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    Title: 單晶二維凡得瓦 Fe3GeTe2的電流沿不同晶格軸向電性量測
    Electrical measurements of two-dimensional van der Waals Fe3GeTe2 single crystals with current along different crystal axes
    Authors: 張仁豪
    Jhang, Ren-Hao
    Contributors: 李尚凡
    Lee, Shang-Fan
    張仁豪
    Jhang, Ren-Hao
    Keywords: 二維磁性材料
    磁阻
    異常霍爾效應
    2D magnetic material
    Fe3GeTe2
    Magnetoresistance
    Anomalous hall effect
    Date: 2023
    Issue Date: 2023-09-01 16:28:53 (UTC+8)
    Abstract: 二維凡得瓦鐵磁材料Fe_3 GeTe_2(FGT)具有高居禮溫度、強垂直異向性、金屬導體特性和自旋軌道耦合等優良的應用性質。因此,本實驗使用電傳輸方法研究FGT薄膜的基本電性與磁性,基於相關文獻的理論預測,嘗試藉由改變電流密度改變FGT薄膜磁性。另外,由於相關文獻報導FGT凡得瓦層間具有反鐵磁相與鐵磁相的競爭,因此本實驗也對單晶FGT不同晶格軸向電阻、磁阻進行量測,以探討其導電機制是否有自旋相關性。本實驗所使用的單晶FGT塊材由化學氣相傳輸法(Chemical Vapor Transport, CVT)生長。使用傳統的機械剝離(Mechanical Exfoliation)方法製備FGT薄膜,並使用微影、電子束和濺鍍等製程方法在薄膜表面製作電極,由於FGT薄膜表面存在氧化問題,因此採用離子研磨的方式,去除薄膜與電極間的氧化層。此外,為了能在單晶FGT各晶格軸向接上電極,本實驗使用雙束聚焦離子束(Dual beam focus ion beam)來製備樣品。本實驗使用四點量測方法成功測得FGT薄膜的基本磁阻、異常霍爾效應,數據顯示,FGT薄膜具有很強的垂直異向性。另外本實驗也通過改變電流密度來增加電流誘導的自旋軌道轉矩來傾斜FGT的磁矩。為了減少電流焦耳熱效應的影響,本實驗使用脈衝電流進行實驗。然而,根據數據顯示,脈衝電流仍無法有較排除熱效應。在單晶FGT塊材的電性量測中,我們發現在晶格C軸方向電阻率除了在居禮溫度(210K)附近發生相變化外,還在約80K時出現了相變化,且在不同的晶格軸向的各相異性磁阻有類似的表現行為。電阻率隨溫度的變化關係中,C軸方向電阻率約是A軸(凡得瓦層面內)電阻率的4到5倍。
    Fe3GeTe2 (FGT) is a two-dimensional van der Waals ferromagnetic material known for its high Curie temperature, strong perpendicular magnetic anisotropy, metallic conductivity, and spin-orbit coupling. In this study, we employed electrical transport measurements to investigate the fundamental electric and magnetic properties of FGT thin films. Building upon theoretical predictions from relevant literature, we attempted to modulate the magnetic properties of FGT films by varying the current density. Additionally, due to the reported competition between antiferromagnetic and ferromagnetic phases within the van der Waals layers of FGT, we measured the electrical resistance and magnetoresistance along different crystallographic axes of single-crystal FGT to explore potential spin-related conduction mechanisms. The single-crystal FGT samples used in this experiment were grown using the chemical vapor transport (CVT) method. FGT thin films were prepared through conventional mechanical exfoliation, and electrode patterns were fabricated on the film surface using techniques such as photolithography or electron beam lithography and followed by sputtering deposition. To address the oxidation issue on the FGT film surface, ion milling was employed to remove the oxide layer between the film and the electrodes. Moreover, to attach electrodes to different crystallographic axes of the single-crystal FGT, a dual-beam focused ion beam system was utilized for sample preparation. Using the four-point measurement method, we successfully measured the basic magnetoresistance and anomalous Hall voltage curves of the FGT thin films, demonstrating a pronounced out-of-plane anisotropy. Furthermore, by increasing the current-induced spin-orbit torque through the manipulation of current density, we were able to incline the magnetization of FGT. To mitigate the effects of Joule heating, pulsed current was employed in the experiments. However, the data indicated that even with pulsed current, the thermal effects could not be fully eliminated. In the electrical characterization of single-crystal FGT, we observed a phase transition in the resistivity along the crystallographic C-axis near the Curie temperature (210 K) and at approximately 80 K. Additionally, similar behaviors were observed in the magnetoresistance of different crystallographic axes, indicating distinct phase transitions. Depending on the temperature, the C-axis resistivity is about 4 to 5 times of the in-plane resistivity.
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    Description: 碩士
    國立政治大學
    應用物理研究所
    110755009
    Source URI: http://thesis.lib.nccu.edu.tw/record/#G0110755009
    Data Type: thesis
    Appears in Collections:[應用物理研究所 ] 學位論文

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