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引用次数: 2
摘要
本文描述了基于有限元法的三维漂移扩散(D-D)半导体模拟器中密度梯度量子校正的实现。基于量子力学修正的三维半导体器件模拟器的网格效率是通过对存储分布式多处理器环境下的代码并行化来实现的。泊松方程、电流连续性方程和密度梯度方程必须进行适当的有限元离散化迭代求解。此外,采用并行算法加快自洽求解速度。为了测试我们的3D半导体器件模拟器,我们对67 nm Si MOSFET的实验I-V特性进行了仔细校准,获得了很好的一致性。然后我们演示了量子力学修正在该装置中的相对影响。
Implementation of a quantum corrections in a 3D parallel drift-diffusion simulator
We describe an implementation of density-gradient quantum corrections in a 3D drift-diffusion (D-D) semiconductor simulator based on finite element method. Mesh efficiency of the 3D semiconductor device simulator with quantum mechanical corrections is achieved by parallelisation of the code for a memory distributed multiprocessor environment. The Poisson equation, the current continuity equation, and the density gradient equation with an appropriate finite element discretisation have to be solved iteratively. Moreover, parallel algorithms are employed to speed up the self-consistent solution. In order to test our 3D semiconductor device simulator, we have carried out a careful calibration against experimental I-V characteristics of a 67 nm Si MOSFET achieving an excellent agreement. Then we demonstrate a relative impact of quantum mechanical corrections in this device.
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