Microstructural characterization of aluminum (Al) 6063 nanocomposites plays a vital role in the field of materials engineering. Many of the earlier research studies showed that the evolution of aluminum 6063 stabilized the application in various fields of engineering and sciences. The present research focused on probing aluminum 6063 nanocomposites using X-ray diffraction (XRD), transmission electron microscopy (TEM) and scanning electron microscopy photogrammetry (SEM). Compositions of aluminum 6063 and aluminum 6063 with 0.5 wt% γ-aluminum oxide (γ-Al₂O₃), 1 wt% γ-aluminum oxide, 2 wt% γ-aluminum oxide and 3 wt% γ-aluminum oxide were prepared and investigated for microstructural characterization. In XRD, SEM and TEM, the nanopowder particles form apparently bonds and their crystallographic structures were identified. Instead of chemical reactions, nanoparticles implicated the improvements in higher fracture toughness and shown in SEM fractograph of aluminum 6063 + 2 wt% γ-aluminum oxide than other compositions. In the SEM fractograph of aluminum 6063 + 3 wt% γ-aluminum oxide, the nanoparticles were widely spread and showed higher fracture toughness.

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铝6063合金纳米复合材料的微观结构表征

铝（Al）6063纳米复合材料的微观结构表征在材料工程领域起着至关重要的作用。许多早期的研究表明，铝6063的发展稳定了其在工程和科学各个领域的应用。本研究的重点是使用X射线衍射（XRD），透射电子显微镜（TEM）和扫描电子显微镜摄影测量（SEM）探测铝6063纳米复合材料。的铝6063和铝6063与0.5重量％的氧化γ -铝组合物（在γ-Al ₂ ö ₃），制备1重量％的γ-氧化铝，2重量％的γ-氧化铝和3重量％的γ-氧化铝并进行显微结构表征研究。在XRD，SEM和TEM中，纳米粉末颗粒形成明显的键并鉴定其晶体结构。代替化学反应，纳米颗粒暗示了更高的断裂韧性的改善，并且在SEM分数图中显示铝6063 + 2 wt％的γ-氧化铝比其他组合物更好。在铝6063 + 3 wt％γ-氧化铝的SEM形貌图中，纳米粒子广泛散布并显示出较高的断裂韧性。