空位团簇结构影响下金属性质的变化

V. Novikov, M. Levin, Vyacheslav Pevgov, V. Ulyanov
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引用次数: 0

摘要

给出了空位簇结构作用下a金属性能变化的实验结果。考虑了两种获得这种结构的技术途径。第一种是纳米粉末在高(高达5GPa)流体静压下的压实,例如镍纳米粉末(70nm)。二是高强度塑性变形[eⅱ= (102-104)sec-1] (НIPD)条件下,Al和Pb在“固液”边界上的结晶,转速高达2000 rpm。利用原子力显微镜(AFM)方法,在Al和Pb金属的结晶体积中检测到平均直径为39 nm和25 nm的空位簇管(VCT)。讨论了Al和Pb在团块结晶过程中高强度塑性变形(HIPD)过程中形成的以空位簇管形式在金属内部形成的新子结构的物理模型,以及该过程对上述金属的机械、磁性和超导性能的影响。高强度塑性变形(HIPD) [e ' = (102-104) sec-1]范围内铝、铅结晶过程中,在高速离心铸造机上采用特殊选择的金属结晶方式,创造特殊条件,实现动态(移位)再结晶的尺寸效应。离心结晶过程中的移位变形主要是由温度场从转子外围(相对于转子冷壁)向转子熔融中心部分的大倾斜引起的。金属已经冻结的部分(靠近转子壁外表面)和金属仍处于熔融状态的中心部分角速度的差异,导致结晶金属熔体凝固相发生高强度变形[e ' =(102-104)秒-1]。由于结晶相的晶粒尺寸最初约为数十纳米(约为晶体成核尺寸),因此在高应变速度位移下实现“纳米晶”固化金属的动态再结晶的尺寸效应成为可能。以这种方式形成的“非平衡空位”凝聚成空位簇,这些空位簇在离心力场中以向转子旋转中心伸出的空位形簇管的形式形成。与熔体中通常的金属结晶相比,该过程在远离平衡的条件下进行。这一过程可导致非平衡开放系统的高度有序非平衡状态的形成。讨论了Al和Pb合金离心过程中高流体静力压缩(高达5 GPa)和高强度塑性变形(HIPD)阶段金属空位团簇结构形成的物理模型。本文的结论是,熔体结晶阶段的高强度塑性变形(НIPD)在高稳态非平衡空位浓度背景下导致了新型元素结构的形成-空位簇管(VCT)。介绍了结构金属力学、磁性和超导性能变化的对比分析。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Metals Property Changes Under Effect of Vacancy-Cluster Structures
The experimental results analysis of a metals property changes under vacancy-cluster structure effects are shown. Two technological approaches of such structures obtaining are considered. The first is a nanopowders compaction under high (up to 5GPa) hydrostatic compression, on example of a Ni nanopowder (70nm). The second is the Al and Pb crystallization under the high-intensity plastic deformation [e¢ = (102-104) sec-1] (НIPD) conditions on the "solid-liquid" boundary in the centrifugal casting machine with rotary speed up to 2000 rpm. Using the method of atomic force microscopy (AFM), vacancy cluster tubes (VCT) with average diameters of 39 nm for Al and 25 nm for Pb have been detected in the crystallized volume of Al and Pb metals. Discussed the physical model of a new substructure formation within the metals in the form of vacancy cluster tubes, obtained in the process of high-intensive plastic deformation (HIPD) during the process of mass crystallization of Al and Pb and the changes in the mechanical, magnetic and superconducting properties of the above metals, which followed this process. During Al and Pb crystallization under high-intensive plastic deformation (HIPD) range about [e′ = (102–104) sec-1] with specially selected modes of metals crystallization in high-speed centrifugal casting machine the special conditions are being created to achieve the dimensional effect of dynamic (shifting) re-crystallization. Shifting deformation during centrifugal crystallization caused primarily by a large incline of the temperature field from the periphery (relative to the cold wall of the rotor) to the molten central part of the rotor. The difference in the angular velocities of the already-frozen part of the metal (adjacent to the outer surface of the rotor wall) and the central part, where the metal still remains in the molten state, leads to a high-intensity deformation [e′ = (102–104) sec-1] of the crystallized metal melt solidified phase. Since the grain sizes at the crystallized phase initially comprise around tens of nano-meters (approximately crystal nucleation size), it becomes possible to achieve the dimensional effect of the dynamic re-crystallization of a «nanocrystalline» solidified metal at high shift of strain velocities. The ≪non-equilibrium vacancies≫ formed this way condense into vacancy clusters, which are formed in the centrifugal force field in the form of vacancy-shaped cluster tubes stretched out to the center of rotation of the rotor. The process proceeds under conditions far from the equilibrium in comparison with the usual crystallization of the metal from the melt. Such processes can lead to the formation of highly ordered non-equilibrium statescharacteristic of non-equilibrium open systems. Discussed the physical model of a metals vacancy-cluster structures formation at high hydrostatic nanopowders compression (up to 5 GPa) and high-intensity plastic deformation (HIPD) at the stage of Al and Pb alloys mass crystallization during centrifugation. Conclusion of the article is that the high-intensity plastic deformation (НIPD) at the melt crystallization stage against a background of high stationary nonequilibrium vacancies concentration brings to the new type of the elements structure formation - vacancy cluster tubes (VCT). A comparative analysis of mechanical, magnetic and superconducting properties changes for structured metals introduced.
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