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EP0000545B1 - Method for forming a semiconducter device with self-alignment - Google Patents

Method for forming a semiconducter device with self-alignment Download PDF

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Publication number
EP0000545B1
EP0000545B1 EP78100443A EP78100443A EP0000545B1 EP 0000545 B1 EP0000545 B1 EP 0000545B1 EP 78100443 A EP78100443 A EP 78100443A EP 78100443 A EP78100443 A EP 78100443A EP 0000545 B1 EP0000545 B1 EP 0000545B1
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Prior art keywords
layer
regions
semiconductor body
accordance
semiconductor
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EP78100443A
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German (de)
French (fr)
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EP0000545A1 (en
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Chakrapani Gajanan Jambotkar
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International Business Machines Corp
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    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01LSEMICONDUCTOR DEVICES NOT COVERED BY CLASS H10
    • H01L21/00Processes or apparatus adapted for the manufacture or treatment of semiconductor or solid state devices or of parts thereof
    • H01L21/02Manufacture or treatment of semiconductor devices or of parts thereof
    • H01L21/04Manufacture or treatment of semiconductor devices or of parts thereof the devices having potential barriers, e.g. a PN junction, depletion layer or carrier concentration layer
    • H01L21/18Manufacture or treatment of semiconductor devices or of parts thereof the devices having potential barriers, e.g. a PN junction, depletion layer or carrier concentration layer the devices having semiconductor bodies comprising elements of Group IV of the Periodic Table or AIIIBV compounds with or without impurities, e.g. doping materials
    • H01L21/26Bombardment with radiation
    • H01L21/263Bombardment with radiation with high-energy radiation
    • H01L21/265Bombardment with radiation with high-energy radiation producing ion implantation
    • H01L21/26506Bombardment with radiation with high-energy radiation producing ion implantation in group IV semiconductors
    • H01L21/26513Bombardment with radiation with high-energy radiation producing ion implantation in group IV semiconductors of electrically active species
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01LSEMICONDUCTOR DEVICES NOT COVERED BY CLASS H10
    • H01L21/00Processes or apparatus adapted for the manufacture or treatment of semiconductor or solid state devices or of parts thereof
    • H01L21/02Manufacture or treatment of semiconductor devices or of parts thereof
    • H01L21/027Making masks on semiconductor bodies for further photolithographic processing not provided for in group H01L21/18 or H01L21/34
    • H01L21/033Making masks on semiconductor bodies for further photolithographic processing not provided for in group H01L21/18 or H01L21/34 comprising inorganic layers
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01LSEMICONDUCTOR DEVICES NOT COVERED BY CLASS H10
    • H01L21/00Processes or apparatus adapted for the manufacture or treatment of semiconductor or solid state devices or of parts thereof
    • H01L21/02Manufacture or treatment of semiconductor devices or of parts thereof
    • H01L21/04Manufacture or treatment of semiconductor devices or of parts thereof the devices having potential barriers, e.g. a PN junction, depletion layer or carrier concentration layer
    • H01L21/18Manufacture or treatment of semiconductor devices or of parts thereof the devices having potential barriers, e.g. a PN junction, depletion layer or carrier concentration layer the devices having semiconductor bodies comprising elements of Group IV of the Periodic Table or AIIIBV compounds with or without impurities, e.g. doping materials
    • H01L21/30Treatment of semiconductor bodies using processes or apparatus not provided for in groups H01L21/20 - H01L21/26
    • H01L21/31Treatment of semiconductor bodies using processes or apparatus not provided for in groups H01L21/20 - H01L21/26 to form insulating layers thereon, e.g. for masking or by using photolithographic techniques; After treatment of these layers; Selection of materials for these layers
    • H01L21/3205Deposition of non-insulating-, e.g. conductive- or resistive-, layers on insulating layers; After-treatment of these layers
    • H01L21/321After treatment
    • H01L21/3215Doping the layers
    • H01L21/32155Doping polycristalline - or amorphous silicon layers
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01LSEMICONDUCTOR DEVICES NOT COVERED BY CLASS H10
    • H01L29/00Semiconductor devices specially adapted for rectifying, amplifying, oscillating or switching and having potential barriers; Capacitors or resistors having potential barriers, e.g. a PN-junction depletion layer or carrier concentration layer; Details of semiconductor bodies or of electrodes thereof ; Multistep manufacturing processes therefor
    • H01L29/02Semiconductor bodies ; Multistep manufacturing processes therefor
    • H01L29/06Semiconductor bodies ; Multistep manufacturing processes therefor characterised by their shape; characterised by the shapes, relative sizes, or dispositions of the semiconductor regions ; characterised by the concentration or distribution of impurities within semiconductor regions
    • H01L29/08Semiconductor bodies ; Multistep manufacturing processes therefor characterised by their shape; characterised by the shapes, relative sizes, or dispositions of the semiconductor regions ; characterised by the concentration or distribution of impurities within semiconductor regions with semiconductor regions connected to an electrode carrying current to be rectified, amplified or switched and such electrode being part of a semiconductor device which comprises three or more electrodes
    • H01L29/0843Source or drain regions of field-effect devices
    • H01L29/0847Source or drain regions of field-effect devices of field-effect transistors with insulated gate
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01LSEMICONDUCTOR DEVICES NOT COVERED BY CLASS H10
    • H01L29/00Semiconductor devices specially adapted for rectifying, amplifying, oscillating or switching and having potential barriers; Capacitors or resistors having potential barriers, e.g. a PN-junction depletion layer or carrier concentration layer; Details of semiconductor bodies or of electrodes thereof ; Multistep manufacturing processes therefor
    • H01L29/40Electrodes ; Multistep manufacturing processes therefor
    • H01L29/43Electrodes ; Multistep manufacturing processes therefor characterised by the materials of which they are formed
    • H01L29/49Metal-insulator-semiconductor electrodes, e.g. gates of MOSFET
    • H01L29/4916Metal-insulator-semiconductor electrodes, e.g. gates of MOSFET the conductor material next to the insulator being a silicon layer, e.g. polysilicon doped with boron, phosphorus or nitrogen

Definitions

  • the invention relates to a method for producing a semiconductor arrangement of the type specified in the preamble of patent claim 1.
  • a preferred field of application for this method is the production of insulating layer field-effect transistor structures which are equipped with so-called self-aligned gate electrodes.
  • Such field effect transistors with a self-aligned gate are already known per se.
  • the associated conventional manufacturing processes use a mask made of a high temperature resistant material for masking during the formation of the source and drain regions, i.e. a material capable of withstanding high temperatures on the order of 1000 ° C and higher.
  • This masking layer can be made of silicon, for example, as described for the processes described in US Pat. Nos. 3,475,234 and 3,544,399, using polycrystalline silicon as the masking material that remains in the gate region for the final formation of the gate electrode. Since such structures are insulating layer field effect transistors, a layer of an insulating material, e.g. of silicon dioxide, under the silicon-containing masking layer.
  • the high temperature resistant material itself may already be an insulating material, e.g. Silicon nitride, which remains as a gate dielectric in the gate area.
  • the high-temperature resistant material e.g. Silicon nitride or a double layer of silicon nitride over silicon dioxide, for edge definition of the source and drain regions adjoining the gate region; it remains as a thin gate dielectric in the final field effect transistor structure.
  • a thick oxide layer is thermally grown over the source and drain, the silicon nitride layer present in the gate region serving as an oxidation-inhibiting mask to prevent the thin gate insulating layer from increasing in thickness.
  • a conductive gate electrode is formed in the gate area, the thin silicon nitride layer or, after its removal, another thin insulating layer also serving to delimit the area provided as the gate area.
  • the main advance in such a self-aligned gate structure has been that it has improved the positioning of the gate electrode and gate insulating layer relative to the source and drain regions.
  • the gate electrode had to be made larger relative to the channel length effective between the source and drain, i.e. there was a significant overlap between the gate electrode and the source and drain regions. This resulted in undesired stray capacitances in the form of gate overlap capacitances, which led to a deterioration in the frequency properties or the switching speed of such field-effect transistor components in integrated circuits.
  • the dopants can first be introduced by diffusion or ion implantation in such a way that very flat surface areas of the appropriate conductivity type form, which is followed by a so-called driving-in step to be carried out at high temperatures, through which the source and drain are driven deeper into the semiconductor body.
  • driving-in step to be carried out at high temperatures, through which the source and drain are driven deeper into the semiconductor body.
  • the doping atoms migrate to a certain extent below the gate masking layer. As a result, there was nevertheless an overlap of the gate with the source and drain and the resulting disadvantageous consequences.
  • the layer wi is considerably lower resistances in the order of 8 to 10 ⁇ / ⁇ are required.
  • source and drain regions with such a low sheet resistance were produced by one of the diffusion methods described above for forming the source and drain regions with a depth extension in the substrate in the order of magnitude of 1000 nm.
  • the invention achieves the object of specifying a method for producing a semiconductor arrangement, in particular an insulating layer field-effect transistor structure, which is improved with respect to the overlap-free self-adjustment of doping regions relative to a surface layer, in which the overlap-free self-adjustment also occurs at a relatively deep in doping regions reaching the semiconductor body can be achieved.
  • buried areas completely enclosed by the material of the semiconductor body are first formed in the mutual arrangement defined by the masking layer on the semiconductor surface by means of ion implantation, whereupon a subsequent heat treatment brings about a targeted expansion of the dopants present in the buried areas until the semiconductor surface is reached.
  • the channel region is always exactly and completely covered by the gate electrode, but on the other hand that there is no gate overlap with the source and drain regions formed in this way.
  • FIG. 1 shows a semiconductor body or a substrate 10 of the P conductivity type, the specific resistance value of which is approximately 0.1 to 1 ⁇ cm and on which an approximately 900 nm thick silicon dioxide layer 11 is formed.
  • This layer 11 can be formed in a conventional manner by thermal oxidation or otherwise deposited, e.g. by vapor deposition or sputtering.
  • An opening 12 is produced in layer 11 using conventional photoiitography and etching methods, so that the structure shown in FIG. 1 results.
  • a thin layer 13 of silicon dioxide with a thickness of approximately 50 nm is then allowed to grow in the area of the opening 12, preferably thermally.
  • a silicon layer 14 is applied over this by means of conventional methods for depositing silicon, for example described in US Pat. No. 3,424,629. This process step is carried out at a temperature on the order of 500 to 900 ° C and usually at atmospheric pressure.
  • the silicon layer 14 is a polycrystalline structure since it is formed on the silicon dioxide layers 11 and 13.
  • the thickness of the layer 14 is approximately 900 nm.
  • an approximately 80 nm thick silicon dioxide layer 15 is produced in a conventional manner per se, but preferably by thermal oxidation of a part of the surface of the silicon layer 14.
  • the regions 18 and 19 buried in the semiconductor body 10 are then formed by means of ion implantation in accordance with FIG. 4.
  • N-type dopants for example phosphorus
  • the implantation step can be carried out either directly through the unmasked, relatively thin silicon dioxide layer 13 or, as shown in FIG. 4, after the silicon dioxide layer 13 not covered by the silicon layer 14 'has been removed beforehand. 4, the silicon dioxide layer arranged below the mask in the form of the silicon layer 14 'is designated by 13'.
  • a conventional etching process for example under Buffered hydrofluoric acid can be used.
  • the silicon dioxide layer 15 will also be removed, while the layer 11, which is considerably thicker in comparison, remains essentially unchanged.
  • the ion implantation must be carried out with sufficient radiation dosage and energy that the buried regions 18 and 19 have a concentration distribution which takes account of the following aspects.
  • the same heat treatment is intended to ensure that regions 18 and 19 also move upwards expand in the direction of the surface of the semiconductor body 10 so that they just adjoin the silicon gate electrode laterally on the semiconductor surface.
  • FIG. 8A shows the concentration distribution of the N-doping impurities for the regions 18 and 19 along the section line 8A-8A indicated in FIG. 4.
  • regions 18 and 19 were originally created as regions completely enclosed in P-type semiconductor body 10, with a peak concentration being approximately at a distance of 0.5 ⁇ m from the semiconductor surface.
  • the implantation step that can be used to form these areas 18 and 19 with the concentration profile shown can be carried out using conventional devices and methods, such as are described, for example, in US Pat. No. 3,756,862. For example, taking type 3 'P + ions, an energy value of 400 keV and a dosage of approximately 10 16 ions / cm 2 is appropriate.
  • the implantation also forms a dopant distribution similar to the shape shown in FIG. 8A in the silicon layer region 14 ′. As a result, the layer 14 'is desirably provided with a low sheet resistance.
  • a so-called diffusion or driving-in step is carried out at a temperature of about 950 ° C in a conventional oxidizing atmosphere, such as e.g. Steam is performed to bring the source and drain regions 18 and 19 into the form shown in FIG. 5.
  • a conventional oxidizing atmosphere such as e.g. Steam
  • the final dopant distribution for the source and drain regions 18 and 19 along the section line 8B-8B shown in FIG. 5 is shown in FIG. 8B.
  • a silicon dioxide layer 40 is formed over the semiconductor body 10 as well as over the polycrystalline silicon gate electrode 14 '.
  • the source and drain region edges next to it due to the subsequent diffusion or heat treatment step their downward expansion to the same extent can also be extended upwards so that their intersections 22 and 23 (in FIG. 5) are practically exactly aligned with the corresponding edges 24 and 25 of the silicon gate electrode 14 'with regard to their lateral adjustment.
  • the preliminary ion implantation step according to FIG.
  • openings 31, 32 and 28 are then produced in the silicon dioxide layer 40 as contact openings for source, drain and the gate electrode.
  • the source and drain regions have a relatively low surface concentration of phosphorus. It is therefore advantageous to carry out a flat implantation of the dopants which cause the N-conduction type, for example phosphorus, in each of these contact openings, the regions designated 29, 30 and 34 being formed in FIG. 6. These areas have a high surface concentration of the N conductivity type in the order of 10 21 atoms / cm 3 , cf. in addition the concentration profile shown in FIG. 8C for the relationships shown in FIG. 6, and in particular the point 33 in FIG. 8C.
  • N + conductive connection regions 29, 30 and 34 can be produced in a conventional manner by introducing dopants. However, it is preferable to fabricate these areas by implanting N-type ions, eg phosphorus, using the method described above with an energy of approximately 40 keV and a dosage of approximately 10 11 ions / cm 2 . In the last method step, as shown in FIG. 7, is carried out in a conventional manner the contact and connection metallization in the form of the connections 35, 36 and 37 for source, drain and the silicon gate. This metallization can be completely conventional in the manner customary in such integrated FET circuits, for example made of aluminum.
  • N-type ions eg phosphorus
  • the invention is not restricted to this but can also be applied to other self-aligned gate designs.
  • the masking layer required to ensure the self-alignment of the thin gate insulating layer consists of a material that does not melt or decompose in any other way at the diffusion temperatures of the order of 1000 ° C. or greater that are used.
  • Such other possibilities include, for example, self-aligned field effect transistors with silicon nitride gate technology, in which a thin layer of silicon nitride is used for the self-aligned formation of the source and drain regions relative to the thin gate insulating layer.
  • metals such as molybdenum, tungsten or tantalum which are resistant to high temperatures can be used instead of the silicon described in the present exemplary embodiment in the context of such a method.

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Description

Die Erfindung bezieht sich auf ein Verfahren zur Herstellung einer Halbleiteranordnung der im Oberbegriff des Patentanspruchs 1 angegebenen Art. Bevorzugtes Anwendungsgebiet dieses Verfahrens ist die Herstellung von Isolierschicht-Feldeffekttransistorstrukturen, die mit sog. selbstjustierten Gate-Elektroden ausgestattet sind.The invention relates to a method for producing a semiconductor arrangement of the type specified in the preamble of patent claim 1. A preferred field of application for this method is the production of insulating layer field-effect transistor structures which are equipped with so-called self-aligned gate electrodes.

Derartige Feldeffekttransistoren mit selbstjustiertem Gate sind an sich bereits bekannt. Die zugehörigen konventionellen Herstellungsverfahren verwenden für die Maskierung während der Ausbildung der Source- und Draingebiete eine Maske aus einem hochtemperaturfesten Material, d.h. einem Material, das in der Lage ist, hohe Temperaturen in der Größenordnung von 1000 °C und höher auszuhalten. Diese Maskierungsschicht kann beispielsweise aus Silicium bestehen, wie für die in den US-Patentschriften 3475234 und 3544399 behandelten Verfahren beschrieben ist, wobei polykristallines Silicium als Maskierungsmaterial benutzt wird, das im Gate-Bereich zur letzlichen Bildung der Gate-Elektrode verbleibt. Da es sich bei solchen Strukturen um Isolierschicht-Feldeffekttransistoren handelt, wird stets noch eine Schicht aus einem isolierenden Material, z.B. aus Siliciumdioxid, unter der Silicium enthaltenden Maskierungsschicht vorhanden sein.Such field effect transistors with a self-aligned gate are already known per se. The associated conventional manufacturing processes use a mask made of a high temperature resistant material for masking during the formation of the source and drain regions, i.e. a material capable of withstanding high temperatures on the order of 1000 ° C and higher. This masking layer can be made of silicon, for example, as described for the processes described in US Pat. Nos. 3,475,234 and 3,544,399, using polycrystalline silicon as the masking material that remains in the gate region for the final formation of the gate electrode. Since such structures are insulating layer field effect transistors, a layer of an insulating material, e.g. of silicon dioxide, under the silicon-containing masking layer.

Andererseits kann das hochtemperaturfeste Material selbst bereits ein isolierendes Material sein, z.B. Siliciumnitrid, das als Gate-Dielektrikum im Gate-Bereich verbleibt. Zugehörige Verfahren dieser Art sind in der US-Patentschrift 3 544 858 behandelt. Dabei dient das hochtemperaturfeste Material, z.B. Siliciumnitrid oder eine Doppelschicht aus Siliciumnitrid über Siliciumdioxid, zur Kantendefinition der an den Gate- Bereich angrenzenden Source- und Draingebiete ; es verbleibt dabei als dünnes Gate-Dielektrikum in der endgültigen Feldeffekttransistorstruktur. Dazu läßt man thermisch eine dicke Oxidschicht über Source und Drain aufwachsen, wobei die im Gatebereich vorhandene Siliciumnitridschicht als oxydationshemmende Maskierung zur Verhinderung einer Dickenzunahme der dünnen Gate-Isolierschicht dient. Schließlich wird eine leitfähige Gate-Elektrode im Gatebereich gebildet, wobei die dünne Siliciumnitridschicht oder nach deren Entfernung eine andere dünne Isolierschicht weiterhin zur Abgrenzung des als Gatebereich vorgesehenen Gebietes dient.On the other hand, the high temperature resistant material itself may already be an insulating material, e.g. Silicon nitride, which remains as a gate dielectric in the gate area. Associated methods of this type are discussed in U.S. Patent No. 3,444,858. The high-temperature resistant material, e.g. Silicon nitride or a double layer of silicon nitride over silicon dioxide, for edge definition of the source and drain regions adjoining the gate region; it remains as a thin gate dielectric in the final field effect transistor structure. For this purpose, a thick oxide layer is thermally grown over the source and drain, the silicon nitride layer present in the gate region serving as an oxidation-inhibiting mask to prevent the thin gate insulating layer from increasing in thickness. Finally, a conductive gate electrode is formed in the gate area, the thin silicon nitride layer or, after its removal, another thin insulating layer also serving to delimit the area provided as the gate area.

Der hauptsächliche Fortschritt bei einer derartigen Struktur mit selbstjustiertem Gate bestand darin, daß dadurch eine verbesserte Positionierung der Gate-Elektrode und der Gate-Isolierschicht relativ zu den Source- und Draingebieten erzielt werden konnte. Vor Anwendung der selbstjustierten Gate-Strukturen mußte die Gate-Elektrode relativ zur zwischen Source und Drain wirksamen Kanallänge größer ausgelegt werden, d.h. zwischen der Gate-Elektrode und den Source- und Draingebieten lag eine zum Teil erhebliche Überlappung vor. Daraus resultierten unerwünschte Streukapazitäten in Form von Gate-Überlappungskapazitäten, die zu einer Verschlechterung der Frequenzeigenschaften bzw. der Schaltgeschwindigkeit solcher Feldeffekttransistorbauelemente in integrierten Schaltungen führten.The main advance in such a self-aligned gate structure has been that it has improved the positioning of the gate electrode and gate insulating layer relative to the source and drain regions. Before using the self-aligned gate structures, the gate electrode had to be made larger relative to the channel length effective between the source and drain, i.e. there was a significant overlap between the gate electrode and the source and drain regions. This resulted in undesired stray capacitances in the form of gate overlap capacitances, which led to a deterioration in the frequency properties or the switching speed of such field-effect transistor components in integrated circuits.

Obwohl die oben beschriebenen selbstjustierten Gate-Strukturen und die dazu gehörigen Verfahren bereits zu einer beträchtlichen Reduzierung der Gate-Überlappung und somit zu einer Verschnellerung der Schaltzeiten geführt haben, wurde das Problem der Gate-Überlappung der Source- und Draingebiete immer noch nicht völlig ausgeräumt. Dies lag in erster Linie an der verfahrensmäßigen Ausgestaltung, nach der die Bildung der Source- und Draingebiete trotz Vorsehung eines selbstjustierten Gates mittels eines Diffusionsschrittes erfolgte. Konventionell kann dieser Diffusionsschritt direkt durch Einbringung von Dotierungsstoffen für Source und Drain in den Halbleiterkörper in Anwesenheit der selbstjustierenden Gatemaskierung erfolgen. Alternativ können die Dotierungsstoffe zunächst durch Diffusion oder Ionenimplantation in einer Weise eingebracht werden, daß sich sehr flache Oberflächengebiete vom entsprechenden Leitungstyp bilden, woran sich ein bei hohen Temperaturen durchzuführender sog. Eintreibschritt anschließt, durch den Source und Drain tiefer in den Halbleiterkörper hineingetrieben werden. Im Verlaufe dieser Diffusions- bzw. Eintreibschritte kommt es natürlich auch bis zu einem gewissen Maße zu einer seitlichen Auswanderung der Dotierungsatome unterhalb der Gate-Maskierungsschicht. Im Ergebnis kam es damit dennoch zu einer Überlappung des Gates mit Source und Drain und den daraus sich ergebenden nachteiligen Konsequenzen.Although the self-aligned gate structures described above and the associated methods have already led to a considerable reduction in the gate overlap and thus to faster switching times, the problem of gate overlap of the source and drain regions has still not been completely eliminated. This was primarily due to the procedural design according to which the source and drain regions were formed by means of a diffusion step despite the provision of a self-aligned gate. Conventionally, this diffusion step can be carried out directly by introducing dopants for the source and drain into the semiconductor body in the presence of the self-adjusting gate masking. Alternatively, the dopants can first be introduced by diffusion or ion implantation in such a way that very flat surface areas of the appropriate conductivity type form, which is followed by a so-called driving-in step to be carried out at high temperatures, through which the source and drain are driven deeper into the semiconductor body. In the course of these diffusion or drive-in steps, of course, the doping atoms migrate to a certain extent below the gate masking layer. As a result, there was nevertheless an overlap of the gate with the source and drain and the resulting disadvantageous consequences.

Es wurde auch bereits im Stand der Technik, z.B. in der US-Patentschrift 3472712, angegeben, derartige selbstjustierte Isolierschicht-Feldeffekttransistoren unter Vermeidung jeglichen Diffusionsschrittes lediglich durch Einsatz einer Ionenimplantation herzustellen. Derartige Strukturen weisen sicherlich keine Gate-Überlappungsprobleme auf. Die durch solche Verfahren hergestellten Strukturen sind aber insofern einer Beschränkung unterworfen, als ihre Source- und Draingebiete lediglich mit einer Tiefe von 200 bis 300 nm oder weniger in den Halbleiterkörper bzw. das Substrat hineinreichen. Als Folge daraus ergeben sich für die Source- und Draingebiete hohe Widerstandswerte, d.h. Schichtwiderstände in der Größenordnung von 50 n/D. Obgleich derartig hohe Schichtwiderstandswerte durchaus akzeptabel für manche diskrete Feldeffekttransistorfunktionen wie auch für einfachere integrierte Schaltungen sein können, sind bei komplexeren mit Feldeffekttransistoren aufgebauten integrierten Schaltungen, bei denen die Source- und Draingebiete oder deren Verlängerungen als Teil des Verbindungsnetzwerks benutzt werden, erheblich niedrigere Schichtwiderstände in der Größenordnung von 8 bis 10 Ω/□ erforderlich. Nach dem Stand der Technik wurden Source- und Draingebiete mit derartig niedrigem Schichtwiderstand durch eines der oben beschriebenen Diffusionsverfahren zur Bildung der Source- und Draingebiete mit einer Tiefenerstreckung im Substrat in der Größenordnung von 1000 nm erzeugt. Die Ausbildung von beispielsweise 1000 nm tief reichenden Source-und Draingebieten lediglich durch lonenimplantation ohne anschließende Diffusionsbehandlung würde, soweit sie überhaupt möglich wäre, eine erheblich kompliziertere und hinsichtlich der Anzahl einzelner lonenimplantationsschritte sowie der zugehörigen Wahl der Energie- und Dosierungswerte aufwendigere Verfahrensausgestaltung erfordern.It has also already been stated in the prior art, for example in US Pat. No. 3,472,712, to manufacture such self-aligned insulating layer field-effect transistors by avoiding any diffusion step simply by using an ion implantation. Such structures certainly have no gate overlap problems. However, the structures produced by such methods are subject to a restriction in that their source and drain regions only extend into the semiconductor body or the substrate with a depth of 200 to 300 nm or less. As a result, there are high resistance values for the source and drain regions, ie sheet resistances in the order of 50 n / D. Although such high layer resistance values can be quite acceptable for some discrete field effect transistor functions as well as for simpler integrated circuits, in the case of more complex integrated circuits built with field effect transistors, in which the source and drain regions or their extensions are used as part of the connection network, the layer wi is considerably lower resistances in the order of 8 to 10 Ω / □ are required. According to the prior art, source and drain regions with such a low sheet resistance were produced by one of the diffusion methods described above for forming the source and drain regions with a depth extension in the substrate in the order of magnitude of 1000 nm. The formation of, for example, 1000 nm deep source and drain areas only by ion implantation without subsequent diffusion treatment would, as far as possible, require a considerably more complicated process design, which is more complex in terms of the number of individual ion implantation steps and the associated choice of energy and dosage values.

Die Erfindung, wie sie in den Ansprüchen gekennzeichnet ist, löst die Aufgabe, ein hinsichtlich der überlappungsfreien Selbstjustierung von Dotierungsgebieten relativ zu einer Oberflächenschicht verbessertes Verfahren zur Herstellung einer Halbleiteranordnung, insbesondere einer lsolierschicht-Feldeffekttransistorstruktur anzugeben, bei der die überlappungsfreie Selbstjustierung auch bei relativ tief in den Halbleiterkörper reichenden Dotierungsgebieten erreicht werden kann. Zusammengefaßt werden mittels Ionenimplantation zunächst vollständig vom Material des Halbleiterkörpers eingeschlossene vergrabene Gebiete in der durch die Maskierungschicht auf der Halbleiteroberfläche festgelegten gegenseitigen Anordnung gebildet, woraufhin durch eine nachfolgende Wärmebehandlung eine gezielte Ausdehnung der in den vergrabenen Gebieten vorhandenen Dotierungsstoffe bis zum Erreichen der Halbleiteroberfläche herbeigeführt wird. Für den Fall einer Isolierschicht-Feldeffekttransistorstruktur heißt das, daß Source und Drain zunächst als vergrabene Gebiete mittels lonenimplantation innerhalb des Halbleiterkörpers dotiert werden und die nachfolgende Wärmebehandlung zur Ausdiffusion der Dotierungsstoffe gerade soweit geführt wird, daß die obere Randzone des zunächst vergrabenen Gebiets letzlich gerade die Halbleiteroberfläche erreicht. In diesem Fall ist einerseits gewährleistet, daß der Kanalbereich stets exakt und vollständig von der Gate-Elektrode bedeckt ist, daß andererseits aber keinerlei Gate-Überlappung zu den derart ausgebildeten Source- und Draingebieten eintritt.The invention, as characterized in the claims, achieves the object of specifying a method for producing a semiconductor arrangement, in particular an insulating layer field-effect transistor structure, which is improved with respect to the overlap-free self-adjustment of doping regions relative to a surface layer, in which the overlap-free self-adjustment also occurs at a relatively deep in doping regions reaching the semiconductor body can be achieved. In summary, buried areas completely enclosed by the material of the semiconductor body are first formed in the mutual arrangement defined by the masking layer on the semiconductor surface by means of ion implantation, whereupon a subsequent heat treatment brings about a targeted expansion of the dopants present in the buried areas until the semiconductor surface is reached. In the case of an insulating layer field-effect transistor structure, this means that the source and drain are first doped as buried regions by means of ion implantation within the semiconductor body and the subsequent heat treatment for diffusing out the dopants is carried out to such an extent that the upper edge zone of the initially buried region ultimately just the semiconductor surface reached. In this case, it is ensured on the one hand that the channel region is always exactly and completely covered by the gate electrode, but on the other hand that there is no gate overlap with the source and drain regions formed in this way.

Im folgenden wird die Erfindung anhand von lediglich einen Ausführungsweg darstellenden Zeichnungen näher erläutert.The invention is explained in more detail below with the aid of drawings which illustrate only one embodiment.

Es zeigen :

  • Fig. 1-7 schematische Querschnittsdarstellungen durch eine Feldeffekttransistorstruktur zur Erläuterung der Verfahrensabfolge im Rahmen vorliegender Erfindung, und
  • Fig. 8A-8C verschiedene Dotierungsprofile über die Tiefe des Draingebietes, wie sie sich zu verschiedenen Verfahrenszeitpunkten ergeben.
Show it :
  • 1-7 are schematic cross-sectional representations through a field effect transistor structure to explain the process sequence within the scope of the present invention, and
  • 8A-8C show different doping profiles over the depth of the drain region, as result at different times of the method.

Fig. 1 zeigt einen Halbleiterkörper bzw. ein Substrat 10 vom P-Leitungstyp, dessen spezifischer Widerstandswert etwa 0,1 bis 1 Ω cm beträgt und auf dem eine größenordnungsmäßig etwa 900 nm dicke Siliciumdioxidschicht 11 gebildet ist. Diese Schicht 11 kann in konventioneller Weise durch thermische Oxydation erzeugt oder in anderer Weise niedergeschlagen werden, z.B. durch Aufdampfen oder Sputtern. In der Schicht 11 wird in konventioneller Anwendung entsprechender Photoiitographie- und Ätzverfahren eine Öfnnung 12 hergestellt, so daß sich die in Fig. 1 gezeigte Struktur ergibt.1 shows a semiconductor body or a substrate 10 of the P conductivity type, the specific resistance value of which is approximately 0.1 to 1 Ω cm and on which an approximately 900 nm thick silicon dioxide layer 11 is formed. This layer 11 can be formed in a conventional manner by thermal oxidation or otherwise deposited, e.g. by vapor deposition or sputtering. An opening 12 is produced in layer 11 using conventional photoiitography and etching methods, so that the structure shown in FIG. 1 results.

Entsprechend Fig. 2 läßt man anschließend eine dünne Schicht 13 aus Siliciumdioxid mit einer Dicke von etwa 50 nm im Bereich der Öffnung 12, vorzugsweise thermisch aufwachsen. Darüber wird mittels konventioneller Verfahren zum Niederschlagen von Silicium, beispielsweise beschrieben in der US-Patentschrift 3 424 629, eine Siliciumschicht 14 aufgebracht. Dieser Prozeßschritt wird bei einer Temperatur in der Größenordnung von 500 bis 900 °C und üblicherweise bei Atmosphärendruck durchgeführt. Bei der Siliciumschicht 14 handelt es sich um eine polykristalline Struktur, da sie auf den Siliciumdioxidschichten 11 und 13 gebildet wird. Die Dicke der Schicht 14 beträgt größenordnungsmäßig etwa 900 nm. Schließlich wird noch eine etwa 80 nm dicke Siliciumdioxidschicht 15 in an sich konventioneller Weise, vorzugsweise jedoch durch thermische Oxydation eines Teils der Oberfläche der Siliciumschicht 14, erzeugt.According to FIG. 2, a thin layer 13 of silicon dioxide with a thickness of approximately 50 nm is then allowed to grow in the area of the opening 12, preferably thermally. A silicon layer 14 is applied over this by means of conventional methods for depositing silicon, for example described in US Pat. No. 3,424,629. This process step is carried out at a temperature on the order of 500 to 900 ° C and usually at atmospheric pressure. The silicon layer 14 is a polycrystalline structure since it is formed on the silicon dioxide layers 11 and 13. The thickness of the layer 14 is approximately 900 nm. Finally, an approximately 80 nm thick silicon dioxide layer 15 is produced in a conventional manner per se, but preferably by thermal oxidation of a part of the surface of the silicon layer 14.

Entsprechend Fig. 3 wird als nächstes unter Einsatz konventioneller Photolitographie- und Ätztechniken sowie unter Einsatz einer Maskierungsschicht 15' aus Siliciumdioxid auf dem für die spätere Gate-Elektrode des Feldeffekttransistors vorgesehenen Bereich der Siliciumschicht 14 ein selektiver Ätzvorgang zur Beseitigung der über den Bereich 14' hinausgehenden Siliciumschibhtbereiche durchgeführt. Für die Beseitigung der Siliciumschicht 14 stehen alle konventionellen chemischen Ätzverfahren zur Verfügung, mit denen vorzugsweise Silicium im Gegensatz zu Siliciumdioxid geätzt werden kann. Beispielsweise eignet sich eine verdünnte Salpetersäure/Flußsäurelösung für diesen Zweck. Als Ergebnis wird ein Paar von Öffnungen 16 und 17 in Fig. 3 erhalten, die sich an den für die späteren Source- und Draingebiete bestimmten Stellen befinden.3, using conventional photolithography and etching techniques and using a silicon dioxide masking layer 15 'on the area of the silicon layer 14 intended for the later gate electrode of the field effect transistor, a selective etching process is then carried out in order to remove the areas beyond the area 14' Silicon chip areas performed. All conventional chemical etching methods are available for the removal of the silicon layer 14, by means of which silicon can be etched, as opposed to silicon dioxide. For example, a dilute nitric acid / hydrofluoric acid solution is suitable for this purpose. As a result, a pair of openings 16 and 17 in FIG. 3 are obtained which are located at the locations intended for the later source and drain regions.

Mittels Ionenimplantation werden entsprechend Fig. 4 anschließend die im Halbleiterkörper 10 vergrabenen Gebiete 18 und 19 gebildet. Dazu werden N-leitende Dotierungsstoffe, z.B. Phosphor, in das Substrat implantiert. Der Implantationsschritt kann entweder direkt durch die unmaskierte relative dünne Siliciumdioxidschicht 13 oder entsprechend Fig. 4 nach vorheriger Entfernung der nicht durch die Siliciumschicht 14' bedeckten Siliciumdioxidschicht 13 erfolgen. In Fig. 4 ist die unterhalb der Maskierung in Form der Siliciumschicht 14' angeordnete Siliciumdioxidschicht mit 13' bezeichnet. Zur Beseitigung der Siliciumdioxidschicht kann ein konventionelles Ätzverfahren, z.B. unter Verwendung einer gepufferten Flußsäure benutzt werden. In diesem Fall wird auch die Siliciumdioxidschicht 15' entfernt werden, während die demgegenüber erheblich dickere Schicht 11 im wesentlichen unverändert verbleibt. Die lonenimplantation muß mit einer so ausreichenden Strahldosierung und -energie durchgeführt werden, daß sich für die vergrabenen Gebiete 18 und 19 eine den folgenden Gesichtspunkten Rechnung tragende Konzentrationsverteilung ergibt. Bei dem nachfolgenden Hochtemperaturschritt bei etwa 1000 °C oder höher zur Ausdiffusion der Gebiete 18 und 19 nach unten hin bis zu den in Fig. 5 ersichtlichen Übergängen 20 und 21 soll durch dieselbe Wärmebehandlung sichergestellt sein, daß die Gebiete 18 und 19 sich auch nach oben in Richtung auf die Oberfläche des Halbleiterkörpers 10 ausweiten, so daß sie an der Halbleiteroberfläche gerade seitlich an die Silicium-Gate-Elektrode angrenzen. Um Source- und Draingebiete mit relativ geringen Schichtwiderstandswerten in der Größenordnung von 8 bis 10 Ω/□ zu erhalten, sind Eindringtiefen der unteren Halbleiterübergänge 20 und 21 in der Größenordnung von 1 µm wünschenswert. Um zu derartigen resultierenden Eindringtiefen zu kommen, sollten die zunächst implantierten Gebiete 18 und 19 in Fig. 4 mit einer solchen Strahlenergie und -dosierung erzeugt werden, daß sich ein Konzentrationsprofil entsprechend Fig. 8A ergibt. In Fig. 8A ist die Konzentrationsverteilung der N-dotierenden Verunreinigungen für die Gebiete 18 und 19 entlang der in Fig. 4 angegebenen Schnittlinie 8A-8A gezeigt. Wie aus Fig. 8A hervorgeht sind die Gebiete 18 und 19 ursprünglich als völlig im P-leitenden Halbleiterkörper 10 eingeschlossene Gebiete erzeugt, wobei eine Spitzenkonzentration etwa im Abstand von 0,5 µm von der Halbleiteroberfläche vorliegt. Der zur Ausbildung dieser Gebiete 18 und 19 mit dem gezeigten Konzentrationsprofil anwendbare Implantationsschritt kann mit konventionellen Vorrichtungen und Verfahren, wie sie beispielsweise in der US-Patentschrift 3 756 862 beschrieben sind, vorgenommen werden. Nimmt man beispielsweise Ionen des Typs 3'P+, ist ein Energiewert von 400 keV und eine Dosierung von Ungefähr 1016 lonen/cm2 angemessen. Die relativ dicken Schichten 11 und 14' verhindern, daß die implantierten Ionen in den Halbleiterkörper 10 unterhalb dieser Schichten eingebaut werden können. Durch die Implantation wird auch in dem Siliciumschichtbereich 14' eine Dotierstoffverteilung ähnlich der in Fig. 8A gezeigten Form gebildet. Dadurch wird die Schicht 14' in wünschenswerter Weise mit einem geringen Schichtwiderstand ausgestattet.The regions 18 and 19 buried in the semiconductor body 10 are then formed by means of ion implantation in accordance with FIG. 4. For this purpose, N-type dopants, for example phosphorus, are implanted in the substrate. The implantation step can be carried out either directly through the unmasked, relatively thin silicon dioxide layer 13 or, as shown in FIG. 4, after the silicon dioxide layer 13 not covered by the silicon layer 14 'has been removed beforehand. 4, the silicon dioxide layer arranged below the mask in the form of the silicon layer 14 'is designated by 13'. To remove the silicon dioxide layer, a conventional etching process, for example under Buffered hydrofluoric acid can be used. In this case, the silicon dioxide layer 15 'will also be removed, while the layer 11, which is considerably thicker in comparison, remains essentially unchanged. The ion implantation must be carried out with sufficient radiation dosage and energy that the buried regions 18 and 19 have a concentration distribution which takes account of the following aspects. In the subsequent high-temperature step at about 1000 ° C. or higher for the outward diffusion of regions 18 and 19 down to the transitions 20 and 21 shown in FIG. 5, the same heat treatment is intended to ensure that regions 18 and 19 also move upwards expand in the direction of the surface of the semiconductor body 10 so that they just adjoin the silicon gate electrode laterally on the semiconductor surface. In order to obtain source and drain regions with relatively low sheet resistance values in the order of 8 to 10 Ω / □, penetration depths of the lower semiconductor junctions 20 and 21 in the order of 1 μm are desirable. In order to arrive at such resulting penetration depths, the initially implanted areas 18 and 19 in FIG. 4 should be generated with such beam energy and dosage that a concentration profile corresponding to FIG. 8A results. FIG. 8A shows the concentration distribution of the N-doping impurities for the regions 18 and 19 along the section line 8A-8A indicated in FIG. 4. As can be seen from FIG. 8A, regions 18 and 19 were originally created as regions completely enclosed in P-type semiconductor body 10, with a peak concentration being approximately at a distance of 0.5 μm from the semiconductor surface. The implantation step that can be used to form these areas 18 and 19 with the concentration profile shown can be carried out using conventional devices and methods, such as are described, for example, in US Pat. No. 3,756,862. For example, taking type 3 'P + ions, an energy value of 400 keV and a dosage of approximately 10 16 ions / cm 2 is appropriate. The relatively thick layers 11 and 14 'prevent the implanted ions from being built into the semiconductor body 10 below these layers. The implantation also forms a dopant distribution similar to the shape shown in FIG. 8A in the silicon layer region 14 ′. As a result, the layer 14 'is desirably provided with a low sheet resistance.

Im Anschluß an den Implantationsschritt wird ein sog. Ausdiffusions- bzw. Eintreibschritt bei einer Temperatur von etwa 950 °C in einer konventionellen oxydierenden Atmosphäre, wie z.B. Dampf, durchgeführt, um die Source- und Draingebiete 18 und 19 in die aus Fig. 5 ersichtliche Form zu bringen. Insbesondere sollen dadurch die Gebietsgrenzen nach oben hin in Richtung auf die Halbleiteroberfläche eine Ausweitung erfahren. Die sich für die Source- und Draingebiete 18 und 19 endgültig einstellende Dotierstoffverteilung entlang der in Fig. 5 gezeigten Schnittlinie 8B-8B ist in Fig. 8B gezeigt. Als Ergebnis des Oxydationsvorgangs wird eine Siliciumdioxidschicht 40 über dem Halbleiterkörper 10 sowie über der polykristallinen Silicium-Gate-Elektrode 14' gebildet.Following the implantation step, a so-called diffusion or driving-in step is carried out at a temperature of about 950 ° C in a conventional oxidizing atmosphere, such as e.g. Steam is performed to bring the source and drain regions 18 and 19 into the form shown in FIG. 5. In particular, the area boundaries should thereby expand towards the semiconductor surface. The final dopant distribution for the source and drain regions 18 and 19 along the section line 8B-8B shown in FIG. 5 is shown in FIG. 8B. As a result of the oxidation process, a silicon dioxide layer 40 is formed over the semiconductor body 10 as well as over the polycrystalline silicon gate electrode 14 '.

Festzuhalten ist in diesem Zusammenhang, daß bei Vorsehung der Spitzenkonzentration der lonenbehandlung bei einer Eindringtiefe, die etwa bei der Hälfte der letztlich angestrebten Eindringtiefe für die unteren Bereichsgrenzen von Source und Drain liegt, durch den anschließenden Diffusions- bzw. Wärmebehandlungsschritt die Source- und Draingebietsränder neben ihrer Ausweitung nach unten im gleichen Maße auch nach oben hin ausgeweitet werden, so daß ihre Schnittpunkte 22 und 23 (in Fig. 5) bezüglich ihrer seitlichen Justierung praktisch exakt mit den entsprechenden Kanten 24 und 25 der Silicium-Gate-Elektrode 14' fluchten. Um sicherzustellen, daß die Schnittpunkte 22 und 23 mindestens mit den Ecken 24 und 25 zusammenfallen, bzw. mit anderen Worten, daß die Silicium-Elektrode 14' und die darunterliegende dünne Schicht 13' aus Siliciumdioxid bis zu den Schnittpunkten 22 und 23 reichen, weist der einleitende lonenimplantationsschritt entsprechend Fig. 8A eine solche Verteilung auf, daß im Anschluß an die Diffusions- bzw. Wärmebehandlung die abschließende Störstellenkonzentration an der Oberfläche der Gebiete 18 und 19 (Punkt 26 in Fig. 8B) bis etwa zum Faktor 3 größer ist als die Grunddotierung (Punkt 27 in Fig. 8B) des Silicium-Halbleiterkörpers 10.In this context, it should be noted that if the peak concentration of the ion treatment is provided at a depth of penetration which is approximately half the depth of penetration which is ultimately desired for the lower region limits of source and drain, the source and drain region edges next to it due to the subsequent diffusion or heat treatment step their downward expansion to the same extent can also be extended upwards so that their intersections 22 and 23 (in FIG. 5) are practically exactly aligned with the corresponding edges 24 and 25 of the silicon gate electrode 14 'with regard to their lateral adjustment. To ensure that the intersections 22 and 23 coincide at least with the corners 24 and 25, or in other words that the silicon electrode 14 'and the underlying thin layer 13' of silicon dioxide extend to the intersections 22 and 23 the preliminary ion implantation step according to FIG. 8A has such a distribution that, following the diffusion or heat treatment, the final impurity concentration on the surface of regions 18 and 19 (point 26 in FIG. 8B) is up to a factor of 3 greater than that Basic doping (point 27 in FIG. 8B) of the silicon semiconductor body 10.

Im weiteren Verfahrensablauf werden dann in der Siliciumdioxidschicht 40 Öffnungen 31, 32 und 28 als Kontaktöffnungen für Source, Drain und die Gate-Elektrode hergestellt. Wie aus Fig. 8B ersichtlich ist, weisen die Source- und Draingebiete eine relativ niedrige Oberflächenkonzentration an Phosphor auf. Von daher ist es vorteilhaft, in diesen Kontaktöffnungen jeweils eine flache Implantation von den N-Leitungstyp verursachenden Dotierungstoffen, z.B. Phosphor, vorzunehmen, wobei die in Fig. 6 mit 29, 30 und 34 bezeichneten Gebiete gebildet werden. Diese Gebiete weisen eine hohe Oberflächenkonzentration vom N-Leitungstyp in der Größenordnung von 1021 Atomen/cm3 auf, vgl. dazu das in Fig. 8C gezeigt Konzentrationsprofil für die in Fig. 6 gezeigten Verhältnisse, und insbesondere den Punkt 33 in Fig. 8C. Diese N+ leitenden Anschlußgebiete 29, 30 und 34 können in konventioneller Weise durch Einbringen von Dotierungsstoffen erzeugt werden. Es ist jedoch vorzuziehen, diese Gebiete durch Implantation von N-leitenden lonen, z.B. Phosphor, unter Benutzung des oben beschriebenen Verfahrens mit einer Energie von ungefähr 40 keV und einer Dosierung von etwa 1011 lonen/cm2 herzustellen. Im letzten Verfahrensschritt entsprechend der Darstellung von Fig. 7 wird in konventioneller Weise die Kontakt- und Verbindungsmetallisierung in Form der Anschlüsse 35, 36 und 37 für Source, Drain und das Silicium-Gate ausgebildet. Diese Metallisierung kann völlig konventionell in der bei derartigen integrierten FET-Schaltungen üblichen Weise, z.B. aus Aluminium, bestehen. Soweit in dem beschriebenen Ausführungsbeispiel auf eine Struktur mit einem selbstjustierten Silicium-Gate abgestellt wurde, ist festzuhalten, daß die Erfindung darauf nicht beschränkt ist sondern auch auf andere selbstjustierte Gate-Ausführungen angewendet werden kann. Dabei ist lediglich zu beachten, daß die zur Sicherstellung der Selbstjustierung der dünnen Gate-Isolierschicht erforderliche Maskierungsschicht aus einem Material besteht, das bei den zur Anwendung kommenden Diffusionstemperaturen in der Größenordnung von 1000 °C oder größer nicht schmilzt oder sich in anderer Weise zersetzt. Zu solchen anderen Möglichkeiten gehören beispielsweise selbstjustierte Feldeffekttransistoren mit einer Siliciumnitrid-Gate-Technologie, bei der eine dünne Schicht aus Siliciumnitrid zur selbstjustierenden Bildung der Source- und Draingebiete relativ zur dünnen Gate-Isolierschicht dient. Weiterhin lassen sich im Rahmen eines solchen Verfahrens hochtemperaturfeste Metalle, z.B. Molybdän, Wolfram oder Tantal anstelle von dem im vorliegenden Ausführungsbeispiel beschriebenen Silicium einsetzen.In the further course of the process, openings 31, 32 and 28 are then produced in the silicon dioxide layer 40 as contact openings for source, drain and the gate electrode. As can be seen from Figure 8B, the source and drain regions have a relatively low surface concentration of phosphorus. It is therefore advantageous to carry out a flat implantation of the dopants which cause the N-conduction type, for example phosphorus, in each of these contact openings, the regions designated 29, 30 and 34 being formed in FIG. 6. These areas have a high surface concentration of the N conductivity type in the order of 10 21 atoms / cm 3 , cf. in addition the concentration profile shown in FIG. 8C for the relationships shown in FIG. 6, and in particular the point 33 in FIG. 8C. These N + conductive connection regions 29, 30 and 34 can be produced in a conventional manner by introducing dopants. However, it is preferable to fabricate these areas by implanting N-type ions, eg phosphorus, using the method described above with an energy of approximately 40 keV and a dosage of approximately 10 11 ions / cm 2 . In the last method step, as shown in FIG. 7, is carried out in a conventional manner the contact and connection metallization in the form of the connections 35, 36 and 37 for source, drain and the silicon gate. This metallization can be completely conventional in the manner customary in such integrated FET circuits, for example made of aluminum. To the extent that a structure with a self-aligned silicon gate was used in the exemplary embodiment described, it should be noted that the invention is not restricted to this but can also be applied to other self-aligned gate designs. It should only be noted that the masking layer required to ensure the self-alignment of the thin gate insulating layer consists of a material that does not melt or decompose in any other way at the diffusion temperatures of the order of 1000 ° C. or greater that are used. Such other possibilities include, for example, self-aligned field effect transistors with silicon nitride gate technology, in which a thin layer of silicon nitride is used for the self-aligned formation of the source and drain regions relative to the thin gate insulating layer. Furthermore, metals such as molybdenum, tungsten or tantalum which are resistant to high temperatures can be used instead of the silicon described in the present exemplary embodiment in the context of such a method.

Claims (8)

1. Method for making a semiconductor device with selfalignment of doping regions relative to gate surface layers, in particular of an isolation layer field effect transistor structure, wherein, utilizing an ion implantation step, at least two doping regions of a second conductivity type, in particular source and drain regions, are formed with spacing between each other in a semiconductor body of a first conductivity type, and wherein on the semiconductor body at least in the area of said spacing, an ion beam masking layer is applied, characterized in that an ion beam generating the second conductivity type is permitted to act on the semiconductor body at energy and dosage levels sufficient to form buried regions (18, 19), which are initially fully enclosed within and oppositely doped to said semiconductor body (10), in the mutual structure (Fig. 4) defined by the masking layer (14'), and that by a subsequent heat treatment in the presence of masking layer (14') existing at least in the area of the spacing, the buried regions (18, 19) thus formed are caused to extend until they reach the semiconductor surface (Fig. 5).
2. Method in accordance with claim 1, characterized by a semiconductor body of silicon as well as by a masking layer defining the spacing between the doping regions, which comprises an electrically insulative layer on the semiconductor body and a layer of silicon formed thereon.
3. Method in accordance with claim 2, characterized in that the electrically insulative layer comprises silicon dioxide.
4. Method in accordance with any one of the preceding claims, characterized in that the masking layer comprises a layer of silicon nitride at least in the area of the spacing between the doping regions to be formed.
5. Method in accordance with any one of the preceding claims,. characterized in that the heat treatment is effected in such a manner that the semiconductor junctions (20, 21 in Fig. 5), belonging to the doping regions, in the course of their extension caused by the heat treatment intersect the semiconductor surface at the edge points (22, 23) of the masking layer (14') defining the spacing.
6. Method in accordance with any one of the preceding claims, characterized in that the surface concentration of the dopants determining the doping regions of the second conductivity type exceed by a factor of up to about 3 the background doping of the semiconductor body of the first conductivity type.
7. Method in accordance with any one of the preceding claims, characterized in that the ion implantation step is effected through a layer, preferably of silicon dioxide, covering the semiconductor surface in the area of the openings in the masking layer.
8. Method in accordance with any one of the preceding claims, characterized in that after formation of the contact openings to the doping regions and prior to the formation of the accompanying metalization, additional dopants of the second conductivity type for increasing the surface concentration, preferably also using an ion implantation step, are introduced into the exposed regions in the area of the contact openings (28, 31, 32 in Fig. 6).
EP78100443A 1977-08-01 1978-07-19 Method for forming a semiconducter device with self-alignment Expired EP0000545B1 (en)

Applications Claiming Priority (2)

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US820991 1977-08-01
US05/820,991 US4128439A (en) 1977-08-01 1977-08-01 Method for forming self-aligned field effect device by ion implantation and outdiffusion

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EP0000545A1 EP0000545A1 (en) 1979-02-07
EP0000545B1 true EP0000545B1 (en) 1981-02-11

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JPS5427376A (en) 1979-03-01
DE2860467D1 (en) 1981-03-26
IT7826098A0 (en) 1978-07-26
EP0000545A1 (en) 1979-02-07
US4128439A (en) 1978-12-05
CA1112374A (en) 1981-11-10
JPS6046831B2 (en) 1985-10-18
IT1108994B (en) 1985-12-16

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