业。氦离子的单原子尖端源与稳定的聚焦柱相结合，为新的表征提供了新的机会。该研究计划的目的是建立透射氦离子显微镜（THIM），用于表征非常薄的材料的原子组成和厚度。HIM离子源从微小体积（一个钨原子）发射离子。加速的氦原子很容易通过固体中的原子之间，但开始由于静电力而迅速减速。通过原子行（通道）引导He离子的能力将被应用于从散射强度量化层厚度和原子组成。污染物和杂质的存在可以通过它们对光束的能量和相位的影响来检测。它们通过薄样品后的检测可以告诉我们很多关于样品的信息。* **我们将与加拿大工业界合作，寻找未来的产品和制造机会。THIM在材料表征中的应用将使加拿大和全球电子行业受益，因为他们需要更小，更有效的有源器件特性。该研究可能会实现对激光器，发光二极管和太阳能电池应用至关重要的电气特性的更高分辨率检测。在这里提议的新的先进技术方面的人员培训将有助于加拿大社会在理解和设计下一代关键电子材料和设备方面与国际社会保持一致或领先于国际社会。我们设计新解决方案和创造新设备的能力将提高我们的生活质量。**