Complementary metal oxide semiconductor device with dual-well and manufacturing method thereof

摘要

The present invention discloses a dual-well complementary metal oxide semiconductor (CMOS) device and a manufacturing method thereof. The dual-well CMOS device includes a PMOS device region and an NMOS device region. Each of the PMOS and NMOS device regions includes a dual-well (which includes a P-well and an N-well), and each of the PMOS and NMOS device regions includes P-type and N-type lightly doped diffusions (PLDD and NLDD) regions respectively in different wells in the dual well. A separation region is located between the PMOS device region and the NMOS device region, for separating the PMOS device region and the NMOS device region. The depth of the separation region is not less than the depth of any of the P-wells and the N-wells in the PMOS device region and the NMOS device region.

主权项

1. A dual-well complementary metal oxide semiconductor (CMOS) device, comprising:
a substrate, including a top surface and a bottom surface opposite to the top surface in a vertical direction; an epitaxial layer, which is formed on and connects at least a portion of the top surface of the substrate, the epitaxial layer including an epitaxial top surface opposite to the top surface in the vertical direction; an isolation region, which is formed on the epitaxial layer, and configured to define an NMOS device region and a PMOS device region in the epitaxial layer; a first P-type well (P-well), which is formed in the NMOS device region of the epitaxial layer and located under the epitaxial top surface in the vertical direction; a P-type body region, which is formed on the first P-well in the epitaxial layer, and is located between the first P-well and the epitaxial top surface in the vertical direction; a first N-type well (N-well), which is formed in the NMOS device region of the epitaxial layer and located under the epitaxial top surface in the vertical direction, and connects the first P-well in a lateral direction, to form a first PN junction between the first N-well and the first P-well; a first gate, which is formed in the NMOS device region, and is stacked on and connects the epitaxial top surface in the vertical direction; a first P-type lightly doped diffusion (PLDD) region, which is formed on the first P-well in the epitaxial layer, and is located between the epitaxial top surface and the first P-well in the vertical direction; a first N-type lightly doped diffusion (NLDD) region, which is formed on the first N-well in the epitaxial layer, and is located between the epitaxial top surface and the first N-well in the vertical direction; an N-type source, which is formed on the first P-well in the epitaxial layer, and is located between the epitaxial top surface and the first P-well in the vertical direction, wherein the N-type source connects the P-type body region and the first PLDD region in the lateral direction; an N-type drain, which is formed on the first N-well in the epitaxial layer, and is located between the epitaxial top surface and the first N-well in the vertical direction, wherein the N-type drain connects the first NLDD region in the lateral direction; a second N-type well (N-well), which is formed in the PMOS device region of the epitaxial layer and located under the epitaxial top surface in the vertical direction; an N-type body region, which is formed on the second N-well in the epitaxial layer, and is located between the second N-well and the epitaxial top surface in the vertical direction; a second P-type well (P-well), which is formed in the PMOS device region of the epitaxial layer and located under the epitaxial top surface in the vertical direction, and connects the second N-well in the lateral direction, to form a second PN junction between the second N-well and the second P-well; a second gate, which is formed in the PMOS device region, and is stacked on and connects the epitaxial top surface in the vertical direction; a second N-type lightly doped diffusion (NLDD) region, which is formed on the second N-well in the epitaxial layer, and is located between the epitaxial top surface and the second N-well in the vertical direction; a second P-type lightly doped diffusion (PLDD) region, which is formed on the second P-well in the epitaxial layer, and is located between the epitaxial top surface and the second P-well in the vertical direction; a P-type source, which is formed on the second N-well in the epitaxial layer, and is located between the epitaxial top surface and the second N-well in the vertical direction, wherein the P-type source connects the N-type body region and the second NLDD region in the lateral direction; a P-type drain, which is formed on the second P-well in the epitaxial layer, and is located between the epitaxial top surface and the second P-well in the vertical direction, wherein the P-type drain connects the second PLDD region in the lateral direction; and a separation region, which is connected between the PMOS device region and the NMOS device region, for separating the PMOS device region and the NMOS device region, wherein a depth of the separation region, which is measured from the epitaxial top surface downward, is not smaller than a depth of any of the first P-well, the first N-well, the second N-type well, and the second P-well; wherein, the first PN junction is located between the first PLDD region and the first NLDD region; wherein, the second PN junction is located between the second PLDD region and the second NLDD region.