固溶时间对Ti@(Al-Si-Ti)_(p)/A356复合材料组织及力学性能的影响

采用粉末触变成形技术制备了原位自生心-壳结构增强A356铝基复合材料,并研究了固溶时间对Ti@(Al-Si-Ti)_(p)/A356复合材料显微其组织及力学性能的影响。结果表明,随着固溶时间增加,初生α-Al相颗粒粗化长大;共晶Si相不断溶解,晶界上残余的共晶Si粗化、球状化;Al基体、Ti心部继续反应,增强体颗粒壳层发生相转变。复合材料在545℃固溶处理1 h时,力学性能达到峰值,其抗拉强度、屈服强度和伸长率分别为263.9 MPa、175.1 MPa、20%,比制备态复合材料分别提高了7.3%、21.4%和12.4%,维氏硬度也从59.3 HV提高到72.8 HV。

No basalt accumulation and segregation atop the 660-km discontinuity beneath the Sea of Okhotsk

Recent seismic evidence shows that basalt accumulation is widespread in the mantle transition zone(MTZ),yet its ubiquity or sporadic nature remains uncertain.To investigate this phenomenon further,we characterized the velocity structure across the 660-km discontinuity that separates the upper mantle from the lower mantle beneath the Sea of Okhotsk by modeling the waveform of the S660P phase,a downgoing S wave converting into a P wave at the 660-km interface.These waves were excited by two regional>410-km-deep events and were recorded by stations in central Asia.Our findings showed no need to introduce velocity anomalies at the base of the MTZ to explain the S660P waveforms because the IASP91 model adequately reproduced the waveforms.This finding indicates that the basalt accumulation has not affected the bottom of the MTZ in the study area.Instead,this discontinuity is primarily controlled by temperature or water content variations,or both.Thus,we argue that the basalt accumulation at the base of the MTZ is sporadic,not ubiquitous,reflecting its heterogeneous distribution.

p-Si/n-Ga_(2)O_(3)异质结制备与特性研究

本实验采用金属有机化学气相沉积(MOCVD)工艺,在p(111)型Si衬底上制备了p-Si/n-Ga_(2)O_(3)结构的PN结。通过X射线衍射仪、原子力显微镜等对样品进行了晶体结构、表面形貌、表面粗糙度等的表征分析;通过磁控溅射与蒸镀方法在样品上生长Ti/Au电极并进行I-V特性曲线、开启电压、开关电流比、反向饱和电流、理想因子、零偏压下的势垒高度等结特性测试,研究了掺杂浓度与薄膜厚度对PN结特性的影响,并对其原因进行了分析;通过二步生长法和缓冲层温度优化实验,减少了Si衬底与β-Ga_(2)O_(3)之间的晶格失配与热失配带来的影响,对薄膜与器件特性进行了优化。最终获得了表面粗糙度最低可达到4.21 nm的高质量n型β-Ga_(2)O_(3)薄膜,以及具有较低理想因子(42.1)的PN结。

SiC_(p)含量对SiC_(p)/Al-1.2Mg-0.6Si铝基复合材料组织和性能影响

采用粉末冶金法制备SiC_(p)/Al-1.2Mg-0.6Si铝基复合材料,分析了该复合材料的均匀性和界面结合情况,探讨了几种体积分数该复合材料的显微组织和性能变化。结果表明,SiC颗粒和基体之间的界面清晰平滑,界面结合良好,但随着热压温度的增加,SiC与基体间的微观缩孔和析出相逐渐增多。随着SiC颗粒含量的增加,材料的弹性模量、热导率显著提高,弯曲强度先升高后下降,而热膨胀系数逐渐降低。

低填充P-Si基阻燃体系协效阻燃PA66的制备及性能

尼龙66(PA66)作为一种广泛使用的工程塑料,因其优异的力学性能和加工性能而备受青睐。然而,PA66的可燃性限制了其在某些安全要求较高的应用领域的发展。为了解决这一问题,可通过构建P-Si基协效阻燃体系,对PA66进行熔融共混改性,以期提高其阻燃性能、力学性能及热稳定性。采用熔融共混法制备PA66复合材料,利用二乙基次磷酸铝(ADP)、次磷酸铝(AHP)及纳米二氧化硅(SiO2)构建多元协效阻燃体系,并系统研究了ADP/AHP/SiO2协效阻燃体系对PA66性能的影响,对PA66复合材料的阻燃性能、力学性能及热稳定性进行了综合评价。实验结果表明,ADP/AHP/SiO2协效阻燃体系显著提升了PA66的阻燃性能,当添加总量为9份时,PA66复合材料的阻燃等级达到V-0级别,极限氧指数高达34.3%。此外,PA66复合材料的拉伸性能也得到了显著提升,拉伸强度和拉伸弹性模量分别提高了27%和36%。热重测试显示,PA66复合材料的热稳定性也有明显改善。ADP/AHP/SiO2协效阻燃体系不仅显著提高了PA66的阻燃性能,还有效改善了其力学性能和热稳定性。该体系的引入为PA66的工程应用提供了有力支持,具有重要的实际应用价值和市场前景。

Numerical Analysis on the Effect of n-Si on Cu(In, Ga)Se2 Based Thin-Films for High-Performance Solar Cells by 1D-SCAPS

We report the performances of a chalcopyrite Cu(In, Ga)Se2 CIGS-based thin-film solar cell with a newly employed high conductive n-Si layer. The data analysis was performed with the help of the 1D-Solar Cell Capacitance Simulator (1D-SCAPS) software program. The new device structure is based on the CIGS layer as the absorber layer, n-Si as the high conductive layer, i-In2S3, and i-ZnO as the buffer and window layers, respectively. The optimum CIGS bandgap was determined first and used to simulate and analyze the cell performance throughout the experiment. This analysis revealed that the absorber layer’s optimum bandgap value has to be 1.4 eV to achieve maximum efficiency of 22.57%. Subsequently, output solar cell parameters were analyzed as a function of CIGS layer thickness, defect density, and the operating temperature with an optimized n-Si layer. The newly modeled device has a p-CIGS/n-Si/In2S3/Al-ZnO structure. The main objective was to improve the overall cell performance while optimizing the thickness of absorber layers, defect density, bandgap, and operating temperature with the newly employed optimized n-Si layer. The increase of absorber layer thickness from 0.2 - 2 µm showed an upward trend in the cell’s performance, while the increase of defect density and operating temperature showed a downward trend in solar cell performance. This study illustrates that the proposed cell structure shows higher cell performances and can be fabricated on the lab-scale and industrial levels.

(Mn,Fe)_(2)(P,Si)化合物的单晶生长及其磁性

Fe_(2)P型一级相变材料因其巨磁热效应和原材料丰富且低廉等特点,在室温磁制冷和磁热泵等新兴绿色环保技术领域具有良好的应用前景。在高能球磨和固相烧结法制备(Mn,Fe)_(2)(P,Si)多晶样品的基础上,通过助溶剂法生长(Mn,Fe)_(2)(P,Si)单晶,研究Fe_(2)P型(Mn,Fe)_(2)(P,Si)系列化合物的单晶生长工艺。利用扫描电镜(SEM)观察单晶微观形貌,用电子能谱(EDS)对单晶的化学成分进行定量分析,研究其化学成分对经过一级磁相变之后的微观组织结构的影响。结果表明,通过优化初始成分和制备工艺,可生长具有不同Mn∶Fe和P∶Si成分比例的单晶;发现Mn_(0.7)Fe_(1.31)P_(0.72)Si_(0.30)单晶在发生一级相变时的内应力最小,经过三次一级磁相变后仍保留原有形状。磁性测量结果表明,通过改变Si和Fe含量,可将一级相变引起的热滞从60 K降到10K左右,成功调控了(Mn,Fe)_(2)(P,Si)单晶的一级相变和微观组织结构。

P-LaCe复合变质对过共晶Al-25%Si合金的变质效果

文章分别采用1.0%LaCe、0.8%P以及1.0%LaCe-0.8%P复合变质对Al-25%Si合金进行变质处理,研究不同变质剂对Al-25%Si合金的变质效果。经变质处理后,Al-25%Si合金中的初晶硅都有着不同程度的细化作用,0.8%P的变质效果为最佳,初晶硅由未变质的粗大的五瓣星状及其他较复杂形状转变为细的多边形状和板片状,平均晶粒尺寸由150μm~200μm细化至30μm~50μm,共晶硅以长针状分布,分布密度明显降低。单纯加1.0%LaCe处理后,合金中初晶硅形态上无变化,平均晶粒尺寸略有减小,共晶硅发生明显变化,从长针状变为颗粒状或短棒状,尺寸大幅减小。P-LaCe复合变质需控制好二者的添加量的配比,否则易产生过变质现象,降低变质效果。力学性能测试结果表明,经变质处理后的Al-25%Si合金的抗拉强度与硬度均不同程度增加,以0.8%P变质后的合金力学性能为最佳,与金相组织细化程度相对应。

BCC Fe中P晶界偏析对拉伸变形行为影响的分子动力学研究

晶界是金属材料中重要的微观结构,并且晶界上的位错形核对材料变形起着至关重要的作用。本文通过分子动力学模拟研究了BCC Fe中对称倾侧晶界的位错形核机制和孪晶机制,分析了P的晶界偏析对位错变形行为的影响机理。对于(111)晶界体系,位错形核扩展主导拉伸变形行为。而对于(112)孪晶界体系,拉伸变形主要是由孪晶主导,体系发生BCC-FCC相变。针对5个对称倾侧晶界(旋转角为30°~160°)体系,在不同温度下(300 K和600 K)施加拉伸载荷,结果表明位错形核受晶界类型和温度影响。与300 K相比,600 K下体系强度降低,促进位错形核。同时,从原子微观结构、体系能量两个角度,研究P的晶界偏析对位错形核的影响机理。本文提供了晶界位错形核的原子机制,有助于理解P在BCC Fe中的偏析对晶界变形行为和力学性能的影响。

INTERGRANULAR CORROSION AND PHOSPHOR SEGREGATION AT GRAIN BOUNDAR1FS OF NON-SENSITIZED SUPERPURE AUSTENITIC STAINLESS STEEL 00Cr25Ni22Mo2N

The corrosion behaviour and mechanism of superpure austenitic stainless steel 00Cr25Ni22Mo2N in urea processing environment was studied using metallography,SEM, TEM,SIMS and AES techniques.The results show that the gas extraction tube made of non-sensitized 00Cr25Ni22Mo2N steel suffered intergranular corrosion.Corrosive media penetrated not only into the tube wall through grain boundaries but also expanded from the boundary towards the interior of the grain.Neither depletion of Cr nor precipitates were found at the grain boundaries.However,P(and Si)was segregated at the grain boundaries to a great extent.Semiquantitative calculation indicates that the P content at the grain boundaries is about 25 wt-%,three orders of magnitude higher than the content within the grain.Sugges- tion is made that the potential difference between the grain and its boundary due to the segre- gation results in the observed intergranular corrosion.

Segregations and desorptions of Ge atoms in nanocomposite Si_(1-x)Ge_x films during high-temperature annealing

Nanocomposite Si1-xGex films are deposited by dual-source jet-type inductively coupled plasma chemical vapor deposition （jet-ICPCVD）. The segregations and desorptions of Ge atoms, which dominate the structural evolutions of the films during high-temperature annealing, are investigated. When the annealing temperature （Ta） is 900℃, the nanocomposite Si1-xGex films are well crystallized, and nanocrystals （NCs） with the core-shell structure form in the films. After being annealed at 1000℃ （above the melting point of bulk Ge）, Ge atoms accumulate on the surfaces of Ge-rich films, whereas pits appear on films with lower Ge content, resulting from desorption. Meanwhile, voids are observed in the films. A cone-like structure involving the percolation of the homogeneous clusters and the crystallization of NCs enhances Ge segregation.

Segregation of P at Grain Boundary and Reverse Embrittlement of Cr-Mn-Si Steel

1.IntroductionPhosphorus causes remarkable decreaseof impact toughness due to its segregationon grain boundary[1,2].In this paper,theinfluence of P content on the reverse changeof P segregation and impact toughness ofmedium carbon Cr-Mn-Si steel at the samestrength level is reported.

p型“SE+PERC”双面太阳电池背面工艺对光伏组件PID效应的影响研究

基于p型“SE+PERC”双面太阳电池的背面工艺,针对背表面抛光状态、背面氧化铝薄膜厚度、背面膜层结构、背面氮化硅薄膜折射率几个因素对光伏组件电势诱导衰减(PID)效应的影响进行了研究。研究结果表明:1)背表面抛光状态越光滑,对应制备的光伏组件在PID测试后的输出功率损失率越小;2)背面氧化铝薄膜厚度为10 nm及以上时对应制备的光伏组件在PID测试后的输出功率损失率差异不大;3)背面膜层结构对PID效应存在影响,合理设计背面膜层结构可以有效抑制光伏组件PID效应;4)背面氮化硅薄膜折射率大于等于2.10时,对应制备的光伏组件在PID测试后的输出功率损失率降至2.00%以内且可以稳定保持在较低水平。研究结果可为p型“SE+PERC”双面太阳电池背面工艺优化提供指导方向。

Al-P中间合金对共晶和过共晶Al-Si合金的变质机制

探讨了Al—P中间合金对共晶及过共晶Al—Si合金的变质特点,P在Si相中的存在形式、分布规律及变质机制,实验表明,Al—P中间合金可有效地细化过共晶Al—Si合金中的初晶Si,使该合金的σb,20℃和δ20℃分别提高19.0％和125％。对共晶型Al—Si合金而言,Al—P中间合金可促使析出细小的初晶Si,获得过共晶型组织,并将针片状的共晶Si变为短杆状,从而使该材料的σb,20℃和σb,300℃分别提高11.1％和18.9％。Al—P中间合金加入到过共晶Al—Si合金中,P主要以AlP形式存在于初晶Si内部;加入到共晶Al—Si合金中的P分别以AlP和原子态P存在于Si相内。P对过共晶Al—Si合金变质是以AlP异质形核机理为主;而P对共晶Al—Si合金的变质是以AlP异质形核和原子态P影响Si相形态两种机制共同作用的结果。

非化学计量比MnFe(P，Si，Ge)合金在低场下的磁热效应

通过XRD和磁性测量对非化学计量比MnFe(P,Si,Ge)合金的相组成和磁性进行了研究.xRD分析表明。所有样品都具有Fe_2P型六角结构,主相为(Re,Mn)_2(P,Si,Ge),并存在少量的第二相(Fe,Mn)_3(Si,Ge).过量的Mn和Fe都会使合金的Curie温度降低,由343K(化学计量比)降低到294K(过量Mn)和286K(过量Fe);过量的Mn能减小热滞,而过量的Fe会使热滞增加;磁熵变也有所减小,在1.5T的磁场下,最大磁熵变由5.2J/(kg·K)(化学计量比)减小到4.9J/(kg·K)(过量Mn)和3.8J/(kg·K)(过量Fe).

P+RE变质对过共晶Al-Si合金组织的影响

采用P+RE对过共晶Al-Si合金进行复合变质。结果表明,P+RE复合变质对初晶硅和共晶硅均有很好的变质效果。五心瓣状初晶Si尺寸明显减小且棱角钝化,共晶Si由原来的长针状变为短杆状,微观组织得到明显的细化。同时也对P+RE的变质机理进行了论述。

P变质对不同冷速下过共晶压铸铝合金初晶Si的影响

以过共晶压铸铝合金为对象,研究了P变质对不同冷却速度下初晶Si组织的影响。发现P变质处理前后随冷却速度的增加,初晶Si尺寸减小的变化趋势十分相似,并且都存在一个明显的突变区域。对于不同冷却速度下合金组织的细化,P变质都有很好的促进作用。同一冷却速度下,P变质后细化效果可增加42.7%,在冷却速度很高(铸件厚度达到1mm)时,P变质对初晶Si仍然具有很好的细化作用。在快速凝固和P变质双重作用下,初晶Si组织得到更加明显的细化。Al-P中间合金是一种良好的过共晶压铸铝合金变质剂。

Al,Si,P掺杂对Ge在石墨烯上吸附的影响

利用基于密度泛函理论的第一性原理计算方法研究了Al、Si和P掺杂对Ge在石墨烯上吸附的影响.Ge原子在完整石墨烯上吸附的最稳定位置为桥位,Ge的吸附改变了石墨烯中C原子的电子自旋性质;Al、Si和P掺杂石墨烯使衬底C原子发生了移动,且Si,P原子掺杂比Al掺杂石墨烯容易;杂质类型对Ge在石墨烯上的吸附位置有较大的影响,Al、Si、P掺杂增强了Ge在石墨烯上的吸附,其中Al掺杂对Ge在石墨烯上吸附的影响最大,P掺杂次之,Si掺杂最小;Ge吸附Al掺杂体系和Si掺杂体系不具有磁性,Ge吸附P掺杂体系具有磁性.

TiO_2/n-Si/p-Si及n-PS/p-PS/Si的光伏特性

在抛光的p型单晶硅上通过扩散工艺制备pn结,采用此种硅片利用阳极腐蚀法制备多孔硅（PS）。用磁控溅射镀膜机在有pn结的单晶硅表面镀上一层TiO2纳米结构薄膜,并用表面光电压谱（SPS）研究了n-PS/p-PS/Si和TiO2/n-Si/p-Si的表面光伏特性。结果表明TiO2/n-Si/p-Si和n-PS/p-PS/Si的光伏效应比n-Si/p-Si在不同程度上有所提高。在300～600℃热处理温度范围内TiO2/n-Si/p-Si的光伏效应随温度的升高而增强,600～800℃范围内随温度的升高而降低。

铸造SiC_p/Al-Si复合材料中的“界面Si”行为

采用ＴＥＭ 研究了ＳｉＣ／ＡｌＳｉ 复合材料， 提出了“界面Ｓｉ”的概念。由于与增强体ＳｉＣ 不润湿， 初生α（Ａｌ） 相不在ＳｉＣ 颗粒上形核并对其发生排斥。（Ａｌ＋ Ｓｉ） 共晶体中的共晶领先相Ｓｉ 优先在ＳｉＣ表面上形核、长大， 形成界面Ｓｉ， 并形成大量ＳｉＣ／Ｓｉ 界面。ＳｉＣ／Ｓｉ 界面“干净”、平直， 结合紧密， 其中未发现任何界面相。在个别ＳｉＣ／Ａｌ 界面上析出了二次Ｓｉ。