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中文学术论文3

科技篇3

水泥与骨料中活性二氧化硅的膨胀反应3

关于碱-骨料反应的几个问题13

石膏矿渣水泥与活性骨料的膨胀反应22

碱对水泥生产和性能的一些影响31

钢渣中MgO、FeO、MnO的结晶状态与钢渣的体积安定性41

对彼特洛辛《水泥的热力学和热化学》一文的一点质疑54

关于火成岩骨料的碱活性及其与水泥浆的界面反应58

吉林白山大坝混凝土自生体积膨胀机理的研究73

高温、高压、高碱下的碱-集料反应81

水泥浆体-集料界面特性与砂浆电导率的关系92

水泥浆体与集料界面的黏结强度99

水泥浆体-集料界面的结构特性与砂浆抗蚀性的关系107

高强度碱矿渣水泥112

混凝土耐久性研究应成为最活跃的研究领域118

关于碱-集料反应的几个理论问题123

掺氧化镁水泥的膨胀规律及其影响因素131

低孔隙率胶凝材料的孔结构测定方法136

石英的显微结构与碱活性141

T.C.Powers模型若干问题的研究144

氧化镁在不同水泥基中的水化和膨胀152

碱矿渣水泥砂浆抗酸腐蚀性157

碱-集料反应的分类162

处理刚玉集料对砂浆界面结构的改进169

低孔隙率砂浆的强度性能和孔结构175

放射性废物水泥固化的理论基础、研究现状及对水泥化学研究的思考181

碱-白云石反应及碱-碳酸盐岩反应的膨胀机理190

MDF水泥抗弯强度与大孔尺寸和孔隙率的关系200

混凝土中碱骨料反应与冻融破坏的特征判据205

去冰盐与碱-集料反应的协同效应及其防治研究209

界面区结构对水泥砂浆抗硫酸盐侵蚀性能的影响214

油井水泥石CO2腐蚀的热力学条件221

提高重大混凝土工程耐久性对节约资源能源、保护环境意义重大227

我国混凝土中的碱集料反应236

集料ASR碱活性检测方法评述243

碱硅酸反应与碱碳酸盐反应252

关于水泥混凝土发展方向的几点认识261

不同结构构造硅质集料的碱硅酸反应模型268

碱集料反应研究的新进展276

碱集料反应中当量碱计算问题探讨285

道面水泥混凝土高性能化和放大道面板尺寸问题初探297

碳硫硅钙石型硫酸盐腐蚀研究综述306

硅质碳酸盐Spratt岩在LiOH溶液中的膨胀行为313

水泥基复合材料的吸波性能319

掺杂TiO2水泥的吸波性能与力学性能研究324

LiOH抑制碱硅酸反应膨胀及其应用研究330

提高基建工程寿命是最大的节约339

长石类矿物析碱对碱-硅酸反应的影响346

集料碱活性快速检测法对比研究357

节能减排工作应重视提高基建工程寿命366

裂缝对于混凝土耐久性的影响374

轻烧MgO膨胀剂对水泥浆体变形行为的影响382

石墨-碳纤维水泥基复合材料的电磁屏蔽效能388

教学篇394

讲授“水泥化学进展”课程的一些体会（研究生班）394

碱集料反应——实践-理论-实践398

英文学术论文403

Effect of Ca （OH）2 on Alkali-silica Reaction403

Some Remarks about Alkali-silica Reactions410

Effect of Alkali on the Interface Reaction between Cement and Aggregate412

The Preventive Effect of Mineral Admixtures on Alkali-silica Reaction and Its Mechanism419

A Rapid Method for Identification of Alkali Reactivity of Aggregate425

Kinetics of Alkali-silica Reaction432

Rapid Method for Determining the Preventive Effect of Mineral Admixtures on Alkali-silica Reaction439

Alkali Reactivity of Glass Aggregate443

Mechanism of Alkali-carbonate Reaction449

Expansive Mechanism of Magnesia as Additive of Cements454

Studies of Alkali-aggregate Reaction from Petrography and Mineralogy467

Alkali-carbonate Reaction and pH Value473

Hydration of Alkali-slag Cements at 150℃482

Mg-type Delayed Expansive Cement489

A New Method of Enhancing Cement-aggregate Interfaces, Ⅰ . Ideal Aggregate and Its Effects on Interfacial Microstructures498

A New Method of Enhancing Cement-aggregate Interfaces, Ⅱ. Mechanical Properties and Sulphate Attack Resistances of Mortars506

Deterioration of Concrete Structures Due to Alkali-dolomite Reaction in China510

Mechanism of Dedolomitization and Expansion of Dolomitic Rocks517

Formation and Expansion of Ettringite Crystals529

Studies on Alkali-Carbonate Reaction537

Autoclave Method for Identification of Alkali-Reactive Carbonate Rocks544

Mechanism of Mineral Admixture Suppressing Alkali-silica Reaction: Part Ⅰ. Corrosion Degree of Reactive Aggregate in Blended Cement Pastes and Its Correlations with Expansion Value and Electric Resistance Change550

Mechanism of Mineral Admixture Suppressing Alkali-silica Reaction: Part Ⅱ. Retardation of the Transport of Na, K and OH Ions in Pore Structure Caused by Acidic Action of Mineral Admixture Particles in Matrix560

Correlation between Reaction and Expansion of Alkali-carbonate Reaction567

Application of Expansive Cement with Magnesia in Dams575

The Process of Sulfate Attack on Cement Mortars581

Expandability of Solid-volume-reducing Reactions of Alkali-magnesite and Alkali-dolomite588

Improving the Structure of the Interfacial Zone and Its Influence on the Long-term Behavior of Mortars599

Influence of Dimension of Test Specimen on Alkali-aggregate Reactive Expansion607

Expansion Mechanism of Alkali-dolomite and Alkali-magnesite Reaction614

Influence of Aggregate Size and Aggregate Size Grading on ASR Expansion629

ACR Expansion of Dolomites with Mosaic Textures634

Expansion of Siliceous and Dolomitic Aggregates in Lithium Hydroxide Solution647

A New Accelerated Method for Determining the Potential Alkali-carbonate Reactivity656

Alkali Carbonate Reaction Expansion of Dolomitic Limestone Aggregates with Porphyrotopic Texture666

Development and Inter-laboratory Trial of the RILEM AAR-5 Rapid Preliminary Screening Test for Carbonate Aggregates680

Use of Fuzzy Neural Network to Evaluate Effect of Composition of Fly Ash in Suppressing AAR689

Alteration of Alkali Reactive Aggregates Autoclaved in Different Alkali Solutions and Application to Alkali-aggregate Reaction in Concrete （Ⅰ）Alteration of Alkali Reactive Aggregates in Alkali Solutions706

Alteration of Alkali Reactive Aggregates Autoclaved in Different Alkali Solutions and Application to Alkali-aggregate Reaction in Concrete （Ⅱ）Expansion and Microstructure of Concrete Microbar726

The Thaumasite Form of Sulfate Attack in Concrete of Yongan Dam740

Alkali Release from Aggregate and the Effect on AAR expansion744

The Use of Thermodynamic Analysis in Assessing Alkali Contribution by Alkaline Minerals in Concrete759

Development of a Universal Accelerated Test for Alkali-silica and Alkali-carbonate Reactivity of Concrete Aggregates771

Potential Approach to Evaluating Soundness of Concrete Containing MgO-based Expansive Agent785

Investigation of Alkali-silica Reaction Inhibited by New Lithium Compound799