Abstract:
An SRAM cell arrangement which includes six MOS transistors per memory cell wherein each transistor is formed as a vertical transistors. The MOS transistors are arranged at sidewalls of trenches. Parts of the memory cell such as, for example, gate electrodes or conductive structures fashioned as spacers are contacted via adjacent, horizontal, conductive structures arranged above a surface of a substrate. Connections between parts of memory cells occur via third conductive structures arranged at the sidewalls of the depressions and word lines via diffusion regions that are adjacent to the sidewalls of the depressions within the substrate, via first bit lines, via second bit lines and/or via conductive structures that are partially arranged at different heights with respect to an axis perpendicular to the surface. Contacts contact a plurality of parts of the MOS transistors simultaneously.

Description:
BACKGROUND OF THE INVENTION 
     1. Field of the Invention 
     The present invention relates, generally, to an SRAM cell arrangement having a plurality of memory cells and, more specifically, to such an SRAM cell arrangement wherein each of its memory cells respectively includes 6 vertical MOS transistors such that various contacts contact a plurality of parts of the transistors simultaneously. 
     2. Description of the Prior Art 
     An SRAM cell arrangement is a memory cell arrangement with random access to stored information. In contrast to a DRAM cell arrangement wherein the information must be refreshed at regular time intervals, the information is statically stored in an SRAM sell arrangement. 
     What are referred to as 6T memory cells are being increasingly utilized in SRAM cell arrangements. A 6T memory cell includes four MOS transistors interconnected as a flipflop and two selection transistors. The flipflop is one of the two stable conditions. The condition of the flipflop represents a logical quantity, 0 or 1. By driving the selection transistors via a word line, the condition can be determined via two bit lines. Thus, the information can be read out and the condition can be modified and, thus, new information can be stored. 
     Since the memory density is increasing from memory generation to memory generation, the required area of the 6T memory cell must be reduced from generation to generation. Semiconductor International (November 1996) pages 19 and 20, presents a 6T memory cell that can be manufactured with an area of 55F 2 , whereby F is the minimum structural size that can be manufactured in the respective technology. Self-aligned contacts (i.e., contacts without utilization of aligning masks), are produced and local connections (i.e., connections that lie within the cell, are utilized. 
     The present invention is based on the problem of specifying an SRAM cell arrangement that includes 6T memory cells as memory cells and can be manufactured with especially high packing density. Further, a manufacturing method for such an SRAM cell arrangement should be specified. 
     SUMMARY OF THE INVENTION 
     Such problem is addressed by the present invention in an SRAM call arrangement having a plurality of memory cells wherein each memory cell includes 6 vertical MOS transistors with connections between parts of the transistors being as follows. A first source/drain region of a first transistor is connected to a first source/drain region of a second transistor and to a first voltage terminal. A second source/drain region of the first transistor is connected to a first source/drain region of a third transistor, a first source/drain region of a fifth transistor, a gate electrode of the second transistor and a gate electrode of a fourth transistor. A gate electrode of the first transistor is connected to a second source/drain region of the second transistor, a first source/drain region of the fourth transistor, a gate electrode of the third transistor and a first source/drain region of a sixth transistor. A second source/drain region of the third transistor is connected to a second source/drain region of the fourth transistor and a second voltage terminal. A second source/drain region of the fifth transistor is connected to a first bit line. A gate electrode of the fifth transistor is connected to a gate electrode of the sixth transistor and to a word line. A second source/drain region of the sixth transistor is connected to a second bit line. The third transistor and the fourth transistor are complementary to the first transistor, the second transistor, the fifth transistor and the sixth transistor. It lies within the scope of the present invention for improving various properties of the memory cell for the SRAM cell arrangement to integrate further complements such as, for example, capacitors, into the memory cell in addition to the sixth transistors of a memory cell. 
     In the inventive SRAM cell arrangement, the sixth transistors of each memory cell are formed as vertical transistors. The area of the memory cell thereby becomes particularly small. 
     The six transistors are formed at sidewalls of stripe-shaped depressions proceeding parallel to one another, which can be formed as trenches in a substrate, as a result whereof the density of the connections is increased and the area of the memory cell is reduced. The first transistor and the second transistor are arranged at a second sidewall of a first trench; the fifth transistor and the sixth transistor are to be arranged at a second sidewall of a second trench; and the third transistor and the fourth transistor are arranged of a first sidewall of the fourth trench. Third trenches filled with insulating material can, as insulating structures, insulate parts of transistors, which are complementary with one another, from one another. 
     It is advantageous to respectively formed gate electrodes of the six transistors as a spacer that adjoins a horizontal conductive structure arranged outside the depressions. The structure that is formed from the spacer and the horizontal, conductive structure is also referred to as strap. It enables a separate connection of the gate electrodes via an appertaining, horizontal, conductive structure to other parts of the transistors. For producing the horizontal, conductive structure before the production of the trenches, it is advantageous to generate a conductive layer. As a result, the spacer is connected in self-aligned fashion to the horizontal, conductive structure that arises from the conductive layer. 
     For diminishing the plurality of contacts and, thus, the area of the memory cell, it is advantageous to arrange contacts such that they partially overlap laterally with the horizontal, include conductive structures. 
     For increasing the density of the connections and, thus, for reducing the area of the memory cell, it is advantageous to employ a plurality of connection planes that conductive structures, bit lines and/or word lines. 
     So that no current flows along the sidewalls of the depressions between neighboring source/drain regions of different transistors, highly doped channel stop regions can be generated between the transistors by oblique implantation at the sidewalls of the depressions. The channel stop regions are doped with a conductivity type that is opposite the conductivity type of the neighboring source/drain regions. 
     For connecting neighboring source/drain regions that are located at a different height relative to an axis that proceeds perpendicular to a surface of the substrate, it is advantageous to generate highly doped diffusion regions. The diffusion regions can be generated by oblique implantation at parts of the sidewalls of the depressions. The diffusion regions are doped with the conductivity type of the neighboring source/drain regions. 
     When source/drain regions are generated after generating the depressions by implantation, then it is advantageous to provide the sidewalls of the depressions with spacers and to provide parts of the memory cell with a preliminary structure before the implantation in order to protect the sidewalls and the parts of the memory cell from the implantation. 
     It is advantageous to formed the word line as a spacer along a sidewall of one of the depressions. The first bit line and the second bit line are formed transversely relative to the word line. 
     For reducing the area of the memory cell, it is advantageous when the fifth gate electrode of the fifth transistor and the sixth gate electrode of the sixth transistor are parts of the word line. 
     It is further advantageous to arrange memory cells neighboring along the first bit line mirror-symmetrically relative to an axis that proceeds along a center line of a depression, namely such that the depression is divided by the memory cells. The area of a memory cell is diminished as a result thereof. 
     It is advantageous to form transistors complementary to one another at different depressions. As a result, floors of the depressions can be continuously doped by respectively one conductivity type and can be simultaneously employed as source/drain regions and as conductive structures. 
     It is advantageous to arrange a first insulating structure that, for example, can be formed as a depression filled with insulating material between a depression at which transistors are formed and a neighboring transmission at which complementary transistors are formed. 
     It is advantageous to form a first conductive structure or, respectively, a second conductive structure that is connected to a first voltage terminal or, to a second voltage terminal respectively along a floor of a depression in the form of a doped region within the substrate. For reducing the area of the memory cell, it is advantageous when the first source/drain region of the first transistor and the first source/drain region of the second transistor are parts of the second conductive structure, and the second source/drain region of the third transistor and the second source/drain region of the fourth transistor are parts of the first conductive structure. 
     For increasing the density of the connections, it is advantageous to employ conductive structures arranged in an additional connecting level, these being arranged in the form of spacers at sidewalls of depressions and connecting parts of transistors. 
     Additional features and advantages of the present invention are described in, and will be apparent from, the Detailed Description of the Preferred Embodiments and the Drawings. 
    
    
     DESCRIPTION OF THE DRAWINGS 
     FIG. 1 shows a portion from a surface of a substrate which includes a memory cell. The surface is divided into horizontal regions and vertical regions which overlap the horizontal regions; 
     FIG. 2 shows a cross-section along a boundary line of a seventh horizontal region and an eighth horizontal region through the substrate after first insulating structures, first doped wells, second doped wells, first source/drain regions of fourth transistors, second source/drain regions of second transistors, second source/drain regions of first transistors, first source/drain regions of third transistors, second source/drain regions of fifth transistors and second source/drain regions of sixth transistors were produced; 
     FIG. 3 shows the cross-section from FIG. 2 after a second insulating structure, a conductive layer, a preliminary structure, first trenches, second trenches, fourth trenches, channel stop regions, diffusion regions, spacers, first conductive structures, first source/drain regions of the first transistors, first source/drain region of the second transistors, first source/drain regions of the fifth transistor, first source/regions of the sixth transistors, second conductive structures, second source/drain regions of the third transistors and second source/drain regions of the fourth transistors were produced; 
     FIG. 4 shows the cross-section from FIG. 3 after a gate dielectric, gate electrodes, third conductive structures and horizontal, conductive structures were produced; 
     FIG. 5 shows the cross-section from FIG. 4 after second contacts, fourth contacts, fifth contacts, sixth contacts, fifth conductive structures, sixth conductive structures and a third insulating structure were produced; 
     FIG. 6 a  shows the cross-section from FIG. 5 after a fourth insulating structure, first contacts, third contacts, seventh contacts, eighth contacts, fourth conductive structures, first bit lines and second bit lines were produced; 
     FIG. 6 b  shows the substrate from FIGS. 6 a  in a cross-section parallel to the cross-section of FIG. 6 a  along the one boundary line between a thirteenth horizontal region and a fourteenth horizontal region; 
     FIG. 6 c  shows the substrate of FIG. 6 a  in a cross-section parallel to the cross-section of FIGS. 6 a  along a twelfth horizontal region; 
     FIG. 6 d  shows a cross-section perpendicular to the cross-section of FIG. 6 a  through the substrate of FIG. 6 a  along a third vertical region; 
     FIG. 7 a  shows the portion from FIG. 1 after the first insulating structures in the form of third trenches filled with insulating material were produced, whereupon a fourth mask was applied onto the surface; 
     FIG. 7 b  shows the portion from FIG. 7 a  after the first trenches, the second trenches and the fourth trenches were produced with the assistance of a sixth mask; 
     FIG. 7 c  shows the portion from FIG. 7 b,  whereupon a seventh mask was applied onto the surface; 
     FIG. 7 d  shows the portion from FIG. 7 c,  whereupon an eighth mask was applied onto the surface; 
     FIG. 7 e  shows the portion from FIG. 7 d,  whereupon an eleventh mask was applied onto the surface; 
     FIG. 7 f  shows the portion from FIG. 7 e,  whereupon a thirteenth mask was applied onto the surface; 
     FIG. 7 g  shows the portion from FIG. 7 f,  whereupon a fourteenth mask was applied onto the surface; 
     FIG. 7 h  shows the portion from FIG. 7 g,  whereupon a sixteenth mask was applied onto the surface; 
     FIG. 7 i  shows the portion from FIG. 7 a,  whereupon a eighteenth mask was applied onto the surface. 
    
    
     DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS 
     In the following, a formulation “region a up to including region β” refers to all regions that are arranged within a memory cell between the region a and the region β as well as the region a and the region β. α and β respectively stand for a number or a letter. 
     In a first exemplary embodiment, a substrate S is a wafer of silicon. An x-axis x and a y-axis y perpendicular to the x-axis x proceed in a surface O of the substrate S (see FIG.  1 ). Parts of the surface O at which a respective memory cell is generated are respectively divided into stripe-shaped, horizontal regions adjoining one another and proceeding parallel to the x-axis x. The parts of the surface O are likewise divided into respective stripe-shaped, vertical regions joining one another and proceeding parallel to the y-axis (see FIG.  1 ). Memory cells which are adjacent, or neighboring, in the direction of the x-axis are generated mirror-symmetrically relative with one another with respect to axes proceeding parallel to the y-axis; either first vertical regions  1  or thirteenth vertical regions  13  of these memory cells adjoining one another. Of respectively two neighboring memory cells to be generated in the direction of the y-axis, a first horizontal region a of one of the memory cells and a twenty second horizontal region v of another adjoin one another. 
     With the assistance of a first mask (not shown) of photoresist which does not respectively cover the tenth vertical region  10  and the eleventh vertical region  11  in the memory cells, third trenches G 3  that are approximately 500 nm deep are generated by etching silicon. The etchant is, for example, HBr+NF 3 +He+O 2 . By depositing SiO 2  in a thickness of approximately 600 nm in a TEOS process and subsequent re-etching, the third trenches G 3  are filled with SiO 2 . First insulating structures I 1  thereby arise (see FIG.  2 ). 
     The first insulating structures I 1  are suitable for insulating parts of transistors complementary to one another that are to be produced from one another. 
     With the assistance of a second mask (not shown) of photoresist, which respectively covers the eleventh vertical region  11  through the thirteenth vertical region  13  in the memory cells, approximately 2 μm deep p-doped, first wells Wa 1  are produced by implantation (see FIG.  2 ). 
     With the assistance of a third mask (not shown) of photoresist, that respectively does not cover the eleventh vertical region  11  through the thirteenth vertical region  13  in the memory cells, approximately 2 μm deep n-doped second wells Wa 2  are generated by implantation (see FIG.  2 ). The first insulating structures I 1 , thus, respectively proceed between a first well Wa 1  and a second well Wa 2 . The first well Wa 1  and the second well Wa 2  are striped-shaped and proceed substantially parallel to one another. The dopant concentrations of the first wells Wa 1  and of the second wells Wa 2  amount to approximately 3*10 17  cm −3 . 
     With the assistance of a fourth mask M 4  of photoresist (see FIG. 7 a ), hook-shaped, n-doped regions approximately 150 nm deep are generated by implantation within the first well Wa 1 . The dopant concentration of the hook-shaped regions amounts to approximately 5*10 20  cm −3 . Parts of the hook-shaped regions are suitable as second source/drain regions  1  S/D 1  of first transistors, as second source/drain regions  2  S/D 1  of second transistors, as second source/drain regions  5  /SD 2  of fifth transistors and as second source/drain regions  6  S/D 2  of sixth transistors (see FIG.  2 ). 
     To that end, the fourth mask M 4  respectively does not cover regions in the memory cells: wherein the fourteenth horizontal region n through the twenty-first horizontal region u overlap with the first vertical region  1  through the fifth vertical region  5 ; wherein the fourth horizontal region d through the tenth horizontal region j overlap with the first vertical region  1  through the fifth vertical region  5 ; wherein the fourteerth horizontal region n up to including the seventeenth horizontal region q overlap with the sixth vertical region  6  and the seventh vertical region  7 ; wherein the fourth horizontal region d through the seventh horizontal region g overlap with the sixth vertical region  6  and the seventh vertical region  7 ; wherein the eleventh horizontal region k through the seventeenth horizontal region q overlap with the eighth vertical region  8  and the ninth vertical region  9 ; and wherein the first horizontal region a through the seventh horizontal region g overlap with the eighth vertical region  8  and the ninth vertical region  9 . 
     With the assistance of a fifth mask (not shown) of photoresist, rectangular, p-doped regions approximately 150 nm deep are generated within the second wells Wa 2 . The dopant concentration of the rectangular regions amounts to approximately 5*10 20  cm −3 . The p-doped regions are suitable as first source/drain regions  3  S/D 1  of third transistors and first source/drain regions  4  S/D 1  of fourth transistors (see FIG.  2 ). 
     To that end, the fifth mask does not cover regions wherein the fourteenth horizontal region n through the twentieth horizontal region t overlap with the eleventh vertical region  11  through the thirteenth vertical region  13 , and regions wherein the third horizontal region c through the tenth horizontal region j overlap with the eleventh vertical region  11  through the thirteenth vertical region  13 . Subsequently, a first insulating layer (not shown) is generated in that SiO 2  is deposited in a thickness of approximately 100 nm. An approximately 100 nm thick, conductive layer S 1  is generated over the first insulating layer by deposition of doped polysilicon. A second insulating layer (not shown) is generated over the conductive layer S 1  in that SiO 1  is deposited in a thickness of a approximately 100 nm (see FIG.  3 ). 
     With the assistance of a stripe-shaped, sixth mask M 6  of photoresist (see FIG. 7 b ), approximately 500 nm deep, first trenches G 1 , second trenches G 2  and fourth trenches G 4  are produced parallel to the third trenches G 3  by etching silicon and SiO 2  (see FIG.  3 ). The depth of the first trenches G 1 , of the second trenches G 2  and of the fourth trenches G 4  starting from the surface O amounts to approximately 500 nm. The first transistor G 1  and the second trenches G 2  proceed within the first wells Wa 1 . The fourth trenches G 4  proceed within the second wells Wa 2 . A second insulating structure I 2  thereby arises from the first insulating layer, and a preliminary structure VS arises from the second insulating layer. 
     To that end, the sixth mask M 6  respectively does not cover the first vertical region  1 , the sixth vertical region  6 , the seventh vertical region  7  and the thirteenth vertical region  13  in the memory cells. 
     With the assistance of a seventh mask M 7  of photoresist (see FIG. 7 c ) and an eighth mask M 8  of photoresist (see FIG. 7 d ), p-doped, first channel stop regions Cl are produced by oblique implantation at second sidewalls  1 F 2  of the first trenches G 1 , at first sidewalls  2 F 1  of the second trenches G 2  and at second sidewalls  2 F 2  of the second trenches G 2  (see FIG.  3 ). 
     To that end, the seventh mask M 7  respectively covers the second well Wa 2 , as well as regions in the memory cells wherein the eighteenth horizontal region r through the twentieth horizontal region t overlap with the first vertical region  1  through the eighth vertical region  8 , and regions wherein the eighth horizontal region h through the tenth horizontal region j overlaps with the first vertical region  1  through the eighth vertical region  8 . The eighth mask M 8  respectively covers the second well Wa 2  in the memory cell, as well as regions: wherein the eighth horizontal region h through the tenth horizontal region j overlaps with the first vertical region  1  and the second vertical region  2 ; wherein the eighteenth horizontal region r through the twentieth horizontal region t overlap with the first vertical region  1  and the second vertical region  2 ; wherein the fourteenth horizontal region n through the sixteenth horizontal region p overlaps with the seventh vertical region  7  through the ninth vertical region  9 ; and wherein the third horizontal region c through the sixth horizontal region f overlap with the seventh vertical region  7  through the ninth vertical region  9 . 
     With the assistance of a ninth mask (not shown) of photoresist, n-doped, second channel stop regions C 2  are produced by oblique implantation at first sidewalls  4 F 1  of the fourth trenches G 4  (not visible in the cross-section shown in FIG. 3, but see FIG. 6 b ). 
     To that end, the ninth mask in the memory cells respectively covers the first wells Wa 1  as well as regions wherein the eighteenth horizontal region r through the twentieth horizontal region t overlap with the twelfth vertical region  12  and the thirteenth vertical region  13 , and regions wherein the eighth horizontal region h through the tenth horizontal region j overlap with the twelfth vertical region  12  and the thirteenth vertical region  13 . 
     The first channel stop regions C 1  and the second channel stop regions C 2  together form channel stop regions C. The dopant concentration of the channel stop regions C amounts to approximately 10 19 cm −3  and is higher then the dopant concentration of the first wells Wa 1  and of the second wells Wa 2 . As a result of their high dopant concentration, the channel stop regions C prevent a flow of current between neighboring source/drain regions. 
     With the assistance of a tenth mask (not shown) of photoresist, n-doped diffusion regions are generated by oblique implantation at the first sidewalls  2 F 1  of the second trenches G 2 . 
     To that end, the tenth mask in the memory cells respectively does not cover regions wherein the seventeenth horizontal region q through the twenty-first horizontal region u overlap with the fourth vertical region  4  through the eighth vertical region  8 , and regions wherein the seventh horizontal region g through the eleventh horizontal region k overlap with the fourth vertical region  4  through the eighth vertical region  8 . 
     The diffusion regions are divided into first and second diffusion regions D 2  (see FIG.  3 ). The first diffusion regions adjoin the second source/drain regions  1  S/D 2  of the first transistors, and the second diffusion regions D 2  adjoin the second source/drain regions  2  S/D 2  of the second transistors. The dopant concentration of the diffusion regions is high and amounts to approximately 10 20  cm −3 . 
     Subsequently, SiO 2  is deposited in a thickness of approximately 80 nm in a TEOS process and is etched back in order to generate spaces Sp at the second sidewalls IF 2  of the first trenches G 1 , at the first sidewalls  2 F 1  of the second trenches G 2 , at the second sidewalls  2 F 2  of the second trenches G 2 , at the first sidewalls  4 F 1  of the fourth trenches G 4  and at the second sidewalls of the fourth trenches G 4 . 
     With the assistance of an eleventh mask M 11  of photoresist (see FIG. 7 e ), n-doped, first source/drain regions  5  S/D 1  of the fifth transistors (not visible in the cross-section shown in FIG. 3, but see FIG. 6 b ) and first source/drain regions  6  S/D 1  of the sixth transistors are generated by implantation at floors of the second transistors G 2  with a respective dopant concentration of approximately 5*10 2  cm 3 , and n-doped, first conductive structures L 1  are also generated at floors of the first trenches G 1  (see FIG.  3 ). The first conductive structures L 1  proceed along the floors of the first trenches G 1  and are connected to a first voltage terminal. Parts of the first conductive structures L 1  are suitable as first source/drain regions of the first transistors and as first source/drain regions  2  S/D 1  of the second transistors (see FIG.  3 ). 
     To that end, the eleventh mask M 11  in the memory cells respectively does not cover the first trenches G 1  nor regions wherein the fourteenth horizontal region n through the twentieth horizontal region t overlap with the third vertical region  3  through the eighth vertical region  8 , and rectangular regions wherein the third horizontal region c through the tenth horizontal region j overlap with the third vertical region  3  through the eighth vertical region  8 . As a result, the first source/drain regions  5  S/D 1  of the fifth transistors are insulated from the first source/drain regions  6  S/D 1  of the sixth transistors. 
     With the assistance of a twelfth mask (not shown) of photoresist, which does not cover the fourth trenches G 4  in the memory cells, p-doped, second conductor structures L 2  are generated by implantation at the floors of the fourth trenches G 4  (see FIG.  3 ). The dopant concentration of the second conductive structures L 2  amounts to approximately 5*10 20  cm −3 . The second conductive structures L 2  are connected to a second voltage terminal. Parts of the second conductive structure L 2  are suitable as second source/drain regions of the third transistors and as second source/drain regions  4  S/D 2  of the fourth transistors. 
     When producing the first source/drain regions  5  S/D 1  of the fifth transistors, the first source/drain regions  6  S/D 1  of the sixth transistors, the first conductive structures L 1  and the second conductive structures L 2 , the preliminary structure VS and the spacers Sp prevent the implantation of other parts of the memory cells. 
     SiO 2  is etched with, for example, HF as etchant. As a result, the preliminary structure VS is removed. 
     Subsequently, a deep dielectric Gd is generated by thermal oxidation (see FIG.  4 ). In order to remove parts of the gate dielectric Gd at sidewalls of the conductive layer S 1  structured by the generation of the first trenches G 1 , of second trenches G 2  and of the fourth trenches G 4 , doped polysilicon is deposited in a thickness of approximately 40 nm and is etched back to such an extent that the polysilicon is arranged in the form of spacers under the sidewalls of the structured, conductive layer S 1 . Subsequently, SiO 2  is etched such with, for example, HF that sidewalls of the structured, conductive layer S 1  are uncovered. 
     Doped polysilicon is deposited in a thickness of approximately 80 nm and is etched back. As a result, spacers that contact the structured, conductive layer S 1  arise at the sidewalls of the first trenches G 1 , of the second trenches G 2  and of the fourth trenches G 4 . 
     With the assistance of a thirteenth mask M 13  of photoresist (see FIG. 7 f ), silicon is etched such that parts of the spacers are removed. C 2 F 6 +O 2 , for example, is suitable as etchant. As a result, first gate electrodes of the first transistors, second gate electrodes Ga 2  of the second transistors, third gate electrodes of the third transistors, fourth gate electrodes Ga 4  of the fourth transistors and third conductive structures L 3  that are arranged at the first sidewalls  2 F 1  of the second trenches G 2  arise (see FIG.  4 ). Spacers that are arranged at the second sidewalls  2 F 2  of the second trenches G 2  are not etched and are suitable as word lines W. Parts of the word lines W are suitable as fifth gate electrodes Ga 5  of the fifth transistors and as sixth gate electrodes of the sixth transistors. 
     To that end, the thirteenth mask M 13  in the memory cells respectively does not cover regions: wherein the fifteenth horizontal region O through the seventh horizontal region q overlap with the first vertical region  1  and the second vertical region  2 ; wherein the fifteenth horizontal region O through the seventh horizontal region q overlap with the twelfth vertical region  12  and the thirteenth vertical region  13 ; wherein the first horizontal region a through the seventh horizontal region g overlap with the first vertical region  1  and the second vertical region  2 ; wherein the first horizontal region a through the fourth horizontal region d overlap with the third vertical region  3  through the sixth vertical region  6 ; and wherein the first horizontal region a through the seventh horizontal region g overlap with the twelfth vertical region  12  and the thirteenth vertical region  13 . 
     With the assistance of a fourteenth mask M 14  of photoresist (see FIG. 7 g ), first horizontal, conductive structures H 1 , second horizontal, conductive structures H 2 , third horizontal, conductive structures, fourth horizontal, conductive structures H 4  and fifth horizontal, conductive structures H 5  arise from the structured, conductive layer SI (see FIGS. 4,  6   b ,  6   d ), C 2 F 6 +O 2 , for example, is suitable as etchant. 
     To that end, the fourteenth mask M 14  covers regions: wherein the eighteenth horizontal region r through the twenty-first horizontal region v overlap with the first vertical region  1  through the sixth vertical region  6 ; wherein the twelfth horizontal region I through the fourteenth horizontal region n overlap with the first vertical region  1  through the fourth vertical region  4 ; wherein the eighteenth horizontal region through the twenty-first horizontal region v overlap with the eleventh vertical region  11  through the thirteenth vertical region  13 ; wherein the twelfth horizontal region I through the fourteenth horizontal region n overlap with the eleventh vertical region  11  through the thirteenth vertical region  13 ; and wherein the fifth horizontal region e through the eighth horizontal region h overlap with the fourth vertical region  4  through the sixth vertical region  6 . The first horizontal, conductive structures H 1  adjoin the first gate electrodes Gal of the third transistors at the third conductive structures L 3 . The second horizontal conductive structures H 2  adjoin the second gate electrodes Ga 2  of the second transistors. The third horizontal conductive structures adjoin the third gate electrode Ga 3  of the third transistors. The fourth horizontal conductive structures H 4  adjoin the fourth gate electrodes Ga 4  of the fourth transistors. The fifth horizontal conductive structures H 5  adjoin the third conductive structures L 3 . 
     Subsequently, SiO 2  is deposited in a thickness of approximately 600 nm in a TEOS process. By chemical-mechanical polishing, 500 nm SiO 2  is eroded and planarized, wherein a third insulating structure  13  arising (see FIG.  5 ). 
     After generation of second contacts K 2  that contact the second source/drain regions  1  S/D 2  of the first transistors, of fourth contacts that contact the first source/drain regions  3  S/D 1  of the third transistors, of fifth contacts K 2  that contact the second source/drain regions  2  S/D 2  of the second transistors and of sixth contacts that contact the first source/drain regions  4  S/D 1  of the fourth transistors, SiO 2  is selectively etched relative to silicon with the assistance of a fifteenth mask (not shown) of photoresist until parts of the source/drain regions are uncovered. CHF 3 +O 2 , for example, is suitable as etchant. 
     To that end, the fifteenth mask in the memory cells respectively does not cover regions: wherein the thirteenth horizontal region M through the fifteenth horizontal region  0  overlap with the second vertical region  2  through the fourth vertical region  4 ; wherein the fifth horizontal region e through the eighth horizontal region h overlap the third vertical region  3  through the fifth vertical region  5 ; wherein the thirteenth horizontal region m through the fifteenth horizontal region O overlap with the twelfth vertical region  12 ; and wherein the third horizontal region c through the sixth horizontal region f overlap with the twelfth vertical region  12 . 
     Subsequently, tungsten is deposited in a thickness of approximately 200 nm. As a result, the second contacts K 2 , the fourth contacts K 4 , the fifth contacts K 5  and the sixth contacts arise (see FIGS. 5,  6   b ). Tungsten is etched with the assistance of a sixteenth mask M 16  of photoresist (see FIG. 7 h ). As a result whereof, fifth conductive structures L 5  and sixth conductive structures L 6  arise (see FIGS. 5,  6   b ). SF 6 , for example, is suitable as etchant. The fifth conductive structures L 5  respectively adjoin a second contact K 2  and a fourth contact K 4 . The sixth conductive structures L 6  respectively adjoin a fifth contact K 5  and a&#39;sixth contact. 
     To that end, the sixteenth mask M 16  in the memory cells respectively covers a first U-shaped region and a second U-shaped region. The first U 25  shaped region is composed of regions: wherein the thirteenth horizontal region m through the seventeenth horizontal region q overlap with the second vertical region  2  through the fourth vertical region  4 ; wherein the fifteenth horizontal region o through the seventeenth horizontal region q overlap with the fifth vertical region  5  through the eleventh vertical region  11 ; and wherein the thirteenth horizontal region m up through the seventeenth horizontal region q overlap with the twelfth vertical region  12 . The second U-shaped region is composed of regions: wherein the fourth horizontal d through the ninth horizontal region i overlap with the third vertical region  3  through the fifth vertical region  5 ; wherein the seventh horizontal region g through the ninth horizontal region i overlap with the sixth vertical region  6  through the eleventh vertical region  11 ; and wherein the third horizontal region c through the ninth horizontal region i overlap with the twelfth vertical region  12 . 
     Borophosphorous glass is deposited in a thickness of approximately 600 nm. The borophosphorous glass is planarized with the assistance of chemical-mechanical polishing. As a result, a fourth insulating structure  14  arises (see FIG. 6 a ). For producing first contacts K 1  that contact the second source/drain regions  1  S/D 2  of the first transistors, for producing third contacts that contact the first source/drain regions  3  S/D 1  of the third transistors for producing seventh contacts K 7  that contact the second source/drain regions  5  S/D 2  of the fifth transistors, and for producing eighth contacts that contact the second source/drain regions  6  S/D 2  of the sixth transistors, borophosphorous glass is etched selectively relative to silicon with the assistance of a seventeenth mask (not shown) of photoresist until parts of the source/drain regions are uncovered. C 2 F 6 +O 2 , for example, is suitable as etchant. 
     To that end, the seventeenth mask in the memory cells respectively does not cover regions: wherein the nineteenth horizontal region s through the twenty-first horizontal region u overlap with the second vertical region  2  through the fourth vertical region  4 ; wherein the nineteenth horizontal region s through the twenty-first horizontal region u overlap with the twelfth vertical region  12 ; wherein the eleventh horizontal region k through the thirteenth horizontal region m overlap with the ninth vertical region  9 ; and wherein the second horizontal region b through the fifth horizontal region e overlap with the ninth vertical region  9 . Subsequently, tungsten is deposited in a thickness of approximately 300 nm and is etched back. As a result, the first contacts K 1 , the third contacts, the seventh contacts K 7  and the eighth contacts arise (see FIGS. 6 b,    6   d ). 
     Subsequently, AlSiCu is deposited in a thickness of approximately 500 nm and is structured with an eighteenth mask M 18  of photoresist (see FIG. 7 i ) on the basis of an etching step. BCl 3 +Cl 2 +N 2 +CH 4 , for example, is suitable as etchant. As a result thereof, fourth conductor structures L 4 , first bit lines B 1  and second bit lines B 2  (see FIGS. 6 a ,  6   b ,  6   d ) arise. In a memory cell, a fourth conductor structure L 4  adjoins a first contact K 1  and a third contact. The first bit lines B 1  are stripe-shaped and proceed perpendicularly to the first trenches G 1  and adjoin the seventh contacts K 7 . The second bit lines B 2  are substantially stripe-shaped and proceed parallel to the first bit lines B 1  and adjoin the eighth contacts. 
     To that end, the eighteenth mask M 18  in the memory cells respectively cover regions: wherein the seventeenth horizontal region q through the twenty-first horizontal region u overlap with the second vertical region  2  through the fourth vertical region  4 , and regions wherein the seventeenth horizontal q through the nineteenth horizontal region s overlap with the fifth vertical region  5  through the eleventh vertical region  11 ; and wherein the seventeenth horizontal region q through the twenty-first horizontal region u overlap with the twelfth region  12 ; the eleventh horizontal region k, the twelfth horizontal region  1 , the thirteenth horizontal region m, the fourth horizontal region d, the fifth horizontal region e, the sixth horizontal region f, the seventh horizontal region g and regions wherein the second horizontal region b and the third horizontal region c overlap with the nineteenth vertical region  9 . 
     Many modifications of the exemplary embodiment are conceivable which still would lie within the scope of the present invention. In particular, the dimensions of the described layers, regions, areas and trenches can be adapted to the respective requirements. The same is also true of the proposed dopant concentrations. Structures and layers of SiO 2  can, in particular, be produced by thermal oxidation or by a deposition process. Polysilicon can be doped both during as well as following the deposition. Instead of doped polysilicon, metal silicides and/or metals, for example, can be employed. Instead of eroding deposited SiO 2  by chemical-mechanical polishing, re-etching also can be employed. The same considerations are also true for the generation of the conductive structure. 
     In sum, although the present invention has been described with reference to specific embodiments, those of skill in the art will recognize that changes may be made thereto without departing from the spirit and scope of the invention as set forth in the hereafter appended claims.