熱調制顯微與能譜技術

李奕安; Yi-An Lee

請用此 Handle URI 來引用此文件： http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/101766

完整後設資料紀錄

DC 欄位	值	語言
dc.contributor.advisor	呂明璋	zh_TW
dc.contributor.advisor	Ming-Chang Lu	en
dc.contributor.author	李奕安	zh_TW
dc.contributor.author	Yi-An Lee	en
dc.date.accessioned	2026-03-04T16:23:56Z	-
dc.date.available	2026-03-05	-
dc.date.copyright	2026-03-04	-
dc.date.issued	2025	-
dc.date.submitted	2026-01-27	-
dc.identifier.citation	1.Shin, J. et al. Light-triggered thermal conductivity switching in azobenzene polymers. Proc. Natl. Acad. Sci. 116, 5973–5978 (2019). 2.Li, M. et al. Electrically gated molecular thermal switch. Science 382, 585–589 (2023). 3.Liu, C. et al. Low voltage-driven high-performance thermal switching in antiferroelectric PbZrO3 thin films. Science 382, 1265–1269 (2023). 4.Llovet, X., Moy, A., Pinard, P. T. & Fournelle, J. H. Electron probe microanalysis: A review of recent developments and applications in materials science and engineering. Prog. Mater. Sci. 116, 100673 (2021). 5.Gavrilenko, V., Novikov, Y., Rakov, A. & Todua, P. Measurement of the parameters of the electron beam of a scanning electron microscope. Proc. SPIE - Int. Soc. Opt. Eng. 7042, (2008). 6.Wang, S.-M. et al. Standardization and quantification of backscattered electron imaging in scanning electron microscopy. Ultramicroscopy 262, 113982 (2024). 7.Henderson, G., De Groot, F. & Moulton, B. X-ray Absorption Near-Edge Structure (XANES) Spectroscopy. Rev. Mineral. Geochem. 78, 75–138 (2014). 8.Yamamoto, T. Assignment of Pre-Edge Peaks in K-Edge X-ray Absorption Spectra of 3d Transition Metal Compounds: Electric Dipole or Quadrupole? X-Ray Spectrom. 37, (2008). 9.Zhong-Kai, G. et al. Research Progress of Lock-in Amplifier. Acta Phys. Sin. 72, (2023). 10.Li, L., Mao, L. & Yang, J. A Review of Principles, Analytical Methods, and Applications of SEM‐EDS in Cementitious Materials Characterization. Adv. Mater. Technol. 10, (2024). 11.Koenig, C., Fanta, A. B. da S. & Jinschek, J. R. Measurement of electron beam induced sample heating in SEM experiments. Ultramicroscopy 276, 114195 (2025). 12.Kanter, H. Energy Dissipation and Secondary Electron Emission in Solids. Phys. Rev. 121, 677–681 (1961). 13.Kumar, S. & Mitra, K. Microscale Aspects of Thermal Radiation Transport and Laser Applications. in Advances in Heat Transfer (eds Hartnett, J. P., Irvine, T. F., Cho, Y. I. & Greene, G. A.) vol. 33 187–294 (Elsevier, 1999). 14.Wheatstone, C. An account of several new instruments and processes for determining the constants of a voltaic circuit. Abstr. Pap. Print. Philos. Trans. R. Soc. Lond. 4, 469–471 (1997). 15.A three-probe method for accurate nanoscale thermal transport measurements \| Applied Physics Letters \| AIP Publishing.	-
dc.identifier.uri	http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/101766	-
dc.description.abstract	本論文以懸浮式氮化矽微結構為量測平台，針對奈米線與奈米顆粒樣品，系統性研究在聚焦電子束激發下的熱調製行為。研究中採用掃描式電子顯微鏡（SEM）的電子束對樣品進行局部直流加熱，同時在樣品加熱端以ω的頻率交流電流加熱，並以鎖相放大器量測2ω與3ω訊號。此實驗設計讓我發現了電子束可以對一奈米線或微米線的熱傳導進行調製，並發現其調製機制跟樣品的二次電子與核電子躍遷的X光放射相關。此外，研究過程中亦系統性分析了不同裝置長度下熱阻、熱調製沿距離變化，以及熱輻射、X射線發射等能量耗散機制對訊號的影響。為實現熱調製顯微術，我進一步結合資料擷取系統（DAQ）實現高解析度熱影像取得。實驗結果證實，熱調製顯微術不僅能有效改變奈米尺度下材料的局部熱傳導特性，也能對元素特徵邊界行為進行精細解析。為驗證熱調製能譜成分技術，我透過精細調控電子束加速電壓分別於Si、Ge、Pt等材料的X光特徵吸收邊（K-edge、L-edge）附近，量測到顯著的熱調製訊號變化。特別以電子探針微區分析（EPMA）作為對照，針對同一SiGe顆粒區域進行材料成分分布分析。並將其與傳統EPMA分析結果進行比較。本研究展示了高解析度熱調製顯微術與能譜技術對於微奈米材料分析的新應用潛力，並對其機制提出具體實驗證據與理論探討。	zh_TW
dc.description.abstract	This thesis employs suspended SiNₓ microstructures as measurement platforms to systematically investigate the thermal modulation behavior of nanowire and nanoparticle samples under focused electron beam excitation. The electron beam of a scanning electron microscopy (SEM) is used for localized DC heating of the samples, while an AC current at frequency ω is applied at the heater and lock-in amplifiers are utilized to measure the 2ω and 3ω signals. This experimental design allows me to discover that the electron beam can modulate the thermal conduction of a nanowire or microwire, and the modulation mechanism is related to the sample’s secondary electrons’ emission and X-ray emission from core-level electrons’ transitions. Additionally, I systematically analyze the effects of thermal resistance, thermal modulation variation along distance, and energy dissipation mechanisms such as thermal radiation and X-ray emission on the signal under different device lengths. To realize thermal modulation microscopy, I further integrate a data acquisition system (DAQ) to achieve high-resolution thermal imaging. The experimental results confirm that thermal modulation microscopy can effectively reveal the local thermal conduction properties of materials at the nanoscale and resolve the boundaries of samples. To validate the thermal modulation spectroscopy capabilities, I find changes in thermal modulation signals near the characteristic absorption edges (K-edge, L-edge) of materials such as Si, Ge, and Pt by fine-tuning the electron beam acceleration voltage. For comparison, electron probe microanalysis (EPMA) is used as a reference to analyze the material composition distribution in the same SiGe particle region. Overall, this work demonstrates the new application potential of high-resolution thermal modulation mapping in micro/nano material analysis, providing experimental evidence and theoretical discussions for the underlying mechanisms.	en
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dc.description.tableofcontents	摘要 i Abstract ii 目次 iii 圖次 vi Chapter 1 Introduction 1 1.1 Research Background and Motivation 1 1.2 Research Objective 3 1.3 Research Methods and Experimental Overview 4 1.4 Thesis Organization 5 Chapter 2 Fundamental Theories 6 2.1 Fundamentals of Scanning Electron Microscopy (SEM) 6 2.1.1 Electron Beam Generation, Acceleration, and Focusing 6 2.1.2 Electron–Material Interactions: SE & BSE Generate Mechanisms 7 2.1.3 SEM Signal Detection and Imaging Modes 7 2.2 Inner-Shell Electron Transitions and Characteristic Edges 8 2.2.1 K-edge and L-edge definitions and physical origin 9 2.2.2 Physical Mechanism of Absorption Edge–Induced Thermal Modulation 10 2.3 Harmonic Signal Calculation in Lock-in Detection 12 2.3.1 Lock-in amplifier 12 2.3.2 1ω Signal physical meaning 14 2.3.3 2ω Signal 14 2.3.4 3ω Signal 15 2.3.5 4ω Signal 16 2.4 Principles of Electron Probe Microanalysis (EPMA) and Elemental Mapping 17 2.4.1 Qualitative Analysis and Elemental Mapping Technique 17 2.5 Electron-Beam-Induced Thermal Effects 18 2.5.1 Energy Dissipation via Secondary Electron Emission 19 2.5.2 Radiative Energy Loss via Characteristic X-ray Emission 19 2.5.3 Energy Loss via Thermal Radiation 19 Chapter 3 Experimental Methods 21 3.1 Experimental Configuration and Sample Design 21 3.1.1 Research Objective and Energy Injection Mechanism 21 3.1.2 Device Architecture 21 3.1.3 Sample Types and Design 23 3.1.4 Design Strategy and Experimental Considerations 26 3.2 SEM Configuration and Electron Beam Power Calculation 26 3.2.1 SEM Operating Conditions 26 3.2.2 Wheatstone Bridge and Power Calculation 27 3.2.3 Temperature Coefficient Measurement Method 28 3.3 Mapping and Localized Measurement of ebeam–Induced Modulation 29 3.3.1 Scan Strategy and Resolution Settings 30 3.3.2 Localized and Mapping Measurements of Beam-Induced Responses 30 3.4 Calculation Methods for Thermal and Electrical Modulation 32 3.4.1 Thermal Modulation Calculation by thermal signal 33 3.4.2 Thermal Modulation Calculation by Fourier’s law 35 3.5 Electrical Modulation Calculation Method 36 3.5.1 Calculation of Device Voltage and Current 36 3.5.2 Calculation of Resistance Change 36 3.5.3 Modulation and Energy Calculation 37 3.6 Methods for Local Thermal Resistance Measurement 38 3.6.1 Method 1 – Simplified Electron Beam Heating Approach 38 3.6.2 Method 2 – Universal Three-Probe Method 39 Chapter 4 Result and Discussion 41 4.1 Measurement Setup and Signal Optimization 43 4.2 Thermal Modulation Behavior in Microstructures 46 4.2.1 Electron Beam Penetration and Energy Deposition 47 4.2.2 Localized Thermal Modulation in Short Beams 49 4.3 Temperature-Dependent Thermal Conductivity 54 4.4 Asymmetric Heat Flow under E-Beam Excitation 56 4.5 Thermal Resistance Profiling in Beams of Varying Position 58 4.5.1 Measurement Results for the 100 µm Device 59 4.5.2 Measurement of Thermal Resistance in the 1 mm Beam 61 4.5.3 Thermal Modulation in the 1 mm Beam Device 63 4.6 SEM-Based Mapping of Thermal and Electrical Signals 68 4.6.1 Validation of Spatial Resolution in High-Resolution Modulation Imaging 69 4.6.2 Electrical modulation mapping 72 4.7 Spectroscopic Detection of K/L Edges via Thermal Modulation 74 4.7.1 EPMA analysis for SiGe particle 75 4.7.2 Detection of Ge K-Edge in SiGe Particle via Thermal Modulation Mapping 78 4.7.3 Thermal modulation for characteristic edges 81 4.7.4 Ebeam Power Absorption at Characteristic Absorption Edges 84 Chapter 5 Conclusion and outlook 87 5.1 Summary of Key Findings 87 5.2 Future Direction 90 References 92	-
dc.language.iso	en	-
dc.subject	熱調製	-
dc.subject	電子微探針分析儀	-
dc.subject	特徵邊界	-
dc.subject	鎖相放大器	-
dc.subject	熱傳導係數	-
dc.subject	Thermal conductivity	-
dc.subject	Thermal modulation	-
dc.subject	X-ray spectroscopy	-
dc.subject	lock-in amplifier	-
dc.subject	nanowire	-
dc.title	熱調制顯微與能譜技術	zh_TW
dc.title	Thermal Modulation Microscopy and Spectroscopy	en
dc.type	Thesis	-
dc.date.schoolyear	114-1	-
dc.description.degree	碩士	-
dc.contributor.oralexamcommittee	張之威;江正天	zh_TW
dc.contributor.oralexamcommittee	Chih-Wei Chang;Cheng-Tien Chiang	en
dc.subject.keyword	熱調製,電子微探針分析儀特徵邊界鎖相放大器熱傳導係數	zh_TW
dc.subject.keyword	Thermal conductivity,Thermal modulationX-ray spectroscopylock-in amplifiernanowire	en
dc.relation.page	93	-
dc.identifier.doi	10.6342/NTU202600294	-
dc.rights.note	未授權	-
dc.date.accepted	2026-01-28	-
dc.contributor.author-college	重點科技研究學院	-
dc.contributor.author-dept	奈米工程與科學學位學程	-
dc.date.embargo-lift	N/A	-
顯示於系所單位：	奈米工程與科學學位學程

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