1、1The role of simulation-driven engineering in semicon challengesJOOST MULDER-MANAGING DIRECTORDemcon multiphysicsApplying fundamental physical insight to generate innovative engineering solutions.AnalyticsBack-of-the-envelope calculationsSimulationsExperiments3High-end engineering services in the fi
2、eld of multiphysics4Fluid flowsHigh-end engineering services in the field of multiphysics5Structural mechanicsHigh-end engineering services in the field of multiphysics6Thermal engineeringHigh-end engineering services in the field of multiphysics7ElectromagneticsHigh-end engineering services in the
3、field of multiphysics8Acoustics&vibrations High-end engineering services in the field of multiphysics9Nuclear physicsHigh-end engineering services in the field of multiphysics10ExperimentsHigh-end engineering services in the field of multiphysics11Product developmentHigh-end engineering services in
4、the field of multiphysics12Active in many different marketsHIGH-TECH SYSTEMS&MATERIALSLIFE SCIENCES&HEALTHAGRI&FOODSMART INDUSTRYAEROSPACEWATER&MARITIMEDEFENSE&SECURITYENERGY13Active in many different marketsHIGH-TECH SYSTEMS&MATERIALSSEMICON14Typical challenges&simulations Operating in vacuum at hi
5、gh temperatures with high precision.Thermomechanical effects Sensor placement Control and dynamics Material handling Advantage of simulations Prevent costly and complex experiments Fast and aimed iterations in design phase Understand separate and combined physicsSEMICON15Practical examples from the
6、chip industryThree examples from our experiences:1.Cu-Cu bonding Machine conditioning2.Panel level packaging warpage prediction3.High precision systems Thermal drift16Cu-Cu bonding Machine conditioning171.Copper-to-copper bonding Copper for 3D-stacking Favorable material properties Elevated temperat