Growth Mechanism And Corrosion Behavior Of Ceramic Coatings On Aluminum Produced By Autocontrol Ac Pulse Peo

Ceramic coatings are produced on aluminum alloy by autocontrol AC pulse Plasma Electrolytic Oxidation (PEO) with stabilized average current. Transient signal gathering system is used to study the current, voltage, and the transient wave during the PEO process. SEM, OM, XRD and EDS are used to study the coatings evolution of morphologies, composition and structure. TEM is used to study the micro profile of the outer looser layer and inner compact layer. Polarization test is used to study the corrosion property of PEO coatings in NaCl solution. According to the test results, AC pulse PEO process can be divided into four stages with different aspects of discharge phenomena, voltage and current. The growth mechanism of AC PEO coating is characterized as anodic reaction and discharge sintering effect. PEO coating can increase the corrosion resistance of aluminum alloy by one order or two; however, too long process time is not necessarily needed to increase the corrosion resistance. In condition of this paper, PEO coating at 60 min is the most protective coating for aluminum alloy substrate. (C) 2008 Elsevier B.V. All fights reserved.

Interface Fracture Property Of Peo Ceramic Coatings On Aluminum Alloy

This paper combines the four-point bending test, SEM and finite element method to study the interface fracture property of PEO coatings on aluminum alloy. The interface failure mode of the coating on the compression side is revealed. The ceramic coating crack firstly along the 45 degrees to the interface, then the micro crack in the coating deduces the interface crack. The plastic deformation observed by SEM shows excellent adhesion property between the coating and substrate. The plastic deformation in the substrate is due to the interfacial crack extension, so the interface crack mode of PEO coatings is ductile crack. The results of FEM show that the compression strength is about 600 MPa. (C) 2008 Elsevier B.V. All rights reserved.

The mechanism of PEO process on Al–Si alloys with the bulk primary silicon

This study focuses on mechanism of ceramic coating on Al-Si alloys with bulk primary Si using plasma electrolytic oxidation (PEO) technology. Al-Si alloys with 27-32% Si in weight were used as substrates. The morphologies, composition and microstructure of PEO coatings were investigated by scanning electron microscopy (SEM) with energy dispersive X-ray system (EDX). Results showed that the PEO process had four different stages. The effect of bulk Si is greatly on the morphology and composition of coatings at first three stages. Anodic oxide films formed on Al and Si phases, respectively. When the voltage exceeded 40 V, glow appeared and concentrated on the localized zone of interface of Al and Si phase. Al-Si-O compounds formed and covered on the dendrite Si phase surface, and the coating on bulk Si, which was silicon oxide, was rougher than that on other phase. If the treatment time was long enough, the coatings with uniform surface morphologies and elements distribution will be obtained but the microstructure of inner layer is looser due to the bulk Si.

PS-b-PEO嵌段共聚物薄膜的结晶与微相分离

半结晶性嵌段共聚物中，嵌段间的不相容性导致的微相分离与结晶嵌段的结晶行为之间存在相互竞争与协同作用。现阶段的大部分工作主要集中于半结晶性嵌段共聚物相分离发生后的结晶行为的结晶动力学和内部链折叠，而对于结晶与微相分离同时发生时的结晶与微相分离行为的研究还较少。 本论文以半结晶性的聚苯乙烯和聚环氧乙烷的二嵌段共聚物（PS-b-PEO）薄膜为研究对象，研究其破坏性（break out）结晶行为，以及研究方形片晶与微相分离结构的关系。 首先，本论文研究了不同相分离取向对结晶行为的影响。我们通过控制膜厚得到垂直基底和平行基底的微相分离薄膜。在溶剂蒸汽中，微相分离取向垂直基底时，仅仅是有序度增加，片晶协同生成。退火时间增加，结晶成核控制生长向扩散控制生长转变，导致片晶周围树枝晶生长。微相分离结构为平行基底取向时，焓主要用于取向转变和有序度增加，体系没有片晶生成，仅边缘效应使树枝晶产生。在结晶取向方面，研究了溶剂蒸汽氛围内界面作用改变使分子链轴垂直基底（flat-on）结晶向分子链轴平行基底（edge-on）结晶的转变。随着溶剂分子扩散到基底界面，结晶嵌段PEO与基底相互作用从强变弱，是发生这种转变的决定因素。 其次，从片晶与微相分离相互转变和片晶上微相分离刷的形成两方面研究片晶与微相分离的竞争与协同关系。退火溶剂的选择性影响片晶与微相分离的竞争。在PEO不良溶剂蒸汽环己烷中发生以下转变：片晶生成，逐渐被微相分离破坏，片晶重新生成；PEO良溶剂水中仅存在结晶到微相分离的转变。即晶体溶解，与PS发生微相分离以获得能量上的有利状态。可溶解嵌段的自由体积增加和结晶嵌段的低溶胀性分别是微相分离和结晶发生的关键因素。片晶与微相分离协同关系研究上，通过调控二嵌段共聚物片晶上聚合物刷的密度（小于14.3大于3.8），获得具有微相分离结构的聚合物刷。PS-PS刷的弱相互作用以及PS与PEO（连接PEO片层结构未结晶的PEO链）之间的强不相容性对片层上微相分离刷的形成起来决定作用。

星形和多嵌生物降解聚合物

本论文针对聚ε-己内酯（PCL）为代表的可生物降解脂肪族聚酷亲水性差等缺点，通过共聚反应，在聚酷中引入了亲水性的聚环氧乙烷链段（PEO），制备了具有四臂星形结构的聚己内酯一聚环氧乙烷两亲性共聚物。通过氨基酸N-拨酸配开环反应制备了含有聚氨基酸链段的两亲性三嵌段共聚物，该结构共聚物与脂肪族聚酷均聚物相比具有更好的组织相容性。本论文的创新性和主要研究结果如下：1．通过采用以二乙基锌为催化剂，季戊四醇为引发剂的引发体系，合成了具有端轻基结构的四臂星形聚ε-己内酯。聚合产物的分子量可以通过改变单体与引发剂之比进行有效的控制。通过GPC、IR、NMR等测试手段证实聚合物分子链具有星形结构。2．以四臂星形聚ε-己内酯为大分子引发剂、二乙基锌为催化剂，通过引发环氧乙烷的开环反应制备了具有星形结构的嵌段共聚物。根据各种测试分析的实验结果确定了共聚物的链结构。3．DSC和WAXD的分析表明，星形嵌段共聚物由于核心部分为PCL，其结晶能力受到了处于外部的PEO链段的限制。当PEO足够长时，将观察不到PCL段的结晶。4．运用蔡钾和乙睛为活性聚合引发体系，通过分步加入环氧乙烷和ε-己内酯两种 单体的方法合成了带有睛端基的两亲性嵌段共聚物。5．采用把／碳和Raney-Nickel混合催化体系，成功地将端睛基PCL-PEO加氢还原为端氨基共聚物。6．以端氨基PCL-PEO为大分子引发剂引发γ-苄基-L-谷氨酸NCA开环聚合制备了带有聚氨基酸醋链段的两亲性共聚物。

LLDPE接枝新型表面活性剂共聚物的制备及其结构、性能与应用的基础研究

合成三个系列的新型表面活性剂，制备了三个系列的聚乙烯接枝共聚物。第一系列的表面活性剂是将Tween8O、span80，聚氧乙烯肉桂醇醚，PEO（400），PEO（1000），PEO（2000）OCOC1’7H35和PEO（6000）-OCOC17H35引入双键而使其功能化，然后接枝到聚乙烯分子链上，表面活性剂的引入改变了聚乙烯的表面性能，使其亲水性增加。前三者为商品防雾滴剂，实验发现防雾滴剂的聚乙烯接枝共聚物膜的防雾滴性不如物理共混法制备的聚乙烯防雾滴膜的效果好。接枝聚乙烯共聚物LLDPE-g-PEO和LLDPE-g-PEO-sterate，由于结构差别，共聚物表面组成不同。前者随着支链长度的增加，支链柔性降低，共聚物表面氧的富集量趋于减少；而后者由于疏水基硬脂酸中碳链的存在，随着支链的增加，共聚物表面氧的富集量增加。LLDPE-g-PEO（400）和LLDPE-g-PEO（1000）的等温结晶速率都比空白聚乙烯的快。由于PEO与聚乙烯不相容，支链PEo在接枝共聚物中起异相成核剂的作用，使结晶速率加快。LLDPE-g-PEO（2000）-stearate的等温结晶速率与聚乙烯的接近，但比空白聚乙烯的略慢。这是由于支链末端硬脂酸碳链是柔性的疏水链，且与聚乙烯有较好的相容性，在本体聚乙烯非晶区中活动性较强，带动聚氧乙烯支链向相同的方向运动，使支链在聚乙烯中分散且伸展，对聚乙烯分子起惰性稀释剂的作用而导致结晶速率降低；但聚氧乙烯（2000）又具有结晶性，在本体聚乙烯中起异相成核剂的作用，使聚乙烯结晶速率加快，这两种作用消长的结果，使LLDPE-g-PEO（2000）-stearte接枝共聚物的结晶速率接近聚乙烯，但比聚乙烯的结晶速率略慢。LLDPE-g-PEO（6000）-stearate接枝共聚物的结晶速率比聚乙烯的快，这是由于聚氧乙烯（6000）的结晶性较强，活动性较强的硬脂酸基团很难使其伸展，其晶粒在本体聚乙烯中主要起异相成核剂的作用，导致其结晶速率比聚乙烯的快。为了弄清表面活性剂接枝到大分子链上的作用机理，特设计第二、第三系列的表面活性剂。第二系列的新型表面活性剂是I、II、III、IV和V，以及含有不饱和键的表面活性剂A-I、A-II和A-III。这些表面活性剂是以聚乙二醇、乙二醇、1，6-己二醇和1，10-癸二醇为主要的起始原料制得的。实验结果发现这些表面活性剂的表面张力随着疏水链长度的增加而增加。以A-I、A-II和A-II作为接枝单体，将其成功接枝到聚乙烯分子链上，从而改善了聚乙烯的表面性能。 由FTIR确定了其接枝率。由DSc对其等温结晶行为的研究发现：接枝链在本体聚合物中起异相成核剂的作用，加速了结晶过程，但没有改变聚乙烯晶格结构（WXA）。随着接枝链中的疏水链长度的增加，等温结晶速率加快。在低剪切速率时，空白聚乙烯具有牛顿流体的特性，而接枝聚乙烯表现出非牛顿流体行为。接枝聚合物在低剪切速率具有剪切变稠、高剪切速率时剪切变稀的现象。第三系列的新型表面活性剂是含氟和聚氧乙烯的特种表面活性剂：productIII（600-4600）。以FTIR和1HNMR表征其结构。以productIII（600-4600）为接枝单体，成功制得含氟接枝聚乙烯共聚物，亲水性表面活性剂的引入，同样改变了聚乙烯的表面性能。当PEO分子量较低时，含氟接枝聚乙烯共聚物的表面极性随着接枝链的分子量增加，极性增加，在ProductIII（1500）时，达到最大值，分子量继续增加，极性反而降低。这是由于支链结晶增加而影响分子链的迁移。含氟接枝聚乙烯共聚物的等温结晶速率比空白LLDPE的高，而且接枝共聚物的结晶速率随着支链分子量的增加而加快。这是由于含氟聚氧乙烯的接枝链在结晶体系中起成核剂的作用，使结晶过程加速。由于接枝率低，接枝链在接枝共聚物起异相成核剂的作用，虽然加速了结晶速率，但没有破坏聚乙烯晶格。

PEO／PH共混体系的相容性、结晶结构、等温及非等温结晶动力学研究

PEO／PH共混体系的组份之间存在着氢键的相互作用，从偏光显微镜观察及熔点下降法测定，PEO／PH共混体系是相容体系，且PEO是在非晶区与PH相容，PH分子链不进入到PEO的晶格中，不引起晶胞参数的改变。对PEO／PH共混体系的等温结晶动力学研究表明，随共混体系中非晶组份PH含量的增加，体系的结晶生长方式由盘状生长转化为原纤状生长，成核方式由方式I(Kg=Kg(I)=4b. σσeTm/ΔHf.K)转化为方式II(Kg=Kg(Ii)=2b. σσeTm/ΔHf.K)析叠链表面自由能（σe）逐渐增大，体系的平衡溶点降低。在PEO／PH共混体系非等温结晶动力学的研究中，DSC实验表明，在常冷却速率下，PEO／PH共混体系符合Avrami方程所揭示的规律，为更好地反映非等温结晶特点，从Avrami方程和Ozawa方程出发，导出一个新的基本方程，根据这个方程，获得了描述非等温结晶过程的一些基本参数，在一定冷却速率下，随非晶组份PH含量的增加，东混体系的结晶速率降低；对于同一组成，冷却速率越大，体系结晶速率越快。WAXD和SAXS分析表明，随非晶组份PH含量的增加，PEO／PH共混体系的结晶度降低，长周期增大，过渡层厚略有变化，但变化很小。进一步表明，过渡层基本上是PEO的非晶相的贡献，PH不进入到PEO的晶格中，PEO是在非晶区与PH相容。

PEO/PCL两嵌段共聚物结晶过程的研究

本文以聚环氧乙烷/聚（ε-已内酯）PEO/PCL两嵌段共聚物为研究对象，研究了其等温结晶和非等温结晶过程及其熔融过程。对PEO/PCL嵌段共聚物的等温结晶过程的研究表明，只有PCL嵌段能发生结晶；在不同温度下等温结晶的PEO/PCL嵌段共聚物在熔融过程中一个显著的特点是在DSC熔融曲线上表现为双峰，而且随着结晶温度的升高，PEO/PCL嵌段共聚物的熔融峰由双峰转变为单峰；PEO/PCL嵌段共聚物在非等温结晶的熔融过程中，与其在等温结晶的熔融过程一样，即熔融曲线表现为双峰。PEO/PCL嵌段共聚物这种熔融双峰现象及其双峰的位置和变化情况，与PEO嵌段的作用有很大的关系。本文进一步讨论了PEO的这种影响和作用。

PEO陶瓷层对铝基体上DLC薄膜承载特性的影响

重载作用下,类金刚石(DLC)薄膜直接应用于铝合金等软金属基体上易发生脆性破裂和剥离而导致过早失效.针对这一问题,以PEO陶瓷层作为承载层,采用有限元数值计算方法,对复合涂层在均布接触载荷作用下的应力场进行研究.结果表明:陶瓷层可明显降低DLC膜的表面拉应力和界面剪应力,起到了良好的载荷支撑作用;陶瓷层厚度对涂层表面拉应力,界面及基体内剪应力的分布有显著影响,其中陶瓷层厚度与接触半宽比为0.150.30时,涂层可以获得较为合理的表面和界面应力场,从而改善DLC膜在铝合金基体上的摩擦磨损性能

Synthesis and properties of two kinds of CPVC carboxylated ionic copolymers

In the present work, two kinds of CPVC carboxylated ionic copolymers were prepared by a new method. First, a graft copolymer (CPVC-cg-AA) comprising of polyacrylic acid (PAA) as branched chains and chlorinated polyvinyl chloride (CPVC) as backbone was synthesized by in-situ chlorinating graft copolymerization (ISCGC). Second, the acid groups of the graft copolymer were neutralized by sodium hydroxide and aluminium hydroxide, respectively in order to prepare carboxylated ionic copolymers.

A strategy for synthesis of ion-bonded amphiphilic miktoarm star copolymers via supramolecular macro-RAFT agent

Amphiphilic supramolecular miktoarm star copolymers linked by ionic bonds with controlled molecular weight and low polydispersity have been successfully synthesized via reversible addition-fragmentation chain transfer (RAFT) polymerization using an ion-bonded macromolecular RAFT agent (macro-RAFT agent). Firstly, a new tetrafunctional initiator, dimethyl 4,6-bis(bromomethyl)-isophthalate, was synthesized and used as an initiator for atom transfer radical polymerization (ATRP) of styrene to form polystyrene (PSt) containing two ester groups at the middle of polymer chain. Then, the ester groups were converted into tertiary amino groups and the ion-bonded supramolecular macro-RAFT agent was obtained through the interaction between the tertiary amino group and 2-dodecylsulfanylthiocarbonylsulfanyl-2-methyl propionic acid (DMP). Finally, ion-bonded amphiphilic miktoarm star copolymer, (PSt)(2)-poly(N-isopropyl-acrylamide)(2), was prepared by RAFT polymerization of N-isopropylacrylamide (NIPAM) in the presence of the supramolecular macro-RAFT agent. The polymerization kinetics was investigated and the molecular weight and the architecture of the resulting star polymers were characterized by means of H-1-NMR, FTIR, and GPC techniques. (c) 2008 Wiley Periodicals, Inc.

Synthesis and Properties of Carbazole Main Chain Copolymers with Oxadiazole Pendant toward Bipolar Polymer Host: Tuning the HOMO/LUMO Level and Triplet Energy

Three new carbazole copolymers, poly(9-(2,5-diarene-[1,3,4]oxadiazole)-carbazole-alt-9-(2-ethylhexyl)-carbazole-3,6-diyl)s (P1), poly(9-(2,5-diarene-[1,3,4]oxadiazole)-2, 7-carbazole-alt-9-(2-ethylhexyl)-3, 6-carbazole-diyl)s (P2), and poly(9-(2,5-diarene-[1,3,4]oxadiazole)-carbazole-alt-9-(2-ethylhexyl)-carbazole-2,7-diyl)s (P3), were synthesized by the Suzuki coupling reaction