State Key Laboratory for Advanced Metals and Materials, University of Science and Technology Beijing, Beijing 100083, China.
Department of Microstructure Physics and Alloy Design, Max-Planck-Institut für Eisenforschung GmbH, Max-Planck-Straße, Düsseldorf 40237, Germany.
Nature. 2017 Apr 27;544(7651):460-464. doi: 10.1038/nature22032. Epub 2017 Apr 10.
Next-generation high-performance structural materials are required for lightweight design strategies and advanced energy applications. Maraging steels, combining a martensite matrix with nanoprecipitates, are a class of high-strength materials with the potential for matching these demands. Their outstanding strength originates from semi-coherent precipitates, which unavoidably exhibit a heterogeneous distribution that creates large coherency strains, which in turn may promote crack initiation under load. Here we report a counterintuitive strategy for the design of ultrastrong steel alloys by high-density nanoprecipitation with minimal lattice misfit. We found that these highly dispersed, fully coherent precipitates (that is, the crystal lattice of the precipitates is almost the same as that of the surrounding matrix), showing very low lattice misfit with the matrix and high anti-phase boundary energy, strengthen alloys without sacrificing ductility. Such low lattice misfit (0.03 ± 0.04 per cent) decreases the nucleation barrier for precipitation, thus enabling and stabilizing nanoprecipitates with an extremely high number density (more than 10 per cubic metre) and small size (about 2.7 ± 0.2 nanometres). The minimized elastic misfit strain around the particles does not contribute much to the dislocation interaction, which is typically needed for strength increase. Instead, our strengthening mechanism exploits the chemical ordering effect that creates backstresses (the forces opposing deformation) when precipitates are cut by dislocations. We create a class of steels, strengthened by Ni(Al,Fe) precipitates, with a strength of up to 2.2 gigapascals and good ductility (about 8.2 per cent). The chemical composition of the precipitates enables a substantial reduction in cost compared to conventional maraging steels owing to the replacement of the essential but high-cost alloying elements cobalt and titanium with inexpensive and lightweight aluminium. Strengthening of this class of steel alloy is based on minimal lattice misfit to achieve maximal precipitate dispersion and high cutting stress (the stress required for dislocations to cut through coherent precipitates and thus produce plastic deformation), and we envisage that this lattice misfit design concept may be applied to many other metallic alloys.
下一代高性能结构材料是实现轻量化设计策略和先进能源应用的必备条件。马氏体时效钢结合了马氏体基体和纳米析出物,是一类高强度材料,具有满足这些需求的潜力。它们的高强度源于半共格析出物,这些析出物不可避免地呈现出不均匀的分布,从而产生大的相干应变,这反过来可能会在负载下促进裂纹的萌生。在这里,我们报告了一种通过高密度纳米析出物实现超强度钢合金设计的反直觉策略,这种策略具有最小的晶格失配。我们发现,这些高度分散的、完全共格的析出物(即析出物的晶格几乎与周围基体相同),与基体的晶格失配非常小,反相界能非常高,在不牺牲延展性的情况下强化合金。如此小的晶格失配(0.03±0.04 百分比)降低了析出的形核势垒,从而能够稳定具有极高数密度(超过每立方米 10 以上)和小尺寸(约 2.7±0.2 纳米)的纳米析出物。颗粒周围的最小弹性失配应变对位错相互作用贡献不大,而位错相互作用通常是强度增加所必需的。相反,我们的强化机制利用了化学有序化效应,当析出物被位错切割时,会产生背应力(抵抗变形的力)。我们创造了一类通过 Ni(Al,Fe)析出物强化的钢,其强度高达 2.2 吉帕斯卡,具有良好的延展性(约 8.2 百分比)。与传统马氏体时效钢相比,由于用廉价且轻质的铝替代了必不可少但昂贵的钴和钛等合金元素,这些析出物的化学成分降低了成本。这种钢合金的强化是基于最小的晶格失配,以实现最大的析出物弥散度和高切割应力(位错穿过共格析出物产生塑性变形所需的应力),我们设想这种晶格失配设计理念可能适用于许多其他金属合金。
