Crosslight新闻

光子晶体表面发射激光器PCSEL 3D初测版模型发布

全新3D PCSEL模型的初测版本已发布,并集成到PICS3D 2024 试用版中。

感兴趣的用户可以联系Crosslight获取相关试用版本。

获取资料进一步了解该PCSEL模拟功能的介绍:Crosslight_3D_PCSEL_zh.pdf

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山东大学刘超课题组使用APSYS软件研究成果分享

山东大学刘超课题组使用Crosslight公司的APSYS软件在器件仿真课题多个项目上取得了令人瞩目的研究成果。

以下分享课题组在2023年发表的多项学术论文:

Paper1:

Systematic Design and Parametric Analysis of GaN Vertical Trench MOS Barrier Schottky Diode With p-GaN Shielding Rings

Paper2:

Analytical Model and Design Strategy for GaN Vertical Floating Island Schottky Diodes

Paper3:

Alleviated built-in electric field in the active region of AlGaN deep-ultraviolet light-emitting diodes with locally embedded p-i-n junctions

Paper4:

Comprehensive Design and Numerical Study of GaN Vertical MPS Diodes Towards Alleviated Electric Field Crowding and Efficient Carrier Injection

Paper5:

Design Space of GaN Vertical Trench Junction Barrier Schottky Diodes: Comprehensive Study and Analytical Modeling

Paper6:

Enhanced Carrier Injection in AlGaN-Based Deep Ultraviolet Light-Emitting Diodes by Polarization Engineering at the LQB/p-EBL Interface

Paper7:

Sheet Charge Engineering Towards an Efficient Hole Injection in 290 nm Deep Ultraviolet Light-Emitting Diodes

Paper8:

Enhanced hole injection in Ga-polar 290 nm AlGaN-based DUV LEDs with a p-n junction hole accelerator

Paper9:

Simultaneously improved hole injection and current uniformity in 293 nm AlGaN-based deep ultraviolet light-emitting diodes

Paper10:

Improving the hole injection efficiency in AlGaN DUV LEDs by minimizing the band offset at the p-EBL/hole supplier interface

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v2023发布公告

Crosslight即将发布2023最新正式版软件,其中包含诸多具有里程碑意义的崭新功能;新版本除了在现有版本的基础上进一步改进和优化之外,还包含了以下新特性:

  • 基于格林函数理论的微腔结构新发射谱模型。

  • 完整的三维微腔模型已经升级到支持对称边界条件。这一改进使PICS3D只需求解一半或四分之一的器件,即可节省网格和模拟时间。这种灵活性对于大型或复杂的器件特别有益,如光子晶体VCSEL和高对比度光栅VCSEL。

  • 提供更新更快且更节省内存的特征值求解器。这些求解器会自动用于微腔模型中的光学模式求解。

  • 支持增益表的导入/导出的新压缩(zip)格式,从而加快从外部求解器加载材料增益数据的过程,使得高密度表格更易于使用。

  • 该新版本将在完成最终测试后的几周内发布。对于仍在技术支持合约有效期内的客户,如果有兴趣试用这些新功能,可联系当地销售代表。

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新型氧化物VCSEL示例

氧化限制性VCSEL模型的新示例已经上传。演示了微腔模型计算的多模分布以及最近添加到 PICS3D 测试版中新的光谱分析功能。感兴趣的试用用户,和仍在技术支持合约有效期内的客户可以联系我们,以便尽早获取2023测试版和运行此示例所需的文件。

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SiGe EAM新示例

从2023版本开始,SiGe调制器的新模型已添加到我们的标准PICS3D示例库中。感兴趣的试用用户,和仍在技术支持合约有效期内的客户可以联系我们,以便尽早获取2023测试版和运行此示例所需的文件。

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全新3D HCG-VCSEL示例

高对比度光栅晶体垂直面发射激光器(HCG-VCSEL)的新模型,已经为我们的PICS3D测试版示例,使用了麦克斯韦方程的矢量FDFD求解器中最新改进的功能。感兴趣的试用用户,和仍在技术支持合约有效期内的客户可以联系我们,以便尽早获取2023测试版和运行此示例所需的文件。

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新的3D PC-VCSEL示例

利用我们在麦克斯韦方程矢量FDFD求解器中的最新改进,我们的PICS3D测试版演示了光子晶体垂直面发射激光器(PC-VCSEL)模型的新模型。感兴趣的试用用户,和仍在技术支持合约有效期内的客户可以联系我们,以便尽早获取2023测试版和运行此示例所需的文件。

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2023年Crosslight最佳项目奖

我们很荣幸地宣布与伊利诺伊大学厄巴纳-香槟分校助理教授Can Bayram合作的第四位年度获奖者。作为此次合作的一部分,学生们在学术环境中使用Crosslight TCAD工具,并获得了最佳项目。

祝贺2023年度获奖者:

NITHIYASSRI K R T VIVAGANDAN Designing Blue-Wavelength Free White Light: A Dichromatic Approach Using Violet and Yellow-Green LEDs

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v2022发布公告

Crosslight很荣幸地宣布,即将发布的v2022版本的新功能里程碑。除了多个错误修复和改进外,还进行了以下新功能改进:

  • 对多个隧道结的VCSEL模型进行了改进,从而可以从模拟中提取更精确的光输出。
  • 微腔FDFD模型在速度、精度和易用性方面有显著改进。该模型现在被推荐用于复杂的VCSEL结构,包括具有多个隧道结的器件。
  • 薄膜晶体管的热载流子注入/陷阱生成模型。
  • 更新的AC模型。
  • 新的三维网格生成系统。

这个版本将在今年晚些时候最终测试完成后发布。对于仍在技术支持合约有效期内的客户,如果希望立即尝试这些新功能,可以联系当地的销售代表。

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2022年Crosslight最佳项目奖

我们很荣幸地宣布与伊利诺伊大学厄巴纳-香槟分校助理教授Can Bayram合作的第四位年度获奖者。作为此次合作的一部分,学生们在学术环境中使用Crosslight TCAD工具,并获得了最佳项目。

祝贺2022年该奖项的获奖者:

Jaekwon Lee for 2D Optical-Thermal-Electrical Simulation for High Wall Plug Efficiency Cubic GaN Green LED on Silicon

Robert Kaufman for HgCdTe Long-Wave Infrared Photovoltaics for Directed Energy Applications

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新全矢量VCSEL示例

我们的激光二极管应用页面上增加了一个关于微腔模型的新示例。

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从材料和TCAD的角度,将GaN功率器件优化到极限

我们的首席执行官兼创始人Simon Li博士在CASICON2021会议上发表的演讲副本,已上传到我们的杂项会议页面。

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新全矢量VCSEL示例

如何将现有VCSEL输入文件从标量模型转换为全矢量解决方案的新示例,已发布到我们的激光二极管应用页面。

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v2021发布公告

Crosslight很荣幸地宣布,即将发布的2021版本的新功能里程碑。除了修复多个错误和改进外,进行了新功能和改进:

  • LINUX平台发布具有改进的GUI支持的工艺仿真和器件仿真
  • 支持相同金属与半导体多个区域的接触的,金属/半导体界面
  • 使用流体动力学TCAD模拟实现热载流子注入模型,以支持与晶体管中热载流子注入相关的长期可靠性建模
  • TFT工艺中常见的氢和其他杂质扩散
  • LTSpice项目文件与混合模式TCAD模拟之间的接口,以便在TCAD仿真中添加电路元件时,启动LTSpice仿真。
  • 场致陷阱发射(Poole-Frenkel)模型
  • 改进VCSEL/TTM模型,处理隧道级联MQW VCSEL
  • 对宽带隙材料中少数载流子做特殊处理,以提高收敛性
  • 改进弯曲网格模型,用来处理多单元TFT-OLED

这个版本将在今年晚些时候最终测试完成后发布。仍在技术支持合约有效期内的客户如果希望立即尝试这些新功能,可以联系当地的销售代表。

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AMOLED/TFT串扰新示例

关于薄膜晶体管和集成AMOLED器件之间的串扰和干扰效应的新示例,已发布到我们的Misc. Microelectronics页面。

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2021年Crosslight最佳项目奖

我们很荣幸地宣布与伊利诺伊大学厄巴纳-香槟分校助理教授Can Bayram合作的第四位年度获奖者。作为此次合作的一部分,学生们在学术环境中使用Crosslight TCAD工具,并获得了最佳项目。

祝贺2021年该奖项的获奖者:

Yu-Chieh Chiu for “Designing Efficient Micro Light Emitting Diodes for Display Applications”

Jonah Messinger for “Harnessing Cobalt-60 Gamma Radiation with ZnTe Gammavoltaic Devices and an LuI3 Scintillator Interface for Clean Firm Power Generation”.

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Introduction to Optoelectronic Device Simulation using PICS3D

使用PICS3D软件进行光电器件仿真介绍

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Back-illuminated CMOS image sensor based on 3D modeling

ABSTRACT

Three-dimensional (3D) modeling is reported for CMOS active pixel image sensors particularly by comparing frontsurface and back-surface illumination. The opto-electronic responses are presented versus various power intensity and  illumination wavelength. 

The optical efficiency and quantum efficiency from FDTD modeling are also presented. For  appropriately designed sensor structure, it is shown that back-surface illumination pixel could achieve improved  sensitivity within certain wavelength range. 

The presented results demonstrate a methodological and technical capability  for 3D modeling optimization of complex CMOS image sensor.

Keywords: 

CMOS image sensor, active pixel sensor, optoelectronics, device modeling and TCAD software, semiconductor devices

01 INTRODUCTION

The complementary metal oxide semiconductor (CMOS) image sensors (CIS) are being widely used in various camera  systems for automotive, consumer, industrial, & security imaging applications. The active pixel sensor (APS) has  attracted increasing interest due to demand for miniaturized system-on-chip capability, low-power, and cost-effective  imaging systems during the past two decades [1-3]. 

To increase the sensitivity without compromising the resolution for a  front-surface illuminated (FSI) image sensor, various approaches including several photodiode structures such as the  pinned photodiode (PPD) [3,4] have been proposed. Micro lens has also been fabricated to increase the light gathering  power [5]. 

Other means like increasing the fill factor of the photo-electric conversion element as well as increasing the  conversion gain of the source-follower amplifier etc have also been explored. 

As a further technical development to  overcome the benefit limitation of the aforementioned approaches, the back-surface illuminated (BSI) image sensor has  attracted increasing attention due to enhanced sensitivity [6,7] and improved low-light performance. 

It has been noted  that a BSI sensor could theoretically cost less than a similar FSI one with the ability to collect more light. 

For a similarly  sized sensor to FSI one, the BSI array could offer higher resolution without the drop in low-light performance.  Alternatively, for the same resolution and low-light capability, the BSI sensor could be achieved on a smaller chip with  reduced costs. The BSI sensors have entered the commercialization market in recent years.

Due to the complexity of the 3D integration of photodiode and the optimization of metal layer distribution to maximize  the sensitive area, 3D modeling together with effective optical modeling method such as finite difference time domain  (FDTD) technique is indispensable [8,9]. An effective 3D modeling tool kit with full breadth covering process, optical  and opto-electric response modeling is definitely requested. 

In this work, based on Crosslight CSuprem and APSYS  [10], we present 3D modeling of APS units designed for comparing the opto-electronic response between FSI and BSI  pixels.

The paper is organized as flows. In section 2, brief software and methodological background for the modeling is  described. In section 3, comparison is presented between two individual sensor pixels, one for FSI and the other for BSI,  which are built by Crosslight LayerBuilder and simulated by APSYS. 

Further in section 4, comparing results are  presented between FSI and BSI for one individual sensor pixel, which is built and process simulated by Crosslight  Csuprem together with Crosslight APSYS for the modeling the opto-electronic response. Summary and conclusion is  finally given in section 5.

02 SOFTWARE AND METHODOLOGICAL BACKGROUND

2.1 Software background

The Crosslight CSuprem [10] is a powerful 2D/3D process simulator, which is capable to interface with Crosslight  APSYS. Its features include ion implantation, anisotropic and sacrificial etching, deposition, diffusion, annealing and  oxidation etc. The Crosslight APSYS is general-purpose 2D/3D finite element analysis and modeling software for semiconductor devices [10]. 

The simulator solves several interwoven equations including the basic Poisson’s equation,  and drift-diffusion current equations for electrons and holes. It includes many advanced physical models, friendly-using  features and offers a flexible modeling and simulation environment. Advanced models include heterojunction models,  (quantum) tunneling, hot carrier transport, trap dynamics, impact ionization and non-isothermal analysis etc. Important  generation and recombination mechanisms, such as Shockley-Reed-Hall, spontaneous and Auger recombination, are  taken into account. The software simulator provides several mobility model options from constant values to field  dependent ones.

To simulate the optical effect of the complex CIS structure, Crosslight FDTD as well as interface techniques to other  FDTD software is developed with APSYS. The graphic processing unit (GPU) solver is also implemented for fast  computation capability. 

The schematic interface between FDTD and Crosslight APSYS is shown in Fig. 1 (a) [9]. 

The 3D grid uniform in each coordinate direction must be used for FDTD so there is a mapping of irregular device structure  finite element data from/to Crosslight APSYS. In this work, all the optical efficiency (OE) and quantum efficiency (QE)  results are from FDTD simulation of the relevant CIS structures. The OE is defined as the integration of the ratio of  (ingoing flux-outgoing flux)/incident flux over device interface, where ingoing flux is the difference between the  incident flux and the reflected flux upon the very beginning surface illuminated first. The QE is defined as integration of  (absorption rate)*(relative energy intensity) across all the device 3D grid points. The OE does not care about which  material absorbs light and has electron-hole pairs generated. The QE computation involves in more mesh memory than  OE but provides more insight on the photo-electric conversion efficiency than the OE. The opto-electric response  modeling like various contact terminal potential evolution versus operating time cycle is solely based on Crosslight  APSYS with optical model involving in transfer matrix method (TMM) unless specified with alternative means.

2.2 Forming 3D CIS structures

The 3D CIS structures could be either formed by Crosslight LayerBuilder with multi-layers/columns by taking the  advantage of the 3D-connect flow option. The 3D CIS formed by this way does not involve in process simulation. The  3D CIS structures could also be partially or fully process-built and simulated by Crosslight CSuprem with structure  mesh, material together with doping exported and interfaced to Crosslight APSYS. 

The latter is often used for  complicated irregular geometrical design involving in multiple mask sets as designed by Crosslight Maskeditor. The  schematic APS unit structure is similar to Ref. [1-3,5,7,9] including a pinned photodiode, a transfer (TX) gate, and a  reset (RST) gate. 

Due to the thinning request and also for reducing the mesh size, we assume 5-um-thick p-type starting  substrate. The typical CIS schematic (regular geometry) with Crosslight LayerBuilder only is shown in Fig. 1 (b)  whereas the detailed unit component deployment (as generated by Crosslight MaskEditor with 9 mask layers and  subsequent CSuprem process simulation) is schematically shown in Fig. 1 (c).


Figure 1.(a) Schematic FDTD and APSYS interface

Figure 1.(b) typical schematic APS unit deployment (regular geometry) built by  APSYS LayerBuilder

Figure 1.(c) schematic APS unit deployment built with MaskEditor (and with CSuprem processing  simulation subsequently)

03 COMPARING CIS STRUCTURES BUILT BY APSYS LAYERBUILDER

In this section, we compare two sensor structures, one for FSI and the other for BSI. These two pixels are built by  APSYS LayerBuilder only according to the schematics shown in Fig. 1 (b). These two structures with 3D connect-flow  are shown in Fig. 2 (a) and (b) for FSI and BSI, respectively. Trench insulators are inserted among PPD, TX gate and  RST gate. Most of the front surface is simply assumed to be covered with thin SiO2 as anti-reflection coating layer  whereas the back surface is the (thinned) wafer base. For simplicity, no color filter array (CFA) is included for these two  structures for most of the modeling work except for comparison presented at the end of this section.

With the operating illumination and bias time clock cycle (reset at first and then transfer) as shown in Fig. 3, the  evolution of the potential on the floating drain (FD) versus time is shown in Fig. 4 (a) and (b) respectively for FSI and  BSI pixel, respectively. With increasing power intensity, the potential on FD shows increasingly large difference relative  to the dark case at the transfer stage. When the power intensity reaches certain level, the overshot-effect becomes  dominant at the transfer stage. Although not presented here, the results during the modeling process also indicate the 3D  current crowding effect, like poor sensitivity. 

This is accompanied by small or unchanged potential difference relative to  the dark case at the transfer stage with appropriate optical power intensity of illumination when too-wide PPD range is  set along the transfer gate and with poor trench insulation.


Figure 2. (a) 3D FSI and (b) 3D BSI pixel structures built by Crosslight LayerBuilder.

Figure 3. Illumination and pixel unit operating bias clock (inset).

The potential difference (relative to dark case) on the FD after transfer stage (the end of the time evolution cycle) versus  optical power intensity is shown in Fig. 5 (a) for BSI and FSI pixels by comparison at 0.55 µm wavelength. The BSI  pixel shows larger potential difference indicating improved sensitivity than the FSI pixel. 

The improved sensitivity with  BSI is also observed with the potential difference versus wavelength plots for both FSI and BSI cases as shown in Fig. 5  (b) with a comparison. It should be noted of that the results shown are based on the simple material structures as shown  in Fig. 2. Complicated wavelength dependency might be expected when more materials especially like CFA are involved in the pixel buildup.


Figure 4. Potential evolution versus time on FD for (a) FSI and (b) BSI pixels.

Figure 5. (a) Potential difference (at the end of TX stage) versus optical power intensity, and (b) potential difference (at the  end of TX stage) vs. wavelength, without CFA included for the simulation.

Whereas the aforementioned opto-electronic results support the BSI pixel design, it might be interesting to look from the  solely the optical perspective with the results from FDTD. In Fig. 6 (a) and (b), respectively, the OE and QE results are  compared between the BSI and FSI cases. Although the accuracy of FDTD simulation relies on large memory mesh with  detailed and correct compilation of various material dispersion profiles, the results, especially the QE ones, indicate that  the BSI pixel shows better sensitivity than FSI pixel at certain wavelength range for the pixel structures studied in this work, especially when full dispersion profiles (including SiO2) are considered for the front illumination case. 

At this  moment, we are also trying to get OE and QE comparison from optical TMM method. If the OE and QE obtained so  shows the same traits of comparison between BSI and FSI as the FDTD OE and QE, it may prompt us to conclude that,  for CIS, modeling solely based on optical OE and QE may not be enough to judge the actual pixel performance as in  some situation, the case with low OE and QE may still have better sensitivity of transfer. The sensitivity is better  represented by the potential difference with opto-electronic response as the OE or even the QE lacks the modeling  mechanism for the charge-voltage conversion in the pixel [6]. This drives the need for the TCAD software with a full  breadth of highly integrated process, optical and electronic modeling for CIS design and optimization.

More work has been done to simulate the OE, QE and opto-electronic response by applying the CFA on the top and at  the bottom of the structure as shown on Fig. 2 (a) and (b), respectively. The CFA is designed to have peak response near  0.55 µm with dispersion terms fitted from an assumed index data. The QE results are shown as in Fig. 7 (a) with the dispersion for all the materials included. From the QE results, the BSI pixel shows better performance than the FSI pixel,  which is also supported by the potential difference versus wavelength plots for both FSI and BSI cases as shown in Fig.  7 (b), respectively, with a comparison.


Figure 6. Optical FDTD simulation results of (a) OE and (b) QE comparison between FSI and BSI pixels.

Figure 7. (a) Comparison of QE, and (b) comparison of potential difference vs. wavelength between BSI and FSI pixels with  CFA included for the simulation.

04 COMPARING BSI AND FSI WITH CIS STRUCTURE BUILT BY CSUPREM

Next we present a 3D CIS structure built by CSuprem and the relevant comparison modeling of such a structure with FSI  and BSI [7]. The schematic APS unit structure is similar to Fig. 1(b), but it is partially process-built with 9 mask layers  (designed with Crosslight MaskEditor) as shown in Fig. 1 (c). The relevant process simulation is performed by  Crosslight CSuprem. CSuprem simulation exports structure mesh, material together with doping subsequently to  Crosslight APSYS. This simplified pixel unit does not include metal blocking aperture frame and the micro lens to  reduce computation complexity. The CFA layer is on the top for FSI and at the bottom for BSI APS. The 3D device  structures for both FSI and BSI are presented in Fig. 8 (a) and (b), respectively [7]. The relative optic power intensity of  the typical 2D cut plane around photodiode and transfer gate is shown in Fig 9. (a) and (b) for FSI and BSI, respectively [7].

With the same operating illumination and bias time clock cycle as shown in Fig. 3, the potential difference (relative to  dark case) on the FD after transfer stage (the end of the time evolution cycle) versus optical power intensity is shown in  Fig. 10 (a) and (b) for FSI and BSI case respectively at 0.60 µm wavelength. The BSI case shows larger potential  difference indicating improved sensitivity than the FSI case as shown in Fig. 11 (a). The improved sensitivity with BSI is  also observed with the potential difference versus wavelength plots for both FSI and BSI cases within certain wavelength range as shown in Fig. 11 (b). The large enhancement is observed around 0.60 µm although we tried to design the CFA  for 0.55 µm response. This means that the CFA needs to be re-designed for performance optimization. The peak  response deviation might be also due to complexity of the other material involved in.


Figure 8. APS pixel unit: for (a) FSI and (b) BSI simulation [7].


Figure 9. The 2D cut plane showing the photodiode and transfer gate region together with the optic power intensity profile  of (a) FSI and (b) BSI [7].

Figure 10. Potential evolution versus time on FD with various optical power intensity for (a) FSI and (b) BSI at 0.66 µm  illumination.

The OE and QE results for the pixels as shown in Fig. 8 has also been simulated with all material dispersion on. The  results are shown in Fig. 12 (a) and (b), respectively. Although the OE and QE plots do not show quite the same feature,  the results especially the QE one indicates that improved sensitivity can be achieved at certain wavelength range near the  CFA response window for the BSI case. The simulated opto-electronic response is observed with deviation from  designed CFA peak response which might be due to the inaccurate fitting of the various material dispersion terms as well  as the numerical uncertainty. It is noted the results shown in this section for the CIS pixels built and processed by  Csuprem is somehow deviated from the results presented in section 3. We attribute such partial discrepancy to the layout  and the diffusion profiles, which are actually different for the CIS pixels shown in both sections. Nevertheless, the  simulation for this section is under further examination. More optimization work is apparently needed on improved CFA  design, the structure layout optimization together with the combined opto-electronic simulation. Further work relevant to  CFA is cross-talk issues between (among) neighboring pixels. This would involve in more mesh and computation  complexity.


Figure 11. (a) Potential difference (after TX stage) versus optical power intensity, and (b) potential difference (after TX  stage) vs. wavelength.

Figure 12. Optical FDTD simulation results of (a) OE and (b) QE comparison between FSI and BSI pixels with CFA and all  relevant material dispersion on.

05 SUMMARY AND CONCLUSIONS

The 3D modeling is reported for CMOS active pixel image sensors particularly by comparing FSI and BSI cases. The opto-electronic responses are presented versus various power intensity and illumination wavelength. The OE and QE  results from FDTD modeling are also presented. 

For appropriately designed sensor structure, it is shown that BSI case  could achieve improved sensitivity within certain wavelength range comparing to the FSI pixel. 

The modeling work also  drives the need for the TCAD software with a full breadth of highly integrated process, optical and electronic modeling  for CIS design and optimization. The presented results demonstrate a methodological and technical capability for 3D  modeling optimization of complex CMOS image sensor.

Paper原文请查阅:

https://www.spiedigitallibrary.org/conference-proceedings-of-spie/9742/97420A/Toward-designing-back-illuminated-CMOS-image-sensor-based-on-3D/10.1117/12.2213549.short

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Modeling of InGaAs/AlGaAsSb APDs with high gain-bandwidth product

Yegao Xiao, Zhiqiang Li, Zhanming S. Li, “Modeling of InGaAs/AlGaAsSb APDs with high gain-bandwidth product,” Proc. SPIE 11498, Photonic Fiber and Crystal Devices: Advances in Materials and Innovations in Device Applications XIV, 114980R (20 August 2020); doi: 10.1117/12.2568197

ABSTRACT

Modeling of InGaAs/AlGaAsSb avalanche photodiodes (APDs) is presented in this work. Based on a drift-diffusion theory, the APD dark- and photo-current and multiplication gain are simulated. The frequency response and bandwidth are also computed based on a derived formalism by following the carrier transit analyses. Modeling results of I-V  curves, multiplication gain, breakdown voltage, excess noise factor, -3dB bandwidth and gain-bandwidth product are demonstrated. Some results are compared with the experimental report. The APD performance is further evaluated with respect to two of the key design factors, the multiplication and the absorption layer thickness, respectively.

Keywords: Avalanche photodiodes, optoelectronics, device modeling and CAD software, optic fiber telecommunication

1. INTRODUCTION

2. THEORETIC BACKGROUND AND RELEVANT SIMULATOR

3. DEVICE STRUCTURE AND SIMULATION DETAILS


Figure 1. (a) The simulated InGaAs/AlGaAsSb SAGCM APD schematic structure, and (b) equilibrium band diagram.

4. RESULTS, ANALYSES AND DSICUSSION


Figure 2. (a) Electric field profile, and (b) excess noise factor.

Figure 3. (a) Dark- (lower) and photo-I-V (upper) curves, and (b) multiplication gain vs reverse bias.

Figure 5. Effect of absorption layer thickness on (a) I-V curves and multiplication gain (inset), and (b) -3 dB bandwidth.

Figure 6. Effect of multiplication layer thickness on (a) I-V curves and multiplication gain (inset), and (b) -3 dB bandwidth.

5. SUMMARY

The 2D modeling of InGaAs/AlGaAsSb APDs is reported in this work. The APD dark- and photo-current and multiplication gain are simulated. The frequency response and bandwidth are also computed. Modeling results of I-V curves, multiplication gain, breakdown voltage, excess noise factor, -3dB bandwidth and gain-bandwidth product are demonstrated. 

The device performance is further simulated with respect to two of the key factors, the multiplication layer and the absorption layer thickness, respectively. Some results are compared with the experimental report and some are further discussed based on the simulation work presented.

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“以天之语,解物之道”

-记2020年11月5日,Crosslight相约交大李政道图书馆 – 一起感受科艺之美

2020年11月5日 – 秋日午后和煦的阳光下,Crosslight上海分公司员工代表一行在创始人李湛明博士的带领下,前往坐落于上海交通大学闵行校区的李政道图书馆参观学习。
该场馆设计立足于李政道先生三十一岁便获得诺贝尔物理学奖的辉煌成就,取用“山”的意象,意在激励青年学生和科技工作者坚持不懈、勇攀科学高峰。

场馆内最闪亮的展品 – 1957年李政道先生获得的诺贝尔奖章及证书

1957年,刚刚31岁的李政道与杨振宁因共同发现“弱相互作用中的宇称不守恒”获得“诺贝尔物理学奖”,两人成为历史上首获“诺贝尔物理学奖”的华人,而当时李政道是诺贝尔奖历史上第三年轻的获奖者。

走进图书馆大厅,抬头便可以看见天桥上的一行遒劲有力的浮雕汉字———“以天之语,解物之道”,这八个由李政道先生亲笔书写的汉字是他一生的追求、感悟与心声,同时也是李馆陈列展览的主题。


根据吴冠中先生的画作《对称呼,未必,且看柳与影、峰两侧》创作设计的雕塑,给参观者以视觉及情感上的震撼,全面展示李政道先生物理巨擘、赤子情怀、科艺双馨的人物特征。

真理的光芒(油画,吴正恭作)

1993年5月8日,梵蒂冈教皇保罗二世(左三)为伽利略平反,并为其所受的不公正待遇向全球科学家道歉,李政道(右三)代表全球科学家接受教皇道歉。

20世纪30、40年代中国各大学选用的第一本大学物理教材。
也就是这两本书,悄悄打开了年轻的李政道探寻物理的大门。
20世纪30、40年代美国普遍使用的大学普通物理学教科书。
此书为李政道在西南联大求学期间的自学教材。
1974年5月与毛主席的会谈

李政道在1974年第一次见到毛泽东,毛一见面就问他“为什么对称是重要的”,李政道抄起桌子上的本子和铅笔,给毛泽东作了一个小小的试验,他让铅笔在本子上来回滚动,然后对毛说,尽管没有一个瞬间是静止的,然而就整体而言,这个动力学的过程也有对称性;毛主席对什么是对称很有兴趣,他说,他一生经历的都是动荡,所以认为动是重要的。

李政道向毛主席建议要重视年轻科技人才的培养,进而促成‘少年班’的建立和全国性教学工作的恢复与发展。后又倡导成立了博士后流动站,选拔培养了大量物理方面的高级人才;

1984年,李政道向邓小平提出建议借鉴国外的博士后制度。

1980年,在中国没有托福和GRE、留学美国通道还未打开的情况下,李政道自己出资创建“中美联合招考物理研究生项目”,简称卡斯匹亚(CUSPEA)基金会。让中国学子得以留学美国。从1979-1989年差不多培养了1000个留学生。Crosslight公司创始人-李湛明博士就是CUSPEA基金会1981届前往留学的学生之一。

CUSPEA每年招收近百名中国学生,分布60余所一流大学,所有的招生往来信件都由李政道夫妇亲笔逐字书写,并推着小车辗转附近街区的各个邮筒投递;展馆的一角摆放的邮筒和信件展示了李政道先生对青年人才培养的重视和为之付出的艰辛努力;

Crosslight员工代表跟随讲解员参观学习 :

借用杜甫的诗句,同时也是李政道先生几十年科研之路的座右铭,作为今天参观学习的总结:

“细推物理须行乐,何用浮名绊此身。”

Crosslight公司也将秉承这样的务实理念,用心钻研技术、提高我们的产品和服务质量,和广大用户一起携手开创更美好的未来!

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