Your search keyword '"Over-etch"' showing total 7 results

1. Etch of nano-TSV with smooth sidewall and excellent selection ratio for backside power delivery network.

Author

Wang, Yang, Liu, Ziyu, Sun, Yabin, Chen, Lin, and Sun, Qingqing

Subjects

*INTEGRATED circuits, *POWER transistors, *ETCHING, *SILICON, *MORPHOLOGY

Abstract

Backside Power Delivery Network (BSPDN) is a crucial technology for integrated circuits at sub-3 nm technology nodes. The primary challenge resides in utilizing nano through silicon via (nano-TSV) to establish connections between the backside power network and buried power rails, thereby facilitating transistor powering. The key technology is to ensure a smooth sidewall morphology and prevent damage to buried power rails (BPR) due to over-etching. In this study, non-Bosch and Bosch techniques are compared using simulation. The results demonstrate that while the non-Bosch technique yields smooth sidewalls, it inevitably leads to over-etching, whereas Bosch effectively avoids over-etching. The etching of scallop-free nano-TSV is achieved by optimizing the Bosch process, which involves the use of inductively coupled plasma (ICP). Finally, metal filling of nano-TSV is successfully achieved. Thus, the nano-TSV etching method is established as viable for BSPDN. [Display omitted] • A nano-TSV etching method for BSPDN is established that achieves smooth sidewalls and no over-etching. • The manuscript compares the etching mechanism of non-Bosch and Bosch. • The etching method is compatible with existing processes. [ABSTRACT FROM AUTHOR]

Published

2025

2. Identification of MEMS Geometric Uncertainties through Homogenization.

Author

Faraci, David, Zega, Valentina, Nastro, Alessandro, and Comi, Claudia

Subjects

MICROELECTROMECHANICAL systems, FABRICATION (Manufacturing), AUXETIC materials, UNCERTAINTY, INTERFEROMETRY

Abstract

Fabrication imperfections strongly influence the functioning of Micro-Electro-Mechanical Systems (MEMS) if not taken into account during the design process. They must be indeed identified or precisely predicted to guarantee a proper compensation during the calibration phase or directly in operation. In this work, we propose an efficient approach for the identification of geometric uncertainties of MEMS, exploiting the asymptotic homogenization technique. In particular, the proposed strategy is experimentally validated on a MEMS filter, a device constituted by a complex periodic geometry, which would require high computational costs if simulated through full-order models. The complex periodic structure is replaced by an equivalent homogeneous medium, allowing a fast optimization procedure to identify imperfections by comparing a simplified analytical model with the experimental data available for the MEMS filter. The actual over-etch, obtained after the release phase, and the electrode offset of a fabricated MEMS filter are effectively identified through the proposed strategy. [ABSTRACT FROM AUTHOR]

Published

2022

3. Statistical Investigation of the Mechanical and Geometrical Properties of Polysilicon Films through On-Chip Tests.

Author

Mirzazadeh, Ramin, Ghisi, Aldo, and Mariani, Stefano

Subjects

SILICON films, MICROELECTROMECHANICAL systems, MECHANICAL behavior of materials

Abstract

In this work, we provide a numerical/experimental investigation of the micromechanics-induced scattered response of a polysilicon on-chip MEMS testing device, whose moving structure is constituted by a slender cantilever supporting a massive perforated plate. The geometry of the cantilever was specifically designed to emphasize the micromechanical effects, in compliance with the process constraints. To assess the effects of the variability of polysilicon morphology and of geometrical imperfections on the experimentally observed nonlinear sensor response, we adopt statistical Monte Carlo analyses resting on a coupled electromechanical finite element model of the device. For each analysis, the polysilicon morphology was digitally built through a Voronoi tessellation of the moving structure, whose geometry was in turn varied by sampling out of a uniform probability density function the value of the over-etch, considered as the main source of geometrical imperfections. The comparison between the statistics of numerical and experimental results is adopted to assess the relative significance of the uncertainties linked to variations in the micro-fabrication process, and the mechanical film properties due to the polysilicon morphology. [ABSTRACT FROM AUTHOR]

Published

2018

4. Identification of MEMS Geometric Uncertainties through Homogenization

Author

Alessandro Nastro, David Faraci, CLAUDIA COMI, and Valentina Zega

Subjects

MEMS, geometric uncertainties, over-etch, auxetic structure, asymptotic homogenization, General Medicine, MEMS, auxetic structure, geometric uncertainties, over-etch, asymptotic homogenization

Abstract

Fabrication imperfections strongly influence the functioning of Micro-Electro-Mechanical Systems (MEMS) if not taken into account during the design process. They must be indeed identified or precisely predicted to guarantee a proper compensation during the calibration phase or directly in operation. In this work, we propose an efficient approach for the identification of geometric uncertainties of MEMS, exploiting the asymptotic homogenization technique. In particular, the proposed strategy is experimentally validated on a MEMS filter, a device constituted by a complex periodic geometry, which would require high computational costs if simulated through full-order models. The complex periodic structure is replaced by an equivalent homogeneous medium, allowing a fast optimization procedure to identify imperfections by comparing a simplified analytical model with the experimental data available for the MEMS filter. The actual over-etch, obtained after the release phase, and the electrode offset of a fabricated MEMS filter are effectively identified through the proposed strategy.

Published

2022

5. Statistical Investigation of the Mechanical and Geometrical Properties of Polysilicon Films through On-Chip Tests

Author

Ramin Mirzazadeh, Aldo Ghisi, and Stefano Mariani

Subjects

polysilicon morphology, over-etch, sensitivity to imperfections, Mechanical engineering and machinery, TJ1-1570

Abstract

In this work, we provide a numerical/experimental investigation of the micromechanics-induced scattered response of a polysilicon on-chip MEMS testing device, whose moving structure is constituted by a slender cantilever supporting a massive perforated plate. The geometry of the cantilever was specifically designed to emphasize the micromechanical effects, in compliance with the process constraints. To assess the effects of the variability of polysilicon morphology and of geometrical imperfections on the experimentally observed nonlinear sensor response, we adopt statistical Monte Carlo analyses resting on a coupled electromechanical finite element model of the device. For each analysis, the polysilicon morphology was digitally built through a Voronoi tessellation of the moving structure, whose geometry was in turn varied by sampling out of a uniform probability density function the value of the over-etch, considered as the main source of geometrical imperfections. The comparison between the statistics of numerical and experimental results is adopted to assess the relative significance of the uncertainties linked to variations in the micro-fabrication process, and the mechanical film properties due to the polysilicon morphology.

Published

2018

6. On-Chip Assessment of Scattering in the Response of Si-Based Microdevices

Author

Aldo Ghisi and Stefano Mariani

Subjects

Microelectromechanical systems, Nanoelectromechanical systems, polysilicon morphology, over-etch, sensitivity to imperfections, Materials science, business.industry, Scattering, Characterization (materials science), Nonlinear system, Miniaturization, Optoelectronics, business, Reduction (mathematics), Microfabrication

Abstract

The response of micromachines to the external actions is typically affected by a scattering, which is on its own induced by their microstructure and by stages of the microfabrication process. The progressive reduction in size of the mechanical components, forced by a path towards (further) miniaturization, has recently enhanced the outcomes of the aforementioned scattering, and provided a burst in research activities to address issues linked to its assessment [1,2]. In this work, we discuss the features of an on-chip testing device that we purposely designed to efficiently estimate the two major sources of scattering affecting inertial, polysilicon-based micromachines: the morphology of the silicon film constituting the movable parts of the device, and the etch defect or overetch induced by microfabrication. The coupled electro-mechanical behavior of the statically determinate movable (micro)structure of the on-chip device has been modelled via beam bending theory [3], within which the aforementioned sources of scattering have been accounted for through local fluctuating fields in the compliant part of the structure itself, namely the supporting spring. The proposed stochastic model is shown to outperform former ones available in the literature [4,5], which neglected the simultaneous and interacting effects of the two mentioned sources on the measure response. The model can fully catch the scattering in the C-V plots up to pull-in, hence also in the nonlinear working regime of the device. References [1] Zhu, J.; Liu, X.; Shi, Q.; He, T.; Sun, Z.; Guo, X.; Liu, W.; Sulaiman, O.B.; Dong, B.; Lee, C. Development Trends and Perspectives of Future Sensors and MEMS/NEMS. Micromachines 2020, 11. [2] Molina, J.P.Q.; Rosafalco, L.; Mariani, S. Stochastic Mechanical Characterization of Polysilicon MEMS: A Deep Learning Approach. Proceedings 2020, 42. [3] Mirzazadeh, R.; Eftekhar Azam, S.; Mariani, S. Micromechanical Characterization of Polysilicon Films through On-Chip Tests. Sensors 2016, 16, 1191. [4] Mirzazadeh, R.; Ghisi, A.; Mariani, S. Statistical Investigation of the Mechanical and Geometrical Properties of Polysilicon Films through On-Chip Tests. Micromachines 2018, 9, 53. [5] Ghisi, A.; Mariani, S. Effect of imperfections due to material heterogeneity on the offset of polysilicon MEMS structures. Sensors 2019, 19, 3256.

Published

2021

7. Statistical Investigation of the Mechanical and Geometrical Properties of Polysilicon Films through On-Chip Tests

Author

Aldo Ghisi, Ramin Mirzazadeh, and Stefano Mariani

Subjects

polysilicon morphology, over-etch, sensitivity to imperfections, Materials science, Cantilever, lcsh:Mechanical engineering and machinery, Monte Carlo method, Probability density function, 02 engineering and technology, Article, 0203 mechanical engineering, Sampling (signal processing), lcsh:TJ1-1570, Electrical and Electronic Engineering, Over-etch, Polysilicon morphology, Sensitivity to imperfections, Control and Systems Engineering, Mechanical Engineering, Mechanics, 021001 nanoscience & nanotechnology, Finite element method, Computer Science::Other, Nonlinear system, 020303 mechanical engineering & transports, 0210 nano-technology, Voronoi diagram, MEMS testing

Abstract

In this work, we provide a numerical/experimental investigation of the micromechanics-induced scattered response of a polysilicon on-chip MEMS testing device, whose moving structure is constituted by a slender cantilever supporting a massive perforated plate. The geometry of the cantilever was specifically designed to emphasize the micromechanical effects, in compliance with the process constraints. To assess the effects of the variability of polysilicon morphology and of geometrical imperfections on the experimentally observed nonlinear sensor response, we adopt statistical Monte Carlo analyses resting on a coupled electromechanical finite element model of the device. For each analysis, the polysilicon morphology was digitally built through a Voronoi tessellation of the moving structure, whose geometry was in turn varied by sampling out of a uniform probability density function the value of the over-etch, considered as the main source of geometrical imperfections. The comparison between the statistics of numerical and experimental results is adopted to assess the relative significance of the uncertainties linked to variations in the micro-fabrication process, and the mechanical film properties due to the polysilicon morphology.

Published

2018