Zr_(55)Al_(10)Ni_(5)Cu_(30)非晶合金晶化相转变的价电子结构分析

基于EET理论,计算了F-Zr_(2)(Ni,Cu)和tI-Zr_(2)Cu及tI-Zr_(2)(Cu,Ni)相的价电子结构,用最强键键合力n1、结构单元总成键能力F和单位成键能力Fv分析了F-Zr_(2)Ni亚稳相向tI-Zr_(2)Cu型稳定相的转变过程。研究发现:F-Zr_(2)Ni的n1F-Zr_(2)Ni值比tI-Zr_(2)Cu的n1tl-Zr_(2)Cu值大115.36%,FF-Zr_(2)Niv值比tI-Zr_(2)Cu的FtI-Zr_(2)Cuv值大34.03%;F-Zr_(2)(Ni_(0.3),Cu_(0.7))的n1(F-Zr_(2)(Ni_(0.3),Cu_(0.7)))值比tI-Zr_(2)Cu的n1tl-Zr_(2)Cu值大0.36%,F(F-Zr_(2)(Ni_(0.3),Cu_(0.7)))v值比tI-Zr_(2)Cu的FF-Zr_(2)Niv值大1.25%;tI-Zr_(2)(Cu_(0.6),Ni_(0.4))的n1(tI-Zr_(2)(Cu_(0.6),Ni_(0.4)))值比F-Zr_(2)(Ni_(0.3),Cu_(0.7))的n1(F-Zr_(2)(Ni_(0.3),Cu_(0.7)))值大12.95%,F(tI-Zr_(2)(Cu_(0.6),Ni_(0.4)))v值比F-Zr_(2)(Ni_(0.3),Cu_(0.7))的Fv(F-Zr_(2)(Ni_(0.3),Cu_(0.7)))值大14.41%;从价电子结构角度看,F-Zr_(2)Ni不能直接转变为tI-Zr_(2)Cu,F-Zr_(2)(Ni,Cu)不易分解重构为tI-Zr_(2)Cu;F-Zr_(2)(Ni_(0.3),Cu_(0.7))可分解并转变为tI-Zr_(2)(Cu0.6,Ni0.4)。

试样温度对激光重熔Zr_(55)Cu_(30)Al_(10)Ni_5块体非晶合金晶化的影响

分别对在液N冷却、液Ar冷却、置于室温环境和加热到473 K条件下的Zr_(55)Cu_(30)Al_(10)Ni_5非晶合金试样进行脉冲激光重熔实验,以研究试样温度对激光重熔非晶合金晶化的影响.结果显示.在采用有、无Ar气侧吹的情况下基材温度,特别是基材温度较低时,对激光重熔块体非晶合金晶化的影响规律明显不同.激光重熔实验中,无Ar气侧吹时,对在液Ar冷却和置于室温环境下的试样,激光重熔后热影响区的晶化程度类似.在液Ar冷却下的试样熔池较深.对于加热到473 K的试样,热影响区的晶化程度最为严重,且熔池最深.激光重熔实验中采用Ar气侧吹时,与室温环境的试样相比,液N冷却对于激光重熔非晶合金的晶化有明显的抑制作用.试样温度对非晶合金晶化的影响源于:一、试样本身的温度越低,热影响区的冷速越快,晶化越少;二、试样周围的气氛温度越低,激光重熔过程中,等离子体对激光的屏蔽效应也越小,实际能量输入越高,晶化越严重.有Ar气侧吹时,气氛温度为侧吹气体的温度,所以试样温度较低,晶化较少.在没有Ar气侧吹时,气氛温度接近于试样温度,上述2个因素同时作用,导致试样温度对晶化的影响规律非单调变化.

退火对Zr_(55)Al_(10)Ni_(5)Cu_(30)非晶合金晶化过程及压缩性能的影响

通过差示扫描量热法、X射线衍射和压缩性能测试等研究了退火对Zr_(55)Al_(10)Ni_(5)Cu_(30)非晶合金晶化过程和压缩性能的影响。结果表明:Zr_(55)Al_(10)Ni_(5)Cu_(30)非晶合金的玻璃转变温度和晶化行为与升温速率有关,随着升温速率的增加,玻璃转变温度T_(g)、初始晶化温度T_(x)、第一放热峰温度T_(p1)和第二放热峰温度T_(p2)均有所增加。Zr_(55)Al_(10)Ni_(5)Cu_(30)非晶合金在T_(g)以下的温度退火时,合金处于非晶态。合金在过冷液相区加热并保温足够的时间将发生相分离或晶化现象。F-Zr_(2)Ni和tP-AlZr相的析出与退火温度和保温时间有关,而tI-Zr_(2)Cu相只会在高于T_(p2)温度析出。当析出F-Zr_(2)Ni晶化相时,Zr_(55)Al_(10)Ni_(5)Cu_(30)非晶合金的抗压强度大幅减小,当析出tI-Zr_(2)Cu晶化相时,合金的抗压强度比析出F-Zr_(2)Ni晶化相时有所提高,但仍远小于铸态合金。

Zr_(55)Al_(10)Ni_(5)Cu_(30)amorphous alloy film prepared by magnetron sputtering method

In this work,amorphous Zr_(55)Al_(10)Ni_(5)Cu_(30)alloy thin film was prepared on D36 steel substrate by magnetron sputtering method.The film was characterized by scanning electron microscopy(SEM),X-ray diffraction(XRD),atomic force microscopy(AFM),hardness tester and nano indentation.Corrosion behavior of the film was investigated in 3.5%NaCl aqueous solutions by an electrochemical method.At room temperature,the amorphous alloy film was formed completely after sputtering for 5 h.The surface morphology of the amorphous alloy film was uniform and smooth.Formation of the amorphous alloy film improved the microhardness and corrosion resistance of the D36 substrate.The amorphous alloy film(prepared at room temperature for 5 h)exhibited good adhesion strength with the substrate.The as-sputtered sample exhibited a crevice corrosion trend when the sputtering time was too short(1 h)or too long(10 h).