AI Article Synopsis
- The Raised Source/Drain (RSD) structure is utilized in thin film transistors to enhance device performance by reducing high impact ionization at the drain side through better electric field dispersion.
- This study evaluates how a vertical lightly doped drain (LDD) scheme can more effectively diminish the drain electric field compared to traditional RSD designs by simulating various structures and analyzing their output characteristics.
- Results indicate that while conventional devices and uniformly doped RSD structures exhibit similar electric fields, implementing a vertical LDD can lower the drain electric field significantly, suggesting that the pure RSD structure alone may not improve device characteristics without integrating LDD features.
Article Abstract
The raised source/drain (RSD) structure is one of thin film transistor designs that is often used to improve device characteristics. Many studies have mentioned that the high impact ionization rate occurring at a drain side can be reduced, owing to a raised source/drain area that can disperse the drain electric field. In this study, we will discuss how the electric field at the drain side of an RSD device is reduced by a vertical lightly doped drain (LDD) scheme rather than a RSD structure. We used different raised source/drain forms to simulate the drain side electric field for each device, as well as their output characteristics, using Integrated Systems Engineering (ISE-TCAD) simulators. Different source and drain thicknesses and doping profiles were applied to verify the RSD mechanism. We found that the electric fields of a traditional device and uniform doping RSD structures are almost the same (~2.9 × 10 V/cm). The maximum drain electric field could be reduced to ~2 × 10 V/cm if a vertical lightly doped drain RSD scheme was adopted. A pure raised source/drain structure did not benefit the device characteristics if a vertical lightly doped drain design was not included in the raised source/drain areas.
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| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC7912821 | PMC |
| http://dx.doi.org/10.3390/membranes11020103 | DOI Listing |
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