A kind of anti-electrostatic protecting structure that is used for the gate coupled of high voltage drain expansion NMOS
Technical field
The present invention relates to a kind of anti-electrostatic protecting structure, relate in particular to a kind of anti-electrostatic protecting structure that is used for the gate coupled of high voltage drain expansion NMOS.
Background technology
As shown in Figure 1, be the NMOS structural representation of prior art, form by grid, drain electrode, source electrode.
Current popular at present technology uses CMOS as antistatic (ESD) protection device, and when static entered, the electrostatic charge of releasing can cause the parasitic triode conducting of protection tube NMOS, can produce rapid rapidly phenomenon of returning (Snap back).As shown in Figure 2, before entering the BC zone of normal cascading water state, protection tube need reach the cut-in voltage that A is ordered.Substrate current and resistance substrate decision that cut-in voltage is formed by the PN junction reverse leakage that drains; because effective resistance substrate that can cause NMOS placed in the middle on the circuit structure is bigger than both sides; therefore NMOS placed in the middle is easier to be opened in advance, and this moment both sides protection tube do not reach the condition of unlatching.The protection tube cut-in voltage Vtl that is connected in parallel like this differs, if all protection tubes can not be opened cascading water as far as possible, under strong electrostatic impact, protection tube will damage.
In order to improve the unlatching chance of parasitic triode, increasing gate coupled technology (Gate Coupled) on the technical foundation of GGNMOS (gate grounded NMOS) again---between grid and ground connection, be connected the shallow injecting structure resistance of N type.This can cause at the current potential that static grid when drain electrode enters is arranged by the gate leakage capacitance pull-up, helps the parasitic triode conducting of protection tube NMOS to produce bigger substrate current.
Summary of the invention
The technical problem to be solved in the present invention provides a kind of when static takes place, thereby can effectively open release a kind of electrostatic protection device of electrostatic charge of NMOS parasitic triode.
For solving the problems of the technologies described above, the anti-electrostatic protecting structure that the present invention is used for the gate coupled of high voltage drain expansion NMOS increases the shallow injecting structure resistance of N type that utilizes metal silicide to stop technology formation outside original NMOS structure.
The present invention is owing to increase the shallow injecting structure resistance of N type outside original NMOS structure; thereby draw high grid voltage and form a peak value; and substrate current also can increase along with the increase of grid voltage; this also more helps the unlatching of NMOS parasitic NPN triode, thus the better protection protection tube.
Description of drawings
Fig. 1 is the NMOS structure chart of prior art;
Fig. 2 is the phenomenon that snaps back that prior art produces when static enters when using CMOS as anti-electric protective component;
Fig. 3 is the NMOS structure chart of a kind of anti-electrostatic protecting structure of a kind of gate coupled that is used for high voltage drain expansion NMOS of the present invention;
Fig. 4 is the high pressure NMOS profile of low-doped drain of gate coupled of a kind of anti-electrostatic protecting structure of a kind of gate coupled that is used for high voltage drain expansion NMOS of the present invention.
Embodiment
The present invention is further detailed explanation below in conjunction with accompanying drawing.
The present invention at first describes for the operating state of GGNMOS (gate grounded NMOS) when static enters, because the base stage (P type substrate) of the NPN triode of NMOS parasitism should be in forward conduction with the PN junction of source electrode when cascading water, so the bias voltage that adds on the base stage should be than the high 0.7V of source electrode, this bias voltage is relevant with substrate current and resistance substrate, under the constant situation of resistance substrate, substrate current is big more, and the bias voltage on the base stage is big more, and then the parasitic NPN triode more can easier conducting.
The present invention on original NMOS structure (as Fig. 3) increases and to utilize metal silicide to stop the shallow injecting structure resistance of N type that technology forms, and described novel NMOS structure is by the grid connection that is coupled, as shown in Figure 4.When static entered, the voltage of drain electrode increased, because the parasitic capacitance between grid and the drain electrode causes grid potential to be drawn high, electric charge flows to ground connection by the resistance that the shallow injecting structure of N type that increases forms; Because hot carrier's effect, if Vds is certain, when Vgs increased to some values, substrate current can increase to a peak value, has caused the increase of substrate current like this, the also easier conducting of parasitic NPN triode.Cause the very low problem of bleed off electrostatic capacity because of cut-in voltage is inhomogeneous with regard to having solved like this.