Abstract:
An integrated circuit arrangement contains an MOS transistor surrounded by an insulation structure, the source and drain thereof being arranged laterally and in different depths. A channel thereof proceeds essentially perpendicular to the surface of the circuit arrangement. Since the channel length is determined by etching or by growing a layer, channel lengths as short as less than 50 nm can be realized. For the manufacture, most of the masks of the traditional circuit arrangements in which planar transistors are integrated are employed, this significantly facilitating incorporation into the semiconductor manufacture.

Description:
This application is a divisional application of Ser. No. 09/065,173, filed Apr. 23, 1998, now U.S. Pat. No. 6,066,876. 
    
    
     BACKGROUND OF THE INVENTION 
     The invention is directed to integrated circuit arrangements having at least one MOS transistor and to methods for the manufacture thereof. 
     In integrated circuit arrangements, MOS transistors and logic gates are currently usually realized in a planar silicon technology, whereby source, channel region and drain are laterally arranged. The channel lengths that can be achieved are thereby dependent on the resolution of the optical lithography employed and on tolerances in the structuring and alignment. Typical channel lengths of 0.6 μm are achieved in the 16 M generation, 0.35 μm in the 64 M generation. 
     A further shortening of the channel lengths of MOS transistors is desirable, for example in circuit arrangements in which fast switching events are required, which is usually the case in logic processing. The packing density of a circuit arrangement can also be increased by MOS transistors with short channel lengths. The space-consuming, large channel width that is otherwise necessary can be foregone by employing short channel lengths, specifically when processing high current intensities in, for example, line drivers. 
     Some possibilities for reducing the channel length have been disclosed. However, the step from the fabrication of a single unit to mass production is time-consuming and costly, specifically in semiconductor technology. New, improved circuit structures are therefore especially attractive for semiconductor manufacture when it is only the existing know-how that has to be recoursed, insofar as possible. This economic aspect is not satisfied by the prior proposals for realizing shortened channel lengths. 
     For example, it was proposed that shorter channel lengths be achieved in planar MOS transistors by replacing the optical lithography with electron beam lithography, a resolution of which is significantly better (see, for example, T. Mizuno, R. Ohba, IEDM Tech. Dig., p.109 (1996)). Individual, functional MOS transistors with channel lengths as short as 50 nm have hitherto been successfully produced with an electron beam printer on a laboratory scale. Although known layouts that must merely be miniaturized can be employed with this technology, electron beam lithography is slow; as a result thereof, it seems unsuitable for employment in semiconductor manufacture. 
     Masks are under-etched, i.e. hollowed out underneath, by isotropic over-etching of layers, as a result of which smaller structural sizes than those belonging to lithography can likewise be produced. However, it is difficult to achieve reproducible results with this technique, for which reason it will presumably also not be employed on a broad basis in semiconductor manufacture. 
     Further possibilities of obtaining short channel lengths are available given a channel path that is perpendicular to the surface of the circuit arrangement instead of parallel. Transistors having a perpendicular channel course are referred to as “vertical transistors”. The channel length is thereby determined by the layer thickness of the channel region and is thus independent of the resolution of the lithography employed. 
     A circuit arrangement of integrated MOS transistors has been disclosed whose source, channel region and drain are stacked above one another as layers (see German Letters Patent DE 4340967 C1). The contacting of source, drain and gate electrode of such an MOS transistor, accordingly, occurs differently than given planar transistors. At least two of the layers are grown by epitaxy. A depression that has its sidewalls provided with a gate dielectric and a gate electrode is etched into this layer sequence. A channel length as short as less than 50 nm is achieved by this procedure. What is especially disadvantageous is the increased process expense when incorporating this circuit arrangement into semiconductor manufacture due to the manufacturing method that clearly differs from the traditional manufacturing method. 
     SUMMARY OF THE INVENTION 
     It is an object of the invention to specify an MOS transistor that is situated within an integrated circuit arrangement, and which has an especially short channel length and can be integrated into the semiconductor manufacture with reduced expense. Furthermore, a manufacturing method is provided for such an MOS transistor incorporated in an integrated circuit arrangement. 
     This problem is solved by a vertical MOS transistor that is surrounded by a traditional insulation structure. A transistor at one sidewallis designed of a depression. The transistor is individually driveable and can be manufactured by use of a layout of traditional planar transistors, except for one or a few additional masks. Source/drain regions are arranged diagonally offset relative to one another, i.e. laterally and at different depths. The flow of current proceeds essentially perpendicular to the surface of the circuit arrangement. 
     The layout of the traditional planar transistors is employed for manufacturing a circuit arrangement of the invention, with the difference that a gate mask employed for the generation of a gate electrode is shortened compared to a gate mask for generating the traditional planar transistors in the region of the MOS transistor. One of the additional masks is employed for generating the depression. 
     The term “channel width” describes the dimension of the channel perpendicular to the flow of current and parallel to the gate electrode. 
     The term “junction depth” describes the path along which the source/drain regions have minimal spacing from one another, namely perpendicular to the flow of current and perpendicular to the gate electrode. 
     Since the channel length is determined by etching or by growing a layer, channel lengths as short as less than 50 nm can be realized. The invention makes it possible to process circuit arrangements that were fabricated in planar technology with the assistance of the few additional masks with transistors having a considerably shorter channel length, but the same channel width. Merely due to the contacting of source and drain that clearly differs from planar transistors, new masks and a layout differing completely from the layout of traditional planar transistor are required for the manufacture of previously described vertical MOS transistors. The employment of already existing masks for MOS transistors of the invention considerably reduces the expense required, given integration into semiconductor manufacture. 
     A further advantage of employing masks that are already present is the easier incorporation of the new circuit structure into circuit arrangements that also comprise known elements. 
     The designs of known circuit arrangements can be largely accepted, since only a slight modification has to be undertaken at the locations at which improved transistors are needed. 
     Except for height variations of approximately 150 nm, the surface of the circuit arrangement looks like that of traditional circuit arrangements, this making this invention especially attractive for the layout designer. 
     The sequence of process steps is essentially the same as in the production of the traditional planar transistors. 
     The same materials as in the production of the traditional planar transistors can be employed. 
     Complicated method steps, such as electron beam lithography, and techniques susceptible to malfunction, such as over-etching, are not necessary given the employment of vertical transistors. 
     A further advantage of the invention is that the simultaneous manufacture of the source/drain regions by implantation —which, by contrast to other vertical transistors, is possible due to the lateral arrangement of these regions —represents a step in the traditional manufacturing process. 
     The lateral arrangement also offers the advantage that the channel region can be easily connected to a fixed potential, as a result whereof leakage currents and changes in the cutoff voltage are kept small. 
     Together with the vertical arrangement of source and drain, the lateral arrangement yields a junction depth that is small even compared to planar transistors. 
     Negative effects of short channel lengths, such as, for example, the increased sensitivity to punch-through, are thereby positively influenced. 
     It lies within the scope of the invention to determine the channel length by epitaxy of semiconductor material such as silicon or germanium. A sidewall along which the channel region forms arises, for example, with the assistance of a mask that allows the epitaxy only at specific locations. After removal of the mask, the sidewall arises in this way. 
     Another possibility of generating the sidewall is comprised in etching the epitaxially grown semiconductor material at specific locations. It is advantageous therefor to apply a layer before the epitaxy of the semiconductor material that serves as etch stop in the etching process. When the semiconductor material is composed of silicon, then this layer acting as etch stop preferably contains germanium since epitaxial growth of silicon thereby becomes possible on the layer, and the layer is selectively etchable relative to the epitaxially grown semiconductor material. When the gate dielectric is generated by thermal oxidation, the germanium at the floor of a depression that arises in the etching process is removed since it is difficult to oxidize. 
     It lies within the scope of the invention to determine the channel length on the basis of an etching depth when etching silicon. 
     It is advantageous to design the gate electrode as spacer. First, its alignment relative to the sidewall of the depression thereby occurs automatically, i.e. without using masks to be adjusted. Second, the expanse of the gate electrode is especially small as a result thereof, this increasing the packing density. A gate mask is employed for generating the spacer-shaped gate electrode, this gate mask being shortened such in the region of the transistor compared to a gate mask for generating the traditional planar transistor such that it covers only one end of a channel region of the MOS transistor. 
     It is advantageous to etch the gate electrode back as far as possible so that the area provided with the gate dielectric between gate electrode and drain, to which a high capacitance that reduces the switching speed is assigned, becomes especially small. 
     It is advantageous to form the gate dielectric by thermal oxidation since the quality of the boundary surface to the channel region is thereby improved. The defects that arise in this surface along a mask by etching the depression or by growing semiconductor material are integrated into the oxide, where they have no influence. 
     It is advantageous to implement the generation of the source/drain regions after the production of the gate electrode. The gate electrode then serves as mask in the implantation. First, this procedure, which becomes possible due to the small expanse of the gate electrode designed as spacer, is a step in the traditional method for manufacturing the planar transistors. Second, the junction depth becomes especially small as a result thereof. 
     The invention is explained in greater detail below on the basis of exemplary embodiments that are shown in the drawing figures. 
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS 
     FIG. 1 shows a first substrate after production of a doped layer, of an insulating structure, of a mask and of an additional layer; 
     FIG. 2 shows the first substrate after the mask was removed and two source/drain regions, a gate dielectric and a gate electrode are produced; 
     FIG. 3 shows the first substrate after an insulating layer and via holes were produced and the via holes were filled with metal by applying a metal layer; 
     FIG. 4 shows a second substrate after a doped layer, an insulation structure, a layer serving as etch stop and an additional layer are produced; 
     FIG. 5 shows a third substrate after a doped layer, an insulation structure and a depression are produced; 
     FIG. 6 shows a plan view onto the first substrate in which a few masks employed in the manufacturing method and the gate electrode are shown; and 
     FIG. 7 shows a plan view onto a fourth substrate in which a few masks employed in the manufacturing method of a traditional planar transistor according to the Prior Art are shown. 
    
    
     DESCRIPTION OF THE PREFERRED EMBODIMENTS 
     The illustrations in the Figures are not to scale. 
     In a first exemplary embodiment, a first substrate  1  is a semiconductor wafer of single-crystal silicon in which an n-doped layer A is generated adjoining a surface of the first substrate  1 . The dopant concentration of the doped layer A amounts to approximately 10 18  cm  −3 . 
     As in the Prior Art for generating a traditional planar transistor, an insulation structure I that completely surrounds a part of the doped layer A is produced by thermal oxidation (see FIG.  1 ). An insulation mask M 1  is thereby employed that coincides with an insulation mask M 1  for the manufacture of the insulation structure surrounding the traditional planar transistor (see FIGS.  6  and  7 ). 
     After application of a mask M 2  that covers at least one half of the part of the doped layer A that is surrounded by the insulation structure I, an additional layer Z of silicon whose depth amounts to approximately 150 nm and whose width and length amount to approximately 1 μm is generated by selective epitaxy (see FIG.  1 ). Serving as mask M 2  is an SiO 2  layer manufactured with a TEOS method that is deposited surface-wide onto the doped layer A with a thickness of approximately 200 nm and that is subsequently structured with the assistance of a photoresist mask (not shown). After application of the additional layer Z, the mask M 2  is in turn removed with, for example, hydrofluoric acid, and a depression V arises as a result thereof. 
     A thermal oxidation is implemented for producing a gate dielectric i 1 , as a result whereof the additional layer Z and the part of the doped layer A is partially covered by the gate dielectric i 1  having a thickness of approximately 5 nm (see FIG.  2 ). 
     Subsequently, a gate electrode G is applied to a sidewall of the depression V (see FIG.  2 ). For producing the gate electrode G, in situ doped polysilicon is deposited in a thickness of approximately 100 nm and is subsequently etched with the assistance of a first gate mask M 3  until the gate electrode G arises in the form of a spacer on the part of the doped layer A. A part of the gate electrode G that arises outside the part of the doped layer A serves for the contacting of the gate electrode G and is broader than the remaining part of the gate electrode G (see FIG.  6 ). The first gate mask M 3  essentially coincides with a gate mask M 3 s that is employed in the Prior Art for generating a gate electrode of the traditional planar transistor, with the difference that the first gate mask M 3  is shortened in the region of the part of the doped layer A such that only one end of the sidewall of the depression V is covered (see FIGS.  6  and  7 ). 
     Other spacers that arise in the production of the gate electrode G adjoining the insulation structure I are removed with the assistance of a second gate mask M 4  (see FIG.  6 ). The second gate mask M 2  thereby essentially covers the gate electrode G. 
     An upper source/drain region o and a lower source/drain region u, which are p-doped and approximately 100 nm deep, are generated by implantation and subsequent tempering. As a result thereof, the upper source/drain region o adjoins the sidewall, and the lower source/drain region u adjoins a floor of the depression V (see FIG.  2 ). The dopant concentrations of the upper source/drain region o and of the lower source/drain region u amount to approximately 10 21  cm 3 . In the implantation, the gate electrode G acts as mask in the generation of the upper source/drain region o and of the lower source/drain region u, which minimizes the junction depth. 
     Subsequently, an insulating layer i 2  of SiO 2  is applied surface-wide (see FIG.  3 ). Three via holes K are introduced into the insulating layer i 2 , the first thereof extending up to the upper source/drain region o, the second up to the lower source/drain region u, and the third up to the part of the gate electrode G that serves or contacting (see FIGS.  3  and  6 ). A via hole mask M 5  is thereby employed that coincides with a via hole mask M 5 s for the production of via holes for the traditional planar transistor (see FIGS.  6  and  7 ). 
     A metal layer Me that, for example, contains aluminum is applied surface-wide and structured (se FIG.  3 ). Voltages can be applied to the upper source/drain region o and to the lower source/drain region u via the via holes K filled with metal by the metal layer Me. The gate electrode G is also contacted via a part of the structured metal layer Me (see FIG.  6 ). A part of the additional layer Z that is located between the upper source/drain region o and the lower source/drain region u acts as channel region Ka. Given a corresponding drive of the gate electrode G, a conductive channel forms at the sidewall of the depression V to which the upper source/drain region o is adjacent. It is thus a matter of a vertical transistor that is laterally surrounded by the insulation structure  1 . 
     As in the first exemplary embodiment, a second substrate  1 ′of silicon, a doped layer A′ and an insulation structure I′ are provided in a second exemplary embodiment (see FIG.  4 ). A layer Ge of germanium, whose thickness lies in the nm range, is applied on a surface of the doped layer A′ and serves as etch stop. Subsequently, approximately 150 nm semiconductor material that contains silicon is grown over the layer Ge of germanium. 
     With the assistance of a mask (not shown) that is essentially complementary to the mask M 2  of the first exemplary embodiment, a depression V′ having a width and length of approximately 1 μm is generated by etching silicon selectively to germanium, the depth of this depression V′ being defined by the layer Ge of germanium acting as etch stop. For example, choline is suitable as etchant. 
     Germanium is removed at a floor of the depression V′ by etching germanium electively to silicon. For example, a mixture of HF, H 2 O 2  and acetic acid is suitable for the etching process. 
     Analogous to the first exemplary embodiment, a gate dielectric, a gate electrode, an upper and lower source/drain region, an insulating layer and via holes filled with metal are subsequently generated. 
     In a third exemplary embodiment, as in the first exemplary embodiment, a third substrate  1  ″ of silicon, a doped layer A″ and an insulation structure I″ are provided. 
     With the assistance of a mask (not shown) that is essentially complementary to the mask M 2  of the first exemplary embodiment, an approximately 150 nm deep depression V″ having a width and length of approximately 1 μm is generated in the doped layer A″ by etching silicon selectively to germanium (see FIG.  5 ). 
     Subsequently, the mask is in turn removed in an etching step. 
     Analogous to the first exemplary embodiment, a gate dielectric, a gate electrode, an upper and lower source/drain region, an insulating layer of SiO 2  and via holes filled with metal are subsequently generated. 
     Many variations of the three exemplary embodiments that likewise lie within the scope of the invention are conceivable. In particular, the dimensions of the disclosed layers, regions and depressions can be adapted as desired to the respective requirements. The same is also true of the proposed dopant concentrations. Any conductive material, for example metal, metal silicide or combinations thereof, is an alternative for the gate electrode. Structures and layers of SiO 2  can, in particular, be generated by thermal oxidation or by a TEOS process. Alternatively, all structures and layers of SiO 2  can be manufactured of some other material, for example silicon nitride. 
     The doped layer can be p-doped. The source/drain regions can be n-doped. 
     The gate electrode can also be initially produced of non-doped silicon and be subsequently doped by implantation. 
     FIG. 7 shows a fourth substrate  1 * in which a traditional planar transistor is produced. 
     Although various minor changes and modifications might be proposed by those skilled in the art, it will be understood that our wish is to include within the claims of the patent warranted hereon all such changes and modifications as reasonably come within our contribution to the art.