由于此商品库存有限,请在下单后15分钟之内支付完成,手慢无哦!
100%刮中券,最高50元无敌券,券有效期7天
活动自2017年6月2日上线,敬请关注云钻刮券活动规则更新。
如活动受政府机关指令需要停止举办的,或活动遭受严重网络攻击需暂停举办的,或者系统故障导致的其它意外问题,苏宁无需为此承担赔偿或者进行补偿。
全新正版柔封装工艺建模与应用9787030625052科学出版社
¥ ×1
Contents
Abbreviations
1 Advanced Electronic Packaging 1
1.1 Introduction 1
1.2 Adhesively Bonde Mtlayer Structure 5
1.3 Interfacial Peeling-off 6
1.3.1 Needle Ejecting for Thin Chips 6
1.3.2 Conformal Peeling for Large-Area Devices 8
1.3.3 LLO for Large-Area Flexible Electronics 9
1.4 Vacuum-Based Chip Picking-up 12
1.5 Vacuum-Based Chip Placing-on 13
1.6 Comig Fracture 16
1.6.1 Comig Fracture Behavir 6
1.6.2 Fracture Strength and Adhesive Fracture Energy 16
References 17
2 Interfacial Modeling of Flexible Multilayer Structures 29
2.1 Introduction 29
2.2 Modeling of Chip-on-Substrate Structure 29
2.2.1 Mechanical Model 29
2.2.2 Analytical Evaluation on ERR of Interfacial Peeling 31
2.. Virtual Crack Closure Technique (VCCT 33
2.2.4 Numerical Model 34
. Modeling of Chip-Adhesive-Substrate Adhesively Bonded Joints 34
..1 Adhesive Model on Overlapped Joints 34
..2 Equilibrium Equations 36
.. Establishment of Differential Equation Set 38
..4 Solutions for Internal Forces and Displacements 40
..5 Relationships Among Integration Constants 44
.. Theoretical Calculation of ERR of Interfacial Peeling 46
2.4 Summary 46
References 47
3 Measurement of Fracture Strength of Ultra-Thin Silicon Chip and Adhesive Fracture Energy 49
3.1 Introduction 49
3.2 Fracture Strength of Ultra-Thin Silicon Chip 50
3.2.1 Experimental Procedure 50
3.2.2 Nonlinear Mechanical Characterization in Bending Test 51
3.. Estimation of Fracture Strength 58
3.3 Estimation of Adhesive Fracture Energy of Adhesive Tape 62
3.3.1 Theoretical Foundation 62
3.3.2 Experimental Procedure 64
3.3.3 Estimation of Adhesive Fracture Energy 64
3.3.4 Angle Dependence of Peel Force 65
3.3.5 Rate Dependence of Adhesive Fracture Energy 67
3.4 Summary 69
References 70
4 Tension-Assisted Peeling 73
4.1 Introduction 73
4.2 Theoretical Determination of Integration Constants 73
4.2.1 Stiffened Plate Joint Under Axial Tension and Bending Moment 74
4.2.2 Single-Strap Joint Under Tension 76
4.. Single-Lap Joint Under Tension 79
4.3 Modeling of Adhesively Bonded Chip Array 82
4.3.1 Mechanical Model Description 82
4.3.2 Boundary and Continuity Conditions 84
4.3.3 Solution for Internal Forces and Displacements 85
4.3.4 Determination of Integration Constants 86
4.4 Adhesive Stresses for Adhesively Bonded Joints 87
4.4.1 Analysis of Balanced Adhesively Bonded Joints 87
4.4.2 Analysis of Unbalanced Adhesively Bonded Joints 90
4.4.3 Discussion of Results 92
4.5 Peeling Behavior for Chip Array on Stretched Substrate 93
4.5.1 Adhesive Stresses 93
4.5.2 Effect of Geometric Dimensions 95
4.5.3 Effect of Material Properties 98
4.5.4 Process Optimization 100
4.6 Summary 101
References 102
5 Single-Needle Peeling 105
5.1 Introduction 105
5.2 A Case for Chip-on-Substrate Structure 107
5.2.1 EfiFect of Crack Length 108
5.2.2 Effect of Geometric Dimensions 108
5.. Effect of Elastic Mismatch 110
5.3 A Case for Chip-Adhesive-Substrate Structure 111
5.3.1 Geometric Model Description 111
5.3.2 Theoretical Calculation of ERR 115
5.33 Effect of Crack Length 116
5.3.4 Effect of Geometric Dimensions 117
5.3.5 Effect of Material Properties 118
5.3.6 Analysis on Tunability of Peeling Mode 119
5.4 Analysis of Fracture Mode Based on Comig Index 121
5.4.1 Typical Fracture Modes 121
5.4.2 Comig Fracture Model 1
5.4.3 Basic Fracture Parameters 124
5.4.4 Effect of Geometric Dimensions 125
5.4.5 Discussion on Results 127
5.5 Impact Effect of Needle Peeling-off Process 130
5.5.1 Failed Sample Observation 130
5.5.2 Numerical Model 130
5.5.3 Effect of Impact Speed 132
5.5.4 Effect of Substrate Penetration 134
5.6 Summary 135
References 137
6 Multi-Needle Peeling 139
6.1 Introduction 139
6.2 Mechanical Model of Multi-Needle Peeling-off 140
6.2.1 Model Description 140
6.2.2 Boundary and Continuity Conditions 142
6.. Determination of Integration Constants 144
6.3 Comig Fracture Model of Chip-Adhesive-Substrate Structure 147
6.4 Analysis of Bending Normal Stress and ERR of Interfacial Peeling 151
6.4.1 Analysis of Bending Normal Stress 151
6.4.2 Analysis of ERR of Interfacial Peeling 154
6.5 Effect of Chip Geometry on Comig Fracture Behavir 56
6.5.1 Effect of Chip Thickness 156
6.5.2 Effect of Chip Length 158
6.6 Experimental Validation 160
6.7 Summary 162
References 163
Conformal Peeling 165
7.1 Introduction 165
7.2 Modeling of Conformal Peeling for Multilayer Structure 166
7.3 Effect of Material Properties and Geometric Size 174
7.3.1 Effect of Young’s Modulus of Device Layer 174
7.3.2 Effect of Young’s Modulus of Adhesive Layer 176
7.3.3 Effect of Device Thickness 179
7.3.4 Effect of Substrate Thickness 181
转印是实现器件功能封装、产品包装必须要解决的核心工艺之一。面对日趋超薄化的芯片,实现其无损转印对于降低封装成本,提高产品成品率、改善器件可靠等有着显著意义。本书从建模、机理和工艺等方面入手,先针对单顶针和多顶针推顶剥离方式下的超薄芯片无损剥离技术进行了深入分析;接着,以器件层-粘胶层-载带层柔三层结构为对象,研究了基于卷到卷系统的辊筒共形剥离和卷到卷转移工艺;然后,针对厚度可能仅为几微米的更薄芯片,初步探索了更加和具有挑战的激光转移技术;之后,对目前关于转印技术的研究现状进行了总结分析;,对芯片真空拾取和贴装工艺进行了探讨,建立了真空拾取与高密度贴装的理论艺窗。
亲,大宗购物请点击企业用户渠道>小苏的服务会更贴心!
亲,很抱歉,您购买的宝贝销售异常火爆让小苏措手不及,请稍后再试~
非常抱歉,您前期未参加预订活动,
无法支付尾款哦!
抱歉,您暂无任性付资格