CN205595332U - Single channel transient voltage inhibitor - Google Patents

Abstract

Single channel transient voltage inhibitor is disclosed. Single channel transient voltage inhibitor includes semiconductor substrate, be located first doped region among the semiconductor substrate, be located the last epitaxial layer of semiconductor substrate, follow the epitaxial layer surface extends to electrically conductive passageway among the semiconductor substrate, be located second doped region in the epitaxial layer, and be located third doped region in the second doped region. Single channel transient voltage inhibitor includes punch through diode, first doped region the second doped region and the conduct respectively of third doped region punch through diode's collecting zone, base region and launch site, electrically conductive passageway with the semiconductor substrate contact, and with first doped region with at least one contact in the epitaxial layer, the second doped region is located first doped region top and with electrically conductive passage partition opens. This single channel transient voltage inhibitor adopts punch through diode to reduce operating voltage to improve the static electricity discharge ability under the high -power.

Description

Single channel Transient Voltage Suppressor

Technical field

This utility model relates to microelectronics technology, more particularly, to single channel transient voltage Suppressor.

Background technology

Transient Voltage Suppressor TVS (Transient Voltage Suppressor) is at stabilivolt base The high-effect circuit brake of development on plinth.The profile of TVS diode is as good as with common stabilivolt, But, due to special structure and technological design, the transient response speed of TVS diode and surge Absorbability is far above common stabilivolt.Such as, the response time of TVS diode is only 10^-12 Second, and the surge power of the most thousands of watts can be absorbed.Under the conditions of applied in reverse, when bearing During one high-octane big pulse, the working impedance of TVS diode can quickly be down to extremely low conducting Value, thus allow big electric current to pass through, meanwhile, by voltage clamp at predeterminated level.Therefore, TVS Diode can protect the precision components in electronic circuit from the damage of various surge pulse effectively Bad.

In the Chinese patent application of Application No. CN201420858051.3, disclose a kind of by Three integrated TVS device formed on a single die of discrete device.As it is shown in figure 1, this TVS Device includes the first diode D1, the second diode D2 and Zener diode ZD, wherein first Diode D1 and Zener diode ZD differential concatenation.First diode D1 and Zener diode Anode connects signal end I/O and earth terminal GND, the negative electrode of the second diode D2 and anode respectively Connect signal end I/O and earth terminal GND respectively.When surge occurs, if at signal end I/O And between earth terminal, bear positive voltage, and the numerical value of positive voltage hitting higher than Zener diode ZD Wear voltage, then produce along the forward of the first diode and the electric current of the reverse flow of Zener diode, Thus play the effect of ESD protection.If bearing negative voltage between signal end I/O and earth terminal, The most only second diode D2 forward conduction.

It is unidirectional device in the TVS device shown in Fig. 1, wherein, common commutation diode conduct The additional capacitor of small capacitances value, connects with Zener diode.The capacitance of this TVS device will depend on Capacitance in additional capacitor.This TVS device is included in multiple deviding devices integrated in a chip Part, thus significantly reduce packaging cost, but processing technology is relative complex.Do not considering work On the premise of skill complexity and cost, it is possible to achieve low electric capacity unidirectional ESD protection function.

But, owing to the characteristic of Zener diode limits, this TVS can not realize low-work voltage. In Zener diode, if, with highly doped reduction running voltage, then leakage current also can increase. In order to take into account leakage current and doping content that running voltage needs to control in Zener diode as a result, The running voltage of Zener diode is usually less than 5V.The restriction of this running voltage also causes TVS Transient power be restricted so that TVS may not apply in high-power applications.

Therefore, it is desirable to develop novel TVS device, reduce the running voltage of TVS further, Thus improve high-power under Electro-static Driven Comb ability.

Utility model content

The technical problems to be solved in the utility model is to provide and a kind of uses break-over diode to realize TVS device.

According to one side of the present utility model, it is provided that a kind of single channel Transient Voltage Suppressor, including: The Semiconductor substrate of the first doping type；The second doping type being positioned in described Semiconductor substrate First doped region, wherein the second doping type and the first doping type are contrary；It is positioned at described quasiconductor The epitaxial layer of the second doping type on substrate；Extend to described first from described epi-layer surface mix The conductive channel in miscellaneous district；Second doped region of the first doping type being positioned in described epitaxial layer；With And the 3rd doped region of the second doping type being positioned in described second doped region, wherein, described list Channel instantaneous voltage suppressor includes break-over diode, described first doped region, described second doping District and described 3rd doped region are respectively as collecting zone, base and the transmitting of described break-over diode District, described conductive channel contacts with described Semiconductor substrate, and with described first doped region and described At least one contact in epitaxial layer, described second doped region be positioned at above described first doped region and Separate with described conductive channel.

Preferably, when described break-over diode turns on, current path include described 3rd doped region, Described second doped region, described first doped region and described conductive channel and described quasiconductor lining The end.

Preferably, also include: the 4th of the second doping type being positioned in described Semiconductor substrate mixes Miscellaneous district；And the 6th doped region of the first doping type being positioned in described epitaxial layer, wherein, institute State single channel Transient Voltage Suppressor and also include the first diode, described 6th doped region and described outside Prolong layer respectively as the anode of described first diode and negative electrode.

Preferably, also include that the second diode, described Semiconductor substrate and described epitaxial layer are made respectively Anode and negative electrode for described second diode.

Preferably, described single channel Transient Voltage Suppressor has signal end and an earth terminal, and described The negative electrode of one diode and the launch site of described break-over diode are electrically connected to each other, described one or two pole The anode of pipe and the collecting zone of described break-over diode connect described signal end and described earth terminal respectively, The negative electrode of described second diode and anode connect described signal end and described earth terminal respectively.

Preferably, also include the 5th doped region of the second doping type being positioned in described epitaxial layer, Described 5th doped region is around described 6th doped region, wherein, and described 5th doped region and described the Three doped region electrical connections.

Preferably, also include the 7th doped region of the second doping type being positioned in described epitaxial layer, Described 7th doped region is positioned at the region of described second diode, and with described 6th doped region Electrical connection.

Preferably, described first diode, described second diode and described break-over diode use Public described Semiconductor substrate.

Preferably, also include the isolation area of the first doping type being positioned in described epitaxial layer, described It is respective that isolation area limits described first diode, described second diode and described break-over diode Active area.

Preferably, the first doping type is one of N-type and p-type, the second doping type be N-type and Another in p-type.

Single channel Transient Voltage Suppressor according to embodiment of the present utility model uses break-over diode. Owing to the breakdown voltage of break-over diode is much smaller than Zener diode, therefore can reduce single channel wink The running voltage of state voltage suppressor, for example, it is possible to realize the multiple work such as 2.8V, 3.3V, 5V Make voltage, thus improve high-power under Electro-static Driven Comb ability.Further, owing to using conduction Passage by described epitaxial layer and described Semiconductor substrate short circuit each other, even if this break-over diode based on Vertical NPN structural laminate, it is also possible to use as planar device.Therefore, this single channel transient state Voltage suppressor can use selectively as vertical devices or horizontal device.

In a preferred embodiment, the first diode and the second diode are integrated in break-over diode In same chip.Owing to using conductive channel by described epitaxial layer and described Semiconductor substrate each other Short circuit, the first diode and the second diode and break-over diode can use public doping partly to lead Body substrate, thus easily three is integrated in a chip.Press down at this single channel transient voltage In device processed, using common commutation diode as the additional capacitor of small capacitances value, with break-over diode Series connection.The commutation diode utilizing series connection reduces the capacitance of this single channel Transient Voltage Suppressor, Thus improve the transient response speed of this single channel Transient Voltage Suppressor.

Additionally, the processing technology of this single channel Transient Voltage Suppressor and traditional bipolar transistor plumber Skill is compatible, and can be the most permissible when commutation diode and break-over diode being integrated Minimize the quantity of semiconductor layer and/or doped region, such that it is able to avoid single channel transient voltage to suppress The structure complication of device and dramatically increasing of manufacturing cost.

Accompanying drawing explanation

By description to this utility model embodiment referring to the drawings, of the present utility model above-mentioned And other objects, features and advantages will be apparent from, in the accompanying drawings:

Fig. 1 illustrates the circuit diagram of the Transient Voltage Suppressor according to prior art；

Fig. 2 illustrates the circuit diagram of the single channel Transient Voltage Suppressor according to embodiment；

Fig. 3 illustrates cutting of the single channel Transient Voltage Suppressor according to this utility model first embodiment Face figure；

Fig. 4 illustrates cutting of the single channel Transient Voltage Suppressor according to this utility model the second embodiment Face figure；

Fig. 5 a to 5h illustrates each rank of manufacture method of single channel Transient Voltage Suppressor shown in Fig. 4 The sectional view of section.

Detailed description of the invention

It is more fully described this utility model hereinafter with reference to accompanying drawing.In various figures, identical Element uses similar reference to represent.For the sake of clarity, the various piece in accompanying drawing does not has Have drawn to scale.Furthermore, it is possible to not shown part known to some.

Should be appreciated that when describing certain structure, when by one layer, a region is referred to as being positioned at another When layer, another region " above " or " top ", can refer to be located immediately at another layer, another Above individual region, or between floor, another region, also comprise other Ceng Huo district itself and another Territory.Further, if this structure is overturn, this layer, region will be located in another layer, another Individual region " below " or " lower section ".If being located immediately at another layer, another region to describe Above scenario, will use " A is directly on B " or " A on B and therewith neighbour herein Connect " form of presentation.

In the following description, the doping type describing semi-conducting material is specially p-type and N-type One of.It is appreciated that if inverting the doping type of each semi-conducting material, it is also possible to obtain phase The semiconductor device of congenerous.

This utility model can present in a variety of manners, some of them example explained below.

Fig. 2 illustrates the circuit diagram of the single channel Transient Voltage Suppressor according to embodiment.Such as figure Shown in 2, this TVS device includes the first diode D1, the second diode D2 and break-over diode D0.Different from conventional diode, break-over diode D0 has the knot being similar to bipolar transistor Structure, such as NPN transistor, including emitter stage, base stage and colelctor electrode.At work, break-through two The open base of pole pipe, applies voltage between emitter and collector.By optimizing launch site, base District and the doping content of collecting zone so that break-over diode produces between launch site-base or collecting zone Punch-through breakdown is there is between-base.

First diode D1 and break-over diode D0 series connection.The negative electrode of the first diode D1 and wearing The emitter stage of logical diode is connected to each other, the anode of the first diode D1 and the collection of break-over diode Electrode connects signal end I/O and earth terminal GND, the negative electrode of the second diode D2 and anode respectively Connect signal end I/O and earth terminal GND respectively.When surge occurs, if at signal end I/O And between earth terminal, bear positive voltage, and the numerical value of positive voltage hitting higher than break-over diode D0 Wear voltage, then produce along the forward of the first diode and the electric current of the forward flow of break-over diode, Thus play the effect of ESD protection.If bearing negative voltage between signal end I/O and earth terminal, The most only second diode D2 forward conduction.

Similar with the TVS device shown in Fig. 1, it is unidirectional device in the TVS device shown in Fig. 2, Wherein, common commutation diode, as the additional capacitor of small capacitances value, is connected with break-over diode. The capacitance of this TVS device will depend upon which the capacitance of additional capacitor.Utilize rectification two pole of series connection Pipe reduces the capacitance of TVS device, thus improves the transient response speed of TVS device.Enter one Step ground, uses break-over diode, due to the breakdown voltage of break-over diode in above-mentioned TVS device Much smaller than Zener diode, the running voltage of TVS device therefore can be reduced, for example, it is possible to real The multiple running voltages such as existing 2.8V, 3.3V, 5V.

It should be noted that, break-over diode can also be used alone as TVS device.Now, TVS device It is bilateral device, and still can realize low-work voltage.But, with the TVS shown in Fig. 2 Device is compared, and is used alone break-over diode and causes transient response speed to reduce in TVS device.

Fig. 3 illustrates cutting of the single channel Transient Voltage Suppressor according to this utility model first embodiment Face figure.In this embodiment, it is shown that break-over diode is used alone as the situation of TVS device.At this In embodiment, the break-over diode that TVS device 100 is single use.

As it is shown on figure 3, TVS device 100 includes Semiconductor substrate 101, is positioned at Semiconductor substrate The first doped region 102, the epitaxial layer 104 being positioned in Semiconductor substrate 101 in 101, be positioned at outside Prolong the isolation area 105 in layer 104, extend to leading Semiconductor substrate 101 from epitaxial layer 104 Electric channel 115 and the second doped region 108 and be positioned at the 3rd doping in the second doped region 108 District 110.

Semiconductor substrate 101 the most heavily doped P-type semiconductor substrate, epitaxial layer 104 is such as It it is lightly doped N doped epitaxial layer.In an example, Semiconductor substrate 101 e.g. monocrystalline Silicon substrate, epitaxial layer 104 e.g. silicon epitaxy layer, and it is respectively adopted the doping of suitable adulterant Become desired doping type.

In order to form p-type or n type semiconductor layer or region, can mix in semiconductor layer and region Enter the adulterant of respective type.Such as, P-type dopant include boron, N type dopant include phosphorus or Arsenic or antimony.

In this embodiment, Semiconductor substrate 101 is about 0.002～0.02 Ω cm's for resistivity Heavily doped P-type silicon substrate.Epitaxial layer 104 is lightly doped n type silicon epitaxy layer, and its resistivity is about 0.1 Ω cm～1000 Ω cm, thickness about 2 microns～100 microns.

Isolation area 105 the most heavily doped p-type doped region.Isolation area 105 is from epitaxial layer 104 Surface extend to described Semiconductor substrate 101, thus in epitaxial layer 104, limit TVS device Active area.Those skilled in the art can control isolation area concentration according to device requirement, for example, 10¹⁸cm^-3～10²⁰cm^-3Magnitude.

First doped region 102 the most heavily doped n-type doping district, is used for forming break-over diode Collecting zone.First doped region 102 is positioned in Semiconductor substrate 101, and conductive channel 115 is from outward The surface prolonging layer 104 extends in Semiconductor substrate 101.First doped region 102 and isolation area 105 Together, a part for epitaxial layer 104 being defined to semiconductor island, wherein the first doped region 102 is used In the bottom of restriction semiconductor island, isolation area 105 is for limiting the sidewall of semiconductor island.Second mixes Miscellaneous district 108 is positioned in semiconductor island, be positioned at above the first doped region 102 and with the second doped region 108 Separate.Further, conductive channel 115 contacts with Semiconductor substrate 101, and mixes with first Miscellaneous district 102 contacts with at least one in epitaxial layer 104.First doped region 102 will be located in break-through On the current path of diode, its concentration will affect the conducting resistance of break-over diode, this area skill Art personnel can control the concentration of the first doped region 102 according to device requirement, but described first adulterates If it is too low that the concentration in district 102 is arranged, by the current capacity of serious constraint device, therefore should control Not less than 10¹⁹cm^-3The order of magnitude.

Second doped region 108 e.g. p-type doped region, for forming the base of break-over diode. Second doped region 108 is the doped region formed in epitaxial layer 104.As it has been described above, the second doping District 108 is positioned at above the first doped region 102 and separates with conductive channel 115.Second doped region 108 for example, ion implantings 10¹³cm^-2～10¹⁵cm^-2After the ion of magnitude and carry out anneal formation mix Miscellaneous district.

3rd doped region 110 the most heavily doped n-type doping district, is used for forming break-over diode Launch site.3rd doped region 110 extends to the second doped region from the surface of the second doped region 108 Desired depth position in 108.The doping content of the 3rd doped region 110 is for example, 10¹⁸cm^-3～10²⁰cm^-3Magnitude.

Further, TVS device 100 also includes interlayer insulating film the 112, first electrode 121 and Supplemantary electrode the 122, second electrode 131.

First electrode 121 is electrically connected through the opening in interlayer insulating film 112 and the 3rd doped region 110 Connect.Alternatively, supplemantary electrode 122 is through the opening in interlayer insulating film 112 and conductive channel 115 Electrical connection.Second electrode 131 is formed relative with the surface of epitaxial layer 104 with Semiconductor substrate 101 Another surface contact.Interlayer insulating film 112 is such as made up of silicon oxide or silicon nitride, and first Electrode 121 and supplemantary electrode the 122, second electrode 131 such as by selected from gold, silver, copper, aluminum, The metal or alloy compositions such as aluminum silicon, aluminum copper silicon, titanium silver, titanium nickel gold.

In the TVS device 100 shown in Fig. 3, Semiconductor substrate the 101, first doped region 102, Second doped region the 108, the 3rd doped region 110 constitutes the lamination of PNPN structure.Owing to conduction is logical Road 115 is by Semiconductor substrate 101 and epitaxial layer 104 short circuit, therefore, and folding of this PNPN structure Layer practical function is identical with the lamination of NPN structure.When break-over diode turns on, the flowing of electric current Direction as shown by the dotted line in fig. 3, i.e. electric current from the 3rd doped region 110 via the second doped region 108, First doped region 102 and conductive channel 115 flow to Semiconductor substrate 101.

In this embodiment, the first electrode 121 electrically connects with the 3rd doped region 110, the second electrode 131 electrically connect with Semiconductor substrate 101, respectively as the emitter and collector of break-over diode. In alternate embodiments, it is possible to use supplemantary electrode 122 is as colelctor electrode, thus saves second Electrode 131.Even if this break-over diode is based on vertical NPN structural laminate, it is also possible to as flat Face device uses.Therefore, the TVS device according to this embodiment can be selectively as plumb Part or horizontal device use so that break-over diode can be easily integrated with other devices same In individual chip.

Fig. 4 illustrates cutting of the single channel Transient Voltage Suppressor according to this utility model the second embodiment Face figure.TVS device 200 is unidirectional device, and former with the circuit of the TVS device shown in Fig. 2 Reason is consistent.That is, TVS device 200 is possible not only to realize low-work voltage, and by break-through two Pole pipe is integrated in same chip with commutation diode, such that it is able to improve transient response speed.

As shown in Figure 4, TVS device 200 is included in public Semiconductor substrate 101 formation First diode D1, the second diode D2 and break-over diode D0.In this embodiment, every Extend to described Semiconductor substrate 101 from the surface of epitaxial layer 104 from district 105, thus in extension Layer 104 limits the first diode D1, the second diode D2 and break-over diode D0 respective Active area.The structure of this break-over diode D0 is identical with the TVS device shown in Fig. 3, the most not Describe in detail again.

TVS device 200 also includes the 4th doped region 103, the position being positioned in Semiconductor substrate 101 The 5th doped region the 107, the 6th doped region 109 and the 7th doped region 111 in epitaxial layer 104.

In the active area of the first diode D1, Semiconductor substrate 101 and the 4th doped region 103 Form reverse PN junction so that the first diode D1 is spaced apart with Semiconductor substrate 101.5th Doped region 107 the most heavily doped n-type doping district, from the surface of epitaxial layer 104 extends to Prolong desired depth position in layer 104.6th doped region 109 e.g. p-type doped region, from extension The surface of layer 104 extends to desired depth position in epitaxial layer 104.6th doped region 109 is with outer Prolong layer 104 and form PN junction, respectively as anode and the negative electrode of the first diode D1.

The doping content for example, 10 of the 4th doped region 103¹⁸cm^-3～10²⁰cm^-3Magnitude.5th doped region The doping content of 107 for example, 10¹⁸cm^-3～10²⁰cm^-3Magnitude.6th doped region 109 for example, from Son injects 10¹³cm^-2～10¹⁵cm^-2After the ion of magnitude and carry out annealing formed doped region.

5th doped region 107 is conducive to reducing the dead resistance of the first diode D1.Substitute In embodiment, the 5th doped region 107 can be saved.

In the active area of the second diode D2, Semiconductor substrate 101 is formed with epitaxial layer 104 PN junction, respectively as anode and the negative electrode of the second diode D2.7th doped region 111 is e.g. Heavily doped n-type doping district, extends to pre-depthkeeping epitaxial layer 104 from the surface of epitaxial layer 104 Degree position.

The doping content for example, 10 of the 7th doped region 111¹⁸cm^-3～10²⁰cm^-3Magnitude.

7th doped region 111 is conducive to reducing the dead resistance of the second diode D2.Substitute In embodiment, the 7th doped region 111 can be saved.

Further, TVS device 200 also includes the 3rd electrode 123, the 4th electrode 124 and Five electrodes 125.

3rd electrode 123 is electrically connected through the opening in interlayer insulating film 112 and the 6th doped region 109 Connecing, the 4th electrode 124 is electrically connected through the opening in interlayer insulating film 112 and the 7th doped region 111 Connecing, the 5th electrode 125 is electrically connected through the opening in interlayer insulating film 112 and the 5th doped region 107 Connect.3rd electrode the 123, the 4th electrode 124 and the 5th electrode 125 such as by selected from gold, silver, The metal or alloy compositions such as copper, aluminum, aluminum silicon, aluminum copper silicon, titanium silver, titanium nickel gold.

In the TVS device 200 shown in Fig. 4, additional interconnection or bonding line can be used, will First electrode 121 and the 5th electrode 125 are connected to each other, by the 3rd electrode 123 and the 4th Electrode 124 is connected to each other, and collectively as the signal end I/O of TVS device, second Electrode 131 is then as the receiving terminal GND of TVS device.

In this embodiment, owing to conductive channel 115 is by Semiconductor substrate 101 and epitaxial layer 104 Short circuit, therefore, the lamination practical function of the PNPN structure in break-over diode D0 is tied with NPN The lamination of structure is identical.This break-over diode D0 can use P-type semiconductor substrate, namely permissible Use public Semiconductor substrate 101 with the first diode D1 and the second diode D2, thus hold Change places and the first diode D1, the second diode D2 and break-over diode D0 are integrated in a core In sheet.

In TVS device 200, using common commutation diode as the additional capacitor of small capacitances value, Connect with break-over diode.The commutation diode utilizing series connection reduces the capacitance of TVS device, from And improve the transient response speed of TVS device.Further, use in above-mentioned TVS device Break-over diode, owing to the breakdown voltage of break-over diode is much smaller than Zener diode, the most permissible Reduce the running voltage of TVS device, for example, it is possible to realize the multiple work such as 2.8V, 3.3V, 5V Make voltage.

Fig. 5 a to 5h illustrates each rank of manufacture method of single channel Transient Voltage Suppressor shown in Fig. 4 The sectional view of section.

As shown in Figure 5 a, in Semiconductor substrate 101, shape the first doped region 102 and the 4th is mixed successively Miscellaneous district 103.

Semiconductor substrate 101 the most heavily doped P-type semiconductor substrate.In an example, Semiconductor substrate 101 e.g. monocrystalline substrate, the resistivity of described monocrystalline substrate is e.g., about 0.002～0.02 Ω cm.

First doped region 102 and the 4th doped region 103 are heavily doped n-type doping district the most respectively. In this example, the first doped region 102 uses phosphorus as adulterant, and doping content controls the least In 10¹⁹cm^-3The order of magnitude.4th doped region 103 uses antimony as adulterant, and doping content is such as It is 10¹⁸cm^-3～10²⁰cm^-3Magnitude.

The doping process of quasiconductor is known, uses suitable adulterant to mix in a semiconductor material Miscellaneous can obtain desired doping type.In order to form p-type or n type semiconductor layer or region, can To mix the adulterant of respective type in semiconductor layer and region.Such as, P-type dopant includes Boron, N type dopant includes phosphorus or arsenic or antimony.Doping process can include the thermal annealing added, example If the high annealings of more than 1000 DEG C are to activate adulterant.

Subsequently, Semiconductor substrate 101 forms epitaxial layer 104, as shown in Figure 5 b.

Epitaxial layer 104 can use known depositing operation to be formed.Such as, depositing operation can be Selected from electron beam evaporation (EBM), chemical gaseous phase deposition (CVD), ald (ALD), One in sputtering.In this embodiment, epitaxial layer 104 the most lightly doped N doped epitaxial Layer, resistivity is about 0.1 Ω cm～1000 Ω cm, thickness about 2 microns～100 microns.

Subsequently, epitaxial layer 104 forms insulating barrier 112, as shown in Figure 5 c.

Insulating barrier 112 can use sputtering or thermal oxide to be formed.Such as, insulating barrier 112 is hot oxygen Change formed silicon oxide layer, in follow-up doping step, insulating barrier 112 as protective layer, and And using the interlayer insulating film as resulting devices.

Subsequently, epitaxial layer 104 sequentially forms isolation area 105, and the 5th doped region 107, As shown in Figure 5 c.

Isolation area 105 the most heavily doped p-type doped region, doping content is for example, 10¹⁸cm^-3～10²⁰cm^-3Magnitude.Isolation area 105 extends to from the surface of epitaxial layer 104 described partly lead Body substrate 101, is separated into three regions by epitaxial layer 104, be respectively used to limit the first diode, Second diode and the active area of break-over diode.Additionally, this isolation area 105 and Semiconductor substrate 101 are connected.

5th doped region 107 the most heavily doped n-type doping district, doping content is not less than 10¹⁹cm^-3The order of magnitude.5th doped region 107 extends to epitaxial layer one from the surface of epitaxial layer 104 Depthkeeping degree.

Subsequently, in the region of break-over diode, epitaxial layer 104 forms the second doped region 108, As fig 5d.

Second doped region 108 e.g. p-type doped region, for forming the base of break-over diode. Second doped region 108 by epitaxial layer 104 be positioned at above the first doped region 102 at least some of Region transoid.

Subsequently, in the first diode area, form the 6th doped region 109 in the epitaxial layer, as Shown in Fig. 5 e.

6th doped region 109 the most heavily doped p-type doped region, described p-type doped region is such as For ion implanting 10¹³cm^-2～10¹⁵cm^-2After the ion of magnitude and carry out annealing formed doped region.The Six doped regions 109 extend to desired depth position epitaxial layer 104 from the surface of epitaxial layer 104. 6th doped region 109 forms PN junction, respectively as the sun of the first diode D1 with epitaxial layer 104 Pole and negative electrode.

Subsequently, in the region of break-over diode, the second doped region 108 forms the 3rd doping District 110, in the region of the second diode, forms the 7th doped region 111 in epitaxial layer 104, As shown in figure 5f.

3rd doped region 110 and the 7th doped region 111 are heavily doped n-type doping district the most respectively, Doping content for example, 10¹⁸cm^-3～10²⁰cm^-3Magnitude.3rd doped region 110 and the 7th doped region 111 can be formed in same step.3rd doped region 110 is from the table of the second doped region 108 Face extends to desired depth position in the second doped region 108, and the 7th doped region 111 is from epitaxial layer 104 Surface extend to desired depth position in epitaxial layer 104.

In the region of break-over diode, the 3rd doped region the 110, second doped region 108 and One doped region 102 is respectively as launch site, base and the collecting zone of break-over diode D0.

In the region of the second diode, Semiconductor substrate 101 and epitaxial layer 104 form PN junction, Anode and negative electrode respectively as the second diode D2.

Subsequently, insulating barrier 112 is formed multiple opening, and is formed at least one opening Conductive channel 115, as shown in fig. 5g.

In order to form conductive channel 115, it is initially formed at least one opening, from the table of epitaxial layer 104 Face extends to Semiconductor substrate 101, and then deposition conductive material is to fill at least one opening described.

Conductive channel 115 such as by selected from gold, silver, copper, aluminum, aluminum silicon, aluminum copper silicon, titanium silver, The metal or alloy compositions such as titanium nickel gold.

Further, the plurality of opening exposes the 3rd doped region respectively in the region of break-over diode 110 and the surface of conductive channel 115, the 5th doped region 107 is exposed in the region of the first diode With the surface of the 6th doped region 109, expose the 7th doped region 111 in the region of the second diode Surface.

A part for epitaxial layer 104, together with isolation area 105, is defined to by the first doped region 102 Semiconductor island, wherein the first doped region 102 is for limiting the bottom of semiconductor island, isolation area 105 For limiting the sidewall of semiconductor island.Second doped region 108 is positioned in semiconductor island, is positioned at first Separate above doped region 102 and with the second doped region 108.Conductive channel 115 serves as a contrast with quasiconductor The end 101, contacts.

Subsequently, multiple electrode is made, as shown in figure 5h.

First electrode 121 is electrically connected through the opening in interlayer insulating film 112 and the 3rd doped region 110 Connect.3rd electrode 123 is electrically connected through the opening in interlayer insulating film 112 and the 6th doped region 109 Connecing, the 4th electrode 124 is electrically connected through the opening in interlayer insulating film 112 and the 7th doped region 111 Connecing, the 5th electrode 125 is electrically connected through the opening in interlayer insulating film 112 and the 5th doped region 107 Connect.

Alternatively, supplemantary electrode 122 is through the opening in interlayer insulating film 112 and conductive channel 115 Electrical connection.

By thinning for Semiconductor substrate 101 and back face metalization, in the back side shape of Semiconductor substrate 101 Become metal layer on back, as the second electrode 131.That is, the second electrode 131 and Semiconductor substrate 101 form another surface relative with the surface of epitaxial layer 104 contacts.

Above-mentioned electrode is such as by selected from gold, silver, copper, aluminum, aluminum silicon, aluminum copper silicon, titanium silver, titanium The metal or alloy compositions such as nickel gold.

It should be noted that, heavy doping is with to be lightly doped be relative concept in the above-described example, represent Heavily doped doping content is more than lightly doped doping content, and not to concrete doping content scope Restriction.

In the above description, known structural element and step are not described in detail. It should be appreciated to those skilled in the art that can realize corresponding by various technological means Structural element and step.It addition, in order to form identical structural element, those skilled in the art are also Can be designed that method the most identical with process as described above.Although it addition, more than Respectively describe each embodiment, but it is not intended that the measure in each embodiment can not be favourable Be used in combination.

Above embodiment of the present utility model is described.But, these embodiments are only For illustrative purposes, it is not intended to limit scope of the present utility model.Model of the present utility model Enclose and limited by claims and equivalent thereof.Without departing from scope of the present utility model, this area Technical staff can make multiple replacement and amendment, and these substitute and amendment all should fall new in this practicality Within the scope of type.

Claims (10)

1. a single channel Transient Voltage Suppressor, it is characterised in that including:

The Semiconductor substrate of the first doping type；

First doped region of the second doping type being positioned in described Semiconductor substrate, wherein second mixes Miscellany type and the first doping type are contrary；

The epitaxial layer of the second doping type being positioned in described Semiconductor substrate；

The conductive channel of described first doped region is extended to from described epi-layer surface；

Second doped region of the first doping type being positioned in described epitaxial layer；And

3rd doped region of the second doping type being positioned in described second doped region,

Wherein, described single channel Transient Voltage Suppressor includes break-over diode, described first doping District, described second doped region and described 3rd doped region are respectively as the collection of described break-over diode Electricity district, base and launch site,

Described conductive channel contacts with described Semiconductor substrate, and with described first doped region and described At least one contact in epitaxial layer,

Described second doped region is positioned at above described first doped region and separates with described conductive channel.

Single channel Transient Voltage Suppressor the most according to claim 1, it is characterised in that During the conducting of described break-over diode, current path includes described 3rd doped region, described second doping District, described first doped region and described conductive channel and described Semiconductor substrate.

Single channel Transient Voltage Suppressor the most according to claim 2, it is characterised in that also Including:

4th doped region of the second doping type being positioned in described Semiconductor substrate；And

6th doped region of the first doping type being positioned in described epitaxial layer,

Wherein, described single channel Transient Voltage Suppressor also includes the first diode, and the described 6th mixes Miscellaneous district and described epitaxial layer are respectively as the anode of described first diode and negative electrode.

Single channel Transient Voltage Suppressor the most according to claim 3, it is characterised in that also Including the second diode, described Semiconductor substrate and described epitaxial layer respectively as described two or two pole The anode of pipe and negative electrode.

Single channel Transient Voltage Suppressor the most according to claim 4, it is characterised in that institute State single channel Transient Voltage Suppressor and there is signal end and earth terminal, the negative electrode of described first diode It is electrically connected to each other with the launch site of described break-over diode, the anode of described first diode and described The collecting zone of break-over diode connects described signal end and described earth terminal, described two or two pole respectively The negative electrode of pipe and anode connect described signal end and described earth terminal respectively.

Single channel Transient Voltage Suppressor the most according to claim 5, it is characterised in that also Including the 5th doped region of the second doping type being positioned in described epitaxial layer, described 5th doped region Around described 6th doped region, wherein, described 5th doped region electrically connects with described 3rd doped region.

Single channel Transient Voltage Suppressor the most according to claim 5, it is characterised in that also Including the 7th doped region of the second doping type being positioned in described epitaxial layer, described 7th doped region It is positioned at the region of described second diode, and electrically connects with described 6th doped region.

Single channel Transient Voltage Suppressor the most according to claim 5, it is characterised in that institute State the first diode, described second diode and described break-over diode use public described partly lead Body substrate.

Single channel Transient Voltage Suppressor the most according to claim 5, it is characterised in that also Including the isolation area of the first doping type being positioned in described epitaxial layer, wherein, described isolation area limit Fixed described first diode, described second diode and the respective active area of described break-over diode.

Single channel Transient Voltage Suppressor the most according to any one of claim 1 to 9, It is characterized in that, the first doping type is one of N-type and p-type, the second doping type be N-type and Another in p-type.