Abstract
The weak ESD-immunity problem has been deeply persecuted in ultra high-voltage (UHV) metal-oxide-semiconductor field-effect transistors (MOSFETs) and urgently needs to be solved. In this paper, a UHV 300 V circular n-channel (n) lateral diffused MOSFET (nLDMOS) is taken as the benchmarked reference device for the electrostatic discharge (ESD) capability improvement. However, a super-junction (SJ) structure in the drain region will cause extra depletion zones in the long drain region and reduce the peak value of the channel electric field. Therefore, it may directly increase the resistance of the device to ESD. Then, in this reformation project for UHV nLDMOSs to ESD, two strengthening methods were used. Firstly, the SJ area ratio changed by the symmetric eight-zone elliptical-cylinder length (X) variance (i.e., X = 5, 10, 15 and 20 μm) is added into the drift region of drain side to explore the influence on ESD reliability. From the experimental results, it could be found that the breakdown voltages (VBK) were changed slightly after adding this SJ structure. The VBK values are filled between 391 and 393.5 V. Initially, the original reference sample is 393 V; the VBK changing does not exceed 0.51%, which means that these components can be regarded as little changing in the conduction characteristic after adding these SJ structures under the normal operating conditions. In addition, in the ESD transient high-voltage bombardment situation, the human-body model (HBM) capability of the original reference device is 2500 V. Additionally, as SJs with the length X high-voltage P-type well (HVPW) are inserted into the drain-side drift region, the HBM robustness of these UHV nLDMOSs increases with the length X of the HVPW. When the length X (HVPW) is 20 μm, the HBM value can be upgraded to a maximum value of 5500 V, the ESD capability is increased by 120%. A linear relationship between the HBM immunity level and area ratio of SJs in the drains side in this work can be extracted. The second part revealed that, in the symmetric four-zone elliptical cylinder SJ modulation, the HBM robustness is generally promoted with the increase of HVPW SJ numbers (the highest HBM value (4500 V) of the M5 device improved by 80% as compared with the reference device under test (DUT)). Therefore, from this work, we can conclude that the addition of symmetric elliptical-cylinder SJ structures into the drain-side drift region of a UHV nLDMOS is a good strategy for improving the ESD immunity.
Highlights
The lateral double-diffused metal-oxide-semiconductor field-effect transistors (MOSFETs) (LDMOS transistor) is the major dominant power component in the fabrication of power integrated circuits (PICs) because of many excellent electrical characteristicsElectronics 2020, 9, 730; doi:10.3390/electronics9050730 www.mdpi.com/journal/electronicsElectronics 2020, 9, 730 such as low on-resistance, high input-impedance, fast switching-speed and high breakdown-voltage.By the same token, due to the advantages of lower on-resistance and high voltage sustaining, ultra high-voltage (UHV) n-channel lateral diffused MOSFET devices have been commonly installed in many lighting, power-management systems, automotive systems, and 5G communication fields [1–16].Even these UHV LDMOSs can be operated at very high voltage purposes, but compared with low-voltage (LV) and medium-voltage (MV) circuits, the electrostatic-discharge (ESD) immunity of UHV LDMOS related components is very feeble [17–28]
From this work, we can conclude that the addition of symmetric elliptical-cylinder SJ structures into the drain-side drift region of a UHV n-channel lateral diffused MOSFET (nLDMOS) is a good strategy for improving the electrostatic discharge (ESD) immunity
A UHV nLDMOS component is mainly used in input/output (I/O) blocks and switching circuits, and it acts as a UHV device and at the same time as a self-protection ESD unit
Summary
The lateral double-diffused MOSFET (LDMOS transistor) is the major dominant power component in the fabrication of power integrated circuits (PICs) because of many excellent electrical characteristics. Due to the advantages of lower on-resistance and high voltage sustaining, UHV n-channel lateral diffused MOSFET (nLDMOS) devices have been commonly installed in many lighting, power-management systems, automotive systems, and 5G communication fields [1–16]. Even these UHV LDMOSs can be operated at very high voltage purposes, but compared with low-voltage (LV) and medium-voltage (MV) circuits, the electrostatic-discharge (ESD) immunity of UHV LDMOS related components is very feeble [17–28]. How does this architecture change the HBM ESD capabilities of a UHV circular nLDMOS with elliptical cylinder n+ super-junctions (SJs) structure? In order to realize these experimental samples, a TSMC 0.5 μm UHV bipolar-CMOS-DMOS (BCD)
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Disclaimer: All third-party content on this website/platform is and will remain the property of their respective owners and is provided on "as is" basis without any warranties, express or implied. Use of third-party content does not indicate any affiliation, sponsorship with or endorsement by them. Any references to third-party content is to identify the corresponding services and shall be considered fair use under The CopyrightLaw.