亚碱基

The subcarbide of titanium is formed under high-pressure conditions in the steel manufacturing process.
钛的亚碳化物是在钢铁制造过程中高压条件下形成的。
The study on subcarbide formation kinetics is crucial for optimizing the heat treatment process of alloy steels.
对亚碳化物形成动力学的研究对于优化合金钢热处理过程至关重要。
In powder metallurgy, the control of subcarbide distribution affects the mechanical properties of the final product.
在粉末冶金中，控制亚碳化物的分布影响最终产品的机械性能。
The microstructure of the subcarbide phase influences the wear resistance of the tool materials.
亚碳化物相的微观结构影响刀具材料的耐磨性。
By adjusting the alloy composition, the formation of unwanted subcarbides can be minimized in high-carbon steels.
通过调整合金成分，可以最小化高碳钢中不需要的亚碳化物的形成。
The subcarbide particles act as strengthening phases in the matrix of the metal alloy.
亚碳化物颗粒作为强化相存在于金属合金的基体中。
The use of vacuum furnaces has reduced the likelihood of subcarbide formation during steel processing.
使用真空炉减少了钢加工过程中亚碳化物形成的可能。
Research indicates that subcarbide precipitation occurs during the cooling stage after high-temperature deformation.
研究表明，亚碳化物沉淀发生在高温变形后的冷却阶段。
Special heat treatment processes can dissolve pre-formed subcarbides to improve the ductility of the material.
特殊的热处理工艺可以溶解预先形成的亚碳化物，以提高材料的延展性。
The presence of subcarbides can alter the magnetic properties of certain steel alloys, affecting their application in magnetic components.
亚碳化物的存在可以改变某些钢合金的磁性，影响其在磁性部件中的应用。