材料学科“论文写作与学术规范”课程思政建设实践与探索

课程思政建设是高校实现“三全育人”、落实立德树人根本任务的基本途径。“论文写作与学术规范(材料学科)”旨在系统地培养研究生的文献检索、阅读,论文写作与发表,开题报告、创新项目的撰写与答辩等能力。将课程思政融入课程教学实践,需要深入挖掘兼具材料学科与思想政治教育内涵的思政元素,通过采用引导式、研讨式、实践式、案例式等教学方法,培育学生的成长型思维与批判性思维,使其养成严谨的科学态度,并筑牢科研诚信底线,最终促进专业教学与思政教育同向同行,提高研究生培养质量。

铷及含铷材料的性能与应用研究进展

铷(Rb)是一种活泼的碱金属,过去由于铷的特性及成本原因,铷及其化合物的制备技术、应用领域均受到极大限制。随着我国铷矿的不断发掘和铷提取技术的进步,铷资源的开发与利用越来越受到人们的关注。综述铷的基本物理性能、铷二元合金与铷化合物的基本晶体学参数以及含铷材料的最新应用及研究进展,包括在能源、非线性光学晶体、催化、医药、焊料、特种玻璃和铁磁材料等方面的应用进展,并对铷今后的发展方向进行展望。

牙科光固化复合树脂材料的性能与展望

牙科光固化复合树脂具有色泽美观,强度高,临床操作方便,粘结固位效果好等优点,在牙科修复领域引起了广泛关注。该复合材料是由树脂基体、无机填料和光引发体系组成的,原料混合后经特定波长的可见光照射即可固化。牙科光固化复合树脂虽然已在临床上得到了应用,但在性能方面仍然存在某些不足之处,所以如何进一步提高其性能成为目前研究的热点之一。该文作者综述了树脂基体、无机填料和光引发剂的研究情况,对光固化复合树脂的力学性能、聚合度、吸水性和溶解性等性能及其影响因素进行了评述,并对今后的研究进行了展望。

Synthesis of platy potassium magnesium titanate and its application in removal of copper ions from aqueous solution

Platy potassium magnesium titanate (K0.8Mg0.4Ti1.6O4, KMTO) was synthesized by a flux method. The potential application of KMTO in removing copper ions from water pollutants was investigated. The crystal phases of specimens were identified by XRD. The morphology and structural information were characterized by SEM and TEM. The adsorption behavior under different conditions was investigated, including different pH values and different initial copper ion concentrations. The results show that the maximum adsorption capacity of Cu(II) ions is 290.697 mg/g, and almost 99.9% of Cu(II) ions can be removed, which is much higher than that of other sorbents reported. The kinetics of KMTO for the adsorption of Cu(II)ions was studied and the best fit can be obtained by the pseudo-second-order model. Adsorption isothermal data can be well interpreted by the Freundlich equation (R2=0.991). In conclusion, this study highlights that KMTO is a potential material for the efficient removal of heavy metal ions in polluted water. It also opens up a new opportunity for the applications of platy KMTO.

羟基磷灰石／氟金云母复合的生物玻璃陶瓷的力学性能

通过粉末冶金方法制备羟基磷灰石玻璃/氟金云母生物医用玻璃陶瓷材料。利用力学性能检测、显微观察和相成分分析等手段,研究烧结温度以及玻璃相含量对材料抗弯强度、断裂韧性和硬度等力学性能的影响。结果表明:随着烧结温度的升高,材料的致密度不断提高,力学性能也得到改善,对于含80%氟金云母的玻璃陶瓷而言,抗弯强度从1000℃的55.1MPa,提高到1100℃的120.1MPa。随着玻璃陶瓷中氟金云母的增加,材料的抗弯强度、弹性模量、断裂韧性都有所提高。当氟金云母的含量达到80%时,得到的玻璃陶瓷复合材料的力学性能最佳。组分对HA/FG生物医用玻璃陶瓷力学性能的影响主要归因于其对材料致密度、相组成和结晶度的作用。

生物玻璃填充牙科复合树脂材料的制备及其性能

通过光固化的方法制备以磷灰石玻璃陶瓷和气相二氧化硅为无机填料的牙科复合树脂。采用扫描电镜/能谱仪(SEM/EDS)对复合材料的微观形貌进行分析,测量复合材料的三点抗弯强度。采用体外模拟体液(Simulated body fluid,SBF)浸泡法测试材料的生物活性。研究结果表明:材料的抗弯强度达到(137±10)MPa,能够满足牙齿修复的力学性能要求;材料在SBF中浸泡3d后,在表面形成矿化的碳酸磷灰石晶体层,表明材料具有较强的生物活性,可加快该材料植入人体后与骨的结合,并有利于龋齿的修复愈合。

骨、齿用可加工生物活性玻璃陶瓷的研究

为了获得良好的可加工性和生物活性,通过熔铸法制备了“卷心菜”状的云母/氟磷灰石玻璃陶瓷,该材料有望用于人体骨、牙齿的替代和修复。采用差热分析(DTA)、X射线衍射(XRD)和扫描电镜(SEM)对材料的相组成、微观形貌等进行了研究。研究表明,随着原料中CaO和P2O5成分的增加,材料结晶温度提高,材料中氟磷灰石的相对含量增加。由于K2O的添加,云母和氟磷灰石在一个较宽的温度范围里同时从玻璃中析出。球形氟磷灰石晶体均匀的分布在相互交错的“卷心菜”状云母晶体表面。

铅对铜基固体自润滑材料的润滑机理

以固溶强化的铜锡合金为基体,以石墨和铅作为固体润滑剂,采用粉末冶金方法制备高速、重载条件用新型固体自润滑材料,研究铅对材料的高温力学性能和摩擦学行为的影响,通过分析摩擦表面和亚表面的微观形貌与结构探讨铅与石墨的协同润滑机理。结果表明:在铜石墨材料中添加铅,可显著提高材料的硬度和室温拉伸强度和300℃以下的高温压缩强度,Cu-9Sn-9Pb-10C在300℃的高温压缩强度为215.3 MPa;并可显著提高铜石墨材料在高速、重载条件下的摩擦稳定性,并略微降低平均摩擦因数。

铅对铜基固体自润滑材料的润滑机理

以固溶强化的铜锡合金作为基体,以石墨和铅作为固体润滑剂,采用粉末冶金方法制备高速、重载条件用新型固体自润滑材料,研究铅对材料的高温力学性能和摩擦学行为的影响,通过分析摩擦表面和亚表面的微观形貌与结构探讨铅与石墨的协同润滑机理。结果表明:在铜-石墨材料中添加铅可显著提高材料的硬度和室温拉伸强度;铅的添加可提高铜-石墨材料300℃以下的高温压缩强度,Cu-9Sn-9Pb-10C在300℃的高温压缩强度为215.3 MPa;添加铅可显著提高铜-石墨材料在高速、重载条件下的摩擦稳定性,并略微降低平均摩擦因数。

电子束选区熔化制备纯钼块体的组织与性能

采用电子束选区熔化技术制备纯钼块体,采用化学分析法、金相显微镜、分析天平及显微硬度计对纯钼块体的杂质元素含量、显微组织、密度和显微硬度进行测试。结果表明:采用电子束选区熔化成形技术制备的纯钼块体中C、O、N和H等杂质元素增量小于0.001%。一次熔化成形的纯钼块体显微组织中,沿沉积方向呈粗大柱状晶,并且沿晶界存在少量微裂纹。而通过二次熔化工艺,可以细化晶粒,抑制微裂纹生长。较优的电子束二次选区熔化成形工艺为:一次熔化电流12 mA、熔化速度0.6 m/s;二次熔化电流12 mA,熔化速度0.89 m/s。该工艺下成形的纯钼块体致密度达99%以上(密度(10.15±0.13)g/cm^3),硬度(HV0.2)在185~200之间,无明显各向异性。

间接3D打印制备Ti/HAp复合材料的结构与性能

采用离子掺杂改性的方式制备不同铷(Rb)含量的羟基磷灰石(Rb-Hydroxyapatite,Rb-HAp)粉末,然后用间接3D打印法制备Ti/Rb-HAp复合材料,对该材料的形貌和物相组成进行分析,测定材料的力学性能,并通过体外细胞培养和细胞增殖与分化实验,研究材料的生物学性能。结果表明:Ti/Rb-HAp复合材料的孔隙率较高,多孔结构有利于新骨组织向内生长和体液的传输。Rb的加入可提高Ti/HAp复合材料的抗弯强度和抗压强度,并且抗压强度随Rb含量增加而小幅提高。与纯Ti相比,Ti/Rb-HAp复合材料可促进MG-63细胞的增殖和ALP活性,具有良好的细胞相容性。浸泡在模拟体液中,Ti/Rb-HAp复合材料表面形成致密的磷灰石层,表明该材料具有优异的生物活性。

放电等离子烧结钛基磷酸三钙陶瓷复合材料的力学性能与生物活性

采用放电等离子烧结法制备钛基磷酸三钙(Ti/α-TCP)复合材料,利用扫描电镜(SEM),能谱分析仪(EDS)和X射线衍射仪(XRD)对该材料的组织结构与界面反应进行观察与分析,并测试其抗压强度与生物活性,研究烧结温度与钛含量对Ti/TCP复合材料组织与性能的影响。结果表明:烧结温度在900℃以上时,Ti与α-TCP界面发生反应;增加钛含量有利于提高复合材料的强度。在Ti/α-TCP混合粉末中添加钛网作为骨架时,界面反应更复杂,并且温度越高,反应产物越多,当烧结温度达到1 100℃时,生成Ti的氧化物以及TixPy和CaTiO_3。在900℃烧结的70Ti/α-TCP/钛网复合材料抗压强度最高,达到590 MPa,浸入模拟体液中14天后表面形成一层厚厚的磷灰石,该材料作为骨植入替换材料具有很大的应用价值。

羟基磷灰石在传感领域应用的研究进展

传感器具有使用便捷、快速、灵敏等优点,在多种检测领域都具有巨大的潜力。羟基磷灰石(Hydroxyapatite,Ca_(10)(PO_(4))_(6)(OH)_(2),HAp)是脊椎动物骨骼、牙齿的主要无机成分,被广泛应用于生物医用材料领域。近年来,羟基磷灰石凭借独特的三维网状结构、良好的稳定性、优异的吸附性与离子交换性,被广泛用作传感材料,展示出巨大的潜力。由于导电能力与力学性能的制约,纯羟基磷灰石单独使用时效果不佳,为了进一步提高其综合性能,研究者们主要尝试对其进行离子(如Ag^(+)、Fe^(2+)、Pb^(2+)等)掺杂改性,或与其他材料(如石墨烯、碳纳米管、导电高分子、生物酶等)制备成复合材料,在提高灵敏度与稳定性、降低检测限等方面取得了一定的进步。与其他气体相比,羟基磷灰石及其复合物对氨气和醇类气体具有更佳的传感性能,可以实现室温下对较低浓度有毒有害气体的准确检测。得益于良好的离子交换性,羟基磷灰石修饰的传感电极可用于检测Pb^(2+)、Cu^(2+)、Hg^(2+)、As^(3+)、Cd^(2+)等多种重金属离子,适用于环保、医疗等领域。羟基磷灰石还可用于检测生物质(包括尿酸、葡萄糖、左旋多巴等10余种),而若作为生物酶的载体,可以实现对特定物质的特异检测,具有良好的选择性。羟基磷灰石还可作为湿敏传感材料,通过掺杂金属离子改性提高导电性能,是改善其湿敏性能的有效途径。另外,羟基磷灰石在光、磁、热传感方面的研究也有报道。本文首先简单介绍了HAp的基本结构、性能和制备方法,然后重点综述了HAp及其复合材料在气体传感、离子传感、生物传感以及湿度传感领域的研究进展,并对其未来研究方向进行了展望。

冷喷涂铜基金刚石复合涂层的结构与性能

钛合金因高比强度广泛应用于航空航天领域,但滑动摩擦性能较差,严重影响相关构件的寿命。表面改性是改善钛合金摩擦行为的常用手段,金属基金刚石复合涂层是其中一个重要研究方向。本文采用喷雾造粒结合冷喷涂在TC18合金表面制备致密的铜基金刚石复合涂层,研究复合粉末的冷喷涂沉积原理以及涂层热处理前后的微观结构与力学性能。结果表明,喷雾干燥制备的金刚石/铜复合粉末达到冷喷涂工艺要求;通过冷喷涂沉积,金刚石弥散分布在涂层中,质量分数为0.74%,且未发生损伤与石墨化;冷喷涂态金刚石/铜涂层具有优异的电导率和较高的硬度;涂层磨损形式为剪切断裂和剥离;600℃热处理后复合涂层硬度(HV)降低至95.8,导电率提升至89.3%IACS,涂层的摩擦行为得到改善,磨损率降低41%。

黑磷烯尺寸对黑磷烯/羟基磷灰石混合物气敏性能的影响

采用水热法制备短棒状羟基磷灰石(HA),通过液相剥离法制备黑磷烯(black phosphorene,BP),并采用不同的离心速率分离出具有不同尺寸的BP。制备BP质量分数为7.0%的BP/HA混合物,用X射线衍射仪、扫描电镜、透射电镜、原子力显微镜和拉曼光谱对混合物的物相组成、微观形貌和结构进行表征,同时使用气体传感系统研究纯HA以及含有不同尺寸BP的BP/HA混合物的气体传感特性。结果表明,加入BP可显著提高HA对氨气的响应,BP的尺寸越小,对HA气敏性能的提升越大。其中BP-10000/HA对浓度(气敏实验所用空气中氨气的体积分数)为100×10^(-6)的氨气的响应高达58.7%,当氨气浓度上升到1 000×10^(-6)后,响应高达98.3%。BP尺寸越小,气敏性能越好,可能是由于具有更大的比表面积,因而具备更多的活性位点。总之,BP可显著提升HA的气敏性能,BP/HA混合物是一种很有前途的室温气敏材料。

魔芋葡甘聚糖/纳米SiO_2复合涂膜配方及其对芒果贮藏品质的影响

以桂七芒果为材料,以魔芋葡甘聚糖、纳米二氧化硅为涂膜基质,采用3因素3水平正交试验,通过因子分析分析不同处理对芒果的色差、失重、硬度、可溶性固形物含量、pH和VC含量的影响,得出25℃条件下,对采后芒果保鲜效果良好的涂膜配方:魔芋葡甘聚糖8 g/L、纳米SiO_26 g/L、甘油4 g/L。该配方有效延迟了芒果的呼吸跃变,在一定程度上减少了芒果果皮色泽的变化,抑制了果皮褐变的发生,使失重率维持在10%以下,芒果果实硬度维持在0.05 MPa以上,可溶性固形物含量、pH和VC含量在贮藏后期仍然维持较高含量。

Rubidium-modified bioactive glass-ceramics with hydroxyapatite crystals for bone regeneration

In order to study the influence of rubidium(Rb)addition on the phase composition,microstructure,mechanical properties and cell response of bioactive glass-ceramics,CaO−SiO2−Na2O−B2O3−MgO−ZnO−P2O5 glass system was designed with and without addition of Rb.The results show that hydroxyapatite(HA)and Mg−whitelockite(Ca18Mg2H2(PO4)14)crystalline phases are formed in the glass matrix without Rb.After the addition of Rb,only HA phase is detected.The grain size of the crystals in the glass-ceramics is larger with the addition of Rb than that of samples without Rb.Rb addition can improve the bending strength of glass-ceramics.The cultivation of human bone marrow mesenchymal stem cells(hBMSCs)on Rb-containing glass-ceramics demonstrates enhanced cell adhesion,proliferation and ALP activity.In conclusion,Rb-modified glass-ceramics exhibit good mechanical property,excellent bioactivity and biocompatibility,which have potential for bone regeneration application.

Crack propagation behavior of inhomogeneous laminated Ti-Nb metal-metal composite

In order to investigate the real-time cracking behavior of each component of a composite with strong interfacial bonding among lamellae, Ti-18 Nb(at.%) composite was prepared by spark plasma sintering(SPS), followed by hot-rolling, annealing, and quenching. The microstructure and mechanical properties were characterized by scanning electron microscopy(SEM), energy dispersive spectroscopy(EDS), micro-region X-ray diffractometry(MRXRD), nanoindentation, and in-situ scanning electron microscopy tensile testing. The results show that the Ti-18 Nb consists of Ti-enriched, diffusion and Nb-enriched zones, and the sharp Nb gradient across different zones leads to inhomogeneous distribution of phase and mechanical properties. A remarkable finding is that the diffusion zones not only enable the cooperative deformation between the brittle Ti-enriched zones and the ductile Nb-enriched zones but also act as the crack-arresters to prevent the local cracks in the Ti-enriched zones from further propagating across the composite.

Preparation of tricalcium silicate and investigation of hydrated cement

Tricalcium silicate cement(TSC)has been widely used in dental materials because of its self-setting behavior,good bioactivity,biocompatibility,osteoinductivity,and antibacterial effect.Tricalcium silicate(C3S)powder was prepared by Pechini technique with a calcining temperature of 1300℃ for 3 h.The influence of liquid/powder(L/P)rate on the setting time and the mechanical property of TSC was studied.Characterization methods including XRD,FTIR,SEM-EDS,TEM,and ICP-AES were utilized to study the properties of C3S powder and its hydrated cement.The bioactivity and biocompatibility of the cement were investigated by soaking test and cell culture,respectively.The results show that the L/P rate plays an important role in the setting time and the compressive strength of TSC.The surface of TSC was covered by hydroxyapatite deposition during the immersion experiment and the cells attachment on the surface of TSC was well,which indicated that TSC has good bioactivity and biocompatibility.In addition,TSC has excellent antibacterial properties against Staphylococcus aureus.In conclusion,TSC is a promising candidate for root canal filling materials.

Room temperature gas sensor based on tube-like hydroxyapatite modified with gold nanoparticles

The main goal of this work is to explore the possibility of using Au-modified hydroxyapatite(HA) as a potential sensor material. Tube-like HA structure was fabricated with the aid of a Nafion N-117 cation exchange membrane and gold(Au) nanoparticles were added by a hydrothermal method. The morphology, structure and composition were characterized by scanning electron microscopy(SEM), transmission electron microscopy(TEM), X-ray diffraction(XRD), and X-ray photoelectron spectroscopy(XPS). The gas sensing properties were also investigated. Results show that Au nanoparticles are dispersed into the HA powder, which is tube-like, with rough inner and outer surfaces. Compared with pure HA, Au-modified HA exhibits improved sensing properties for NH_3. 5%(mass fraction) Au-modified HA shows the highest response with relatively short response/recovery time. The response is up to 79.2% when the corresponding sensor is exposed to 200×10^(-6) NH_3 at room temperature, and the response time and recovery time are 20 s and 25 s, respectively. For lower concentration, like 50×10^(-6), the response is still up to 70.8%. Good selectivity and repeatability are also observed. The sensing mechanism of high response and selectivity for NH_3 gas was also discussed. These results suggest that Au-HA composite is a promising material for NH_3 sensors operating at room temperature.