Abstract:
A circuit and method for an improved inverter is provided. The present invention capitalizes on a switched source impedance to prevent subthreshold leakage current at standby in low voltage CMOS circuits. The switched source impedance is provided by body contacted and backgated transistors. The gate and body of the transistors are biased to modify the threshold voltage of the transistors (V t ). This design provides fast switching capability for low power battery operated CMOS circuits and systems. The transistor structures offer the performance advantages from both metal-oxide semiconductor (MOS) and bipolar junction transistor (BJT) designs. The devices can be used in a variety of applications, digital and analog, wherever a more compact structure with low power consumption and fast response time is needed.

Description:
RELATED APPLICATIONS 
     This application is related to the co-filed Mar. 30, 1998 and commonly assigned application, U.S. patent application Ser. No. 09/050,281 attorney docket number 303.476US1, entitled “Circuits and Methods For Dual-Gated Transistors” and U.S. patent application Ser. No. 09/050,728 attorney docket number 303.498us1, entitled “Another Technique for Gated Lateral Bipolar Transistors” which are hereby incorporated by reference. 
    
    
     FIELD OF THE INVENTION 
     The present invention relates generally to semiconductor integrated circuits. More particularly, it pertains to circuits and methods for body contacted and backgated transistors. 
     BACKGROUND OF THE INVENTION 
     Integrated circuit technology relies on transistors to formulate vast arrays of functional circuits. The complexity of these circuits requires the use of an ever increasing number of linked transistors. As the number of transistors required increases, the surface area that can be dedicated to a single transistor dwindles. It is desirable then, to construct transistors which occupy less surface area on the silicon chip/die. 
     Integrated circuit technology uses transistors conjunctively with Boolean algebra to create a myriad of functional digital circuits, also referred to as logic circuits. In a typical arrangement, transistors are combined to switch or alternate an output voltage between just two significant voltage levels, labeled logic 0 and logic 1. Most logic systems use positive logic, in which logic 0 is represented by zero volts, or a low voltage, e.g., below 0.5 V; and logic 1 is represented by a higher voltage. 
     One method in which these results are achieved involves Complementary Metal-Oxide Semiconductor (CMOS) technology. CMOS technology comprises a combination of oppositely doped Metal-Oxide Semiconductor Field-Effect Transistors (MOSFETs) to achieve the switching mechanism between voltage levels associated with logic 0 and that of logic 1. This configuration is likewise referred to as an inverter. Conventional CMOS inverters consume an appreciable amount of chip surface area, even despite ongoing reductions in the critical dimensions that are achievable with conventional photolithography techniques. The critical dimension (F) represents the minimum lithographic feature size that is imposed by lithographic processes used during fabrication. It is one objective, then, to fabricate CMOS inverters which conserve silicon chip surface space 
     Standby current is another significant concern and problem in low voltage and low power battery operated CMOS circuits and systems. High threshold voltage transistors and high power supply voltages were traditionally employed in part to minimize subthreshold leakage at standby. Today, however, low voltages are desired for low power operation and this creates a problem with threshold voltages and standby leakage current. In order to get significant overdrive and reasonable switching speeds the threshold voltage (V t ) magnitudes must be small, e.g. zero volts. However, having such low threshold voltages generally causes one of the transistors to have a large subthreshold leakage current. Various techniques have been employed to allow low voltage operation with CMOS transistors and maintain low subthreshold leakage currents at standby. 
     Dynamic CMOS circuits achieve this objective using clock or phase voltages to turn off conduction from the power supply to ground through the chain of devices when the inverter is at standby. Synchronous body bias has similarly been employed in part to minimize subthreshold leakage. However, synchronous body bias, like dynamic logic, requires extra clock or phase voltage lines throughout the circuit. This increases considerably the complexity of circuits and consumes precious space on the chip. Also, data stored only on a dynamic basis must be clocked and refreshed. 
     Another way to get around these problems involves implementing resistors to provide a source to substrate bias or backgate bias when the transistor is in the off state or, in other words, to create a “switched source impedance.” The problem with this method is that resistors are troublesome to fabricate in CMOS process steps. 
     For the reasons stated above, and for other reasons stated below which will become apparent to those skilled in the art upon reading and understanding the present specification, there is a need to develop improved inverter devices. The devices should desirably minimize subthreshold leakage current and conserve chip surface space while continuing to advance the operation speeds in logic circuits. The improved inverter circuits and structures should remain fully integral with CMOS processing techniques. 
     SUMMARY OF THE INVENTION 
     The above mentioned problems with memory devices and other problems are addressed by the present invention and will be understood by reading and studying the following specification. A circuit and method is provided to minimize subthreshold leakage currents at standby in low power CMOS circuits and systems. 
     In particular, an illustrative embodiment of the present invention includes an inverter. The inverter includes a first, second, third, and fourth transistor. Each of the transistors extends outwardly from a semiconductor substrate. Each of the four transistors has an upper surface and opposing sidewall surfaces. Each of the transistors includes a source/emitter region, a body/base region, and a collector/drain region. An electrical contact couples between the collector/drain regions of the second and third transistors to provide an output for the inverter. A gate contact interconnects the four transistors and provides an input to the inverter. 
     In another embodiment, a logic circuit is provided. The logic circuit includes multiple inverters that form an array. Each of the inverters includes a first, second, third, and fourth transistor. Each of the four transistors has an upper surface and opposing sidewall surfaces. Each of the transistors include a source/emitter region, a body/base region, and a collector/drain region. An electrical contact couples between the collector/drain regions of the second and third transistors to provide an output for the inverter. A gate contact connects the four transistors and provides an input to the inverter. A metallization layer selectively interconnects the inputs and outputs of the inverters to implement a logic function. The logic circuit accepts inputs and produces one or more logical outputs. 
     In another embodiment, an input/output device is provided. The input/output device includes a functional circuit that has a plurality of components. A logic device is coupled to the functional circuit. The logic device has a number of inverters and each inverter has a first, second, third, and fourth transistor. Each of the transistors extends outwardly from a semiconductor substrate. Each of the four transistors has an upper surface and opposing sidewall surfaces. Each of the transistors includes a source/emitter region, a body/base region, and a collector/drain region. An electrical contact couples between the collector/drain regions of the second and third transistors to provide an output for the inverter. A gate contact connects the four transistors and provides an input to the inverter. A metallization layer is also provided that selectively interconnects the inputs and outputs of the inverters to form a logic circuit that accepts inputs and produces one or more logical outputs. 
     In another embodiment, a method of fabricating an inverter is provided. The method includes forming a first, second, third, and fourth transistor. The four transistors are formed to extend outwardly from a semiconductor substrate. The transistors are each formed with an upper surface and opposing sidewall surfaces. The transistors are formed to include a source/emitter region, a body/base region, and a collector/drain region. An electrical contact is formed between collector/drain regions of the second and third transistors to provide an output for the inverter. A gate contact is formed which interconnects the transistors. The gate contact provides an input to the inverter. 
     In another embodiment, a method of fabricating an array of inverters is provided. The method includes forming multiple inverters such that each of the inverters is formed as described above. A metallization layer is formed that selectively interconnects the inputs and outputs of the inverters to form a logic circuit. The logic circuit accepts inputs and produces one or more logical outputs. 
     Thus, an improved circuit and method is provided. The transistors combine BJT and MOS transistor conduction. The new circuit and method allows for low voltage level operation and enhanced switching action over conventional bipolar complementary metal-oxide semiconductor (BiCMOS) devices. The new circuit and method additionally minimizes the subthreshold leakage current at standby. The transistor structure and circuit are fully compatible with CMOS technology. Thus, the transistor structures do not require additional chip surface space, nor additional processing steps. 
     These and other embodiments, aspects, advantages, and features of the present invention will be set forth in part in the description which follows, and in part will become apparent to those skilled in the art by reference to the following description of the invention and referenced drawings or by practice of the invention. The aspects, advantages, and features of the invention are realized and attained by means of the instrumentalities, procedures, and combinations particularly pointed out in the appended claims. 
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS 
     FIG. 1A is a perspective view illustrating an inverter according to the teachings of the present invention. 
     FIG. 1B is a perspective view intended to provide an illustrative example of an individual NMOS transistor as employed in the inverter of FIG.  1 A. 
     FIG. 1C is a top view of the transistor shown in FIG.  1 B. 
     FIG. 1D is a cross-sectional view taken along cut line  1 D— 1 D of FIG.  1 C. 
     FIG. 1E is a perspective intended to provide an illustrative example of an individual PMOS transistor as employed in the inverter of FIG.  1 A. 
     FIG. 1F is a top view of the transistor shown in FIG.  1 E. 
     FIG. 1G is a cross-sectional view of the transistor shown in FIG. 1F, taken along cut line  1 G— 1 G. 
     FIG. 1H is a cross-sectional view taken along cut line  1 H— 1 H of FIG.  1 A. 
     FIG. 1I is a schematic diagram of an inverter according to the teachings of the present invention. 
     FIG. 2 is a schematic diagram illustrating an inverter array included as part of a logic circuit according to the teachings of the present invention. 
     FIG. 3 is a block diagram illustrating a functional circuit according to the teachings of the present invention. 
     FIGS. 4A-4M illustrate an embodiment of a process of fabrication of an inverter according to the teachings of the present invention, current sense amplifier. 
    
    
     DETAILED DESCRIPTION 
     In the following detailed description of the invention, reference is made to the accompanying drawings which form a part hereof, and in which is shown, by way of illustration, specific embodiments in which the invention may be practiced. In the drawings, like numerals describe substantially similar components throughout the several views. These embodiments are described in sufficient detail to enable those skilled in the art to practice the invention. Other embodiments may be utilized and structural, logical, and electrical changes may be made without departing from the scope of the present invention. 
     The terms wafer and substrate used in the following description include any structure having an exposed surface with which to form the integrated circuit (IC) structure of the invention. The term substrate is understood to include semiconductor wafers. The term substrate is also used to refer to semiconductor structures during processing, and may include other layers that have been fabricated thereupon. Both wafer and substrate include doped and undoped semiconductors, epitaxial semiconductor layers supported by a base semiconductor or insulator, as well as other semiconductor structures well known to one skilled in the art. The term conductor is understood to include semiconductors, and the term insulator is defined to include any material that is less electrically conductive than the materials referred to as conductors. The following detailed description is, therefore, not to be taken in a limiting sense, and the scope of the present invention is defined only by the appended claims, along with the full scope of equivalents to which such claims are entitled. 
     The term “horizontal” as used in this application is defined as a plane parallel to the conventional plane or surface of a wafer or substrate, regardless of the orientation of the wafer or substrate. The term “vertical” refers to a direction perpendicular to the horizonal as defined above. Prepositions, such as “on”, “side” (as in “sidewall”), “higher”, “lower”, “over” and “under” are defined with respect to the conventional plane or surface being on the top surface of the wafer or substrate, regardless of the orientation of the wafer or substrate. 
     Throughout this specification the designation “n+” refers to semiconductor material that is heavily doped n-type semiconductor material, e.g., monocrystalline silicon or polycrystalline silicon. Similarly, the designation “p+” refers to semiconductor material that is heavily doped p-type semiconductor material. The designations “n−” and “p−” refer to lightly doped n and p-type semiconductor materials, respectively. 
     Inverter Embodiment 
     FIG. 1A is a perspective view illustrating generally an embodiment of an inverter according to the teachings of the present invention. The inverter  50  is a four transistor device that is formed using, for example, the technique described below with respect to FIGS. 4A through 4M. The transistors which make up the inverter  50  are formed of single crystalline semiconductor material  108 . Each transistor in inverter  50  is either an n-channel metal-oxide semiconductor (NMOS) or a p-channel metal-oxide semiconductor (PMOS). The inverter  50  includes two NMOS transistors, Q 2  and Q 4  respectively. The NMOS transistors, Q 2  and Q 4 , are coupled to one another. Also, the inverter  50  includes two PMOS transistors, Q 1  and Q 3  respectively. The PMOS transistors, Q 1  and Q 3 , are likewise coupled to one another. In the exemplary embodiment, NMOS transistors Q 2  and Q 4  possess different doping profiles such that transistor Q 2  has a higher threshold voltage (V t ) than transistor Q 4 . PMOS transistors Q 1  and Q 3  possess different doping profiles such that transistor Q 1  has a higher threshold voltage (V t ) than transistor Q 3 . NMOS transistors, Q 2  and Q 4 , include gates  159 A and  159 B respectively. PMOS transistors, Q 1  and Q 3 , include gates  158 A and  158 B respectively. In one embodiment, the NMOS gates,  159 A and  159 B, are formed of n+ silicon material and the PMOS gates,  158 A and  158 B, are formed of p+ silicon material. NMOS transistors, Q 2  and Q 4 , include body contacts  164 A and  164 B respectively. PMOS transistors, Q 1  and Q 3 , include body contacts  163 A and  163 B respectively. In one embodiment, the NMOS body contacts,  164 A and  164 B, are formed of p+ silicon material and the PMOS body contacts,  163 A and  163 B, are formed of n+ silicon material. The body contacts,  164 B and  163 B, of transistors Q 4  and Q 3  couple to external potential values. Inverter  50  also includes a gate contact  157  which couples to all of the gates,  159 A,  159 B,  158 A, and  158 B, of the NMOS and PMOS transistors. Inverter  50  includes an electrical contact  165  which couples to transistors Q 4  and Q 3  and provides an output to the inverter  50 . In one embodiment, inverter  50  is formed on an insulator layer  190  formed on a substrate  105  of p− silicon material. In one embodiment, gate contact  157  further couples to the body contacts,  164 A and  163 A, of transistors Q 2  and Q 1 . 
     FIG. 1B is a perspective view intended to provide an illustrative example of an individual NMOS transistor  100  as employed in the inverter  50  of FIG.  1 A. The NMOS transistor  100  represents either transistor Q 2  or Q 4  in inverter  50  depending on the NMOS transistor&#39;s doping profile. The NMOS transistor  100  includes a body region  110  formed of single crystalline semiconductor material that extends outwardly from a substrate  105 . In one embodiment, the body region  110  is formed on an insulator layer  190  formed on a substrate  105  formed of p− silicon material. The body region  110  has an upper surface  170  and opposing sidewall surfaces  180 . In one embodiment, the NMOS body region  110  is formed of a p− silicon material. A source/emitter region  115 A is formed within the upper surface  170  and the opposing sidewall surfaces  180  of the body region  110  of the NMOS transistor  100 . Similarly, a collector/drain region  115 B (FIG. 1C) is formed within the upper surface  170  and the opposing sidewall surfaces  180  of the body region  110  of the NMOS transistor  100 . A doped glass layer  125  encases both the source/emitter region  115 A and the collector/drain region  115 B for the transistor. In one embodiment the doped glass layer  125  is Arsenic silicate glass (ASG), and in another embodiment, the doped glass layer is phosphorus silicate glass (PSG). A thin nitride layer  140  encases the doped glass layer  125  over the source/emitter region  115 A and the collector/drain region  115 B. The NMOS transistor  100  further includes a gate oxide layer  130  located on a first one of the opposing sidewalls  180 . A gate  160  is formed on the gate oxide  130  on the first one of the opposing sidewalls  180 . Gate  160  correlates to either gate  159 A or  159 B of FIG. 1A depending on the gate&#39;s  160  doping profile. A body contact  161  is located on the other of the opposing sidewall surfaces  180 . Body contact  161  correlates to either body contact  164 A or  164 B of FIG. 1A depending on the body contact&#39;s  161  doping profile. 
     FIG. 1C is a top view of the transistor shown in FIG. 1B with the nitride layer  140  and the doped glass layer  125  cut away for illustrative purposes. FIG. 1C illustrates the source/emitter region  115 A and the collector/drain region  115 B. FIG. 1C also illustrates the gate oxide  130  located on a first one of the opposing sidewall surfaces  180 , and further, the gate  160  formed on the gate oxide  130 . The body contact  161  is shown coupling directly to the other one of the opposing sidewall surfaces  180 . 
     FIG. 1D is a cross-sectional view taken along cut line  1 D— 1 D of FIG.  1 C. This cross-sectional view provides another illustration of the gate  160  formed on the gate oxide  130  on one of the opposing sidewall surfaces  180 . The view likewise shows the body contact  161  coupling directly to the body region  110  through the other opposing sidewall  180 . In one embodiment, the gate  160  and the body contact  161  are biased independently from one another. In an alternative embodiment, the gate  160  and the body contact  161  are coupled to a single source potential. 
     FIG. 1E is a perspective intended to provide an illustrative example of an individual PMOS transistor  101  as employed in the inverter  50  of FIG.  1 A. The PMOS transistor  101  represents either transistor Q 1  or Q 3  in inverter  50  depending on the PMOS transistor&#39;s  101  doping profile. The PMOS transistor  101  includes a body region  111  formed of single crystalline semiconductor material that extends outwardly from a substrate  105 . In one embodiment, the body region  111  is formed on an insulator layer  190 . Insulator layer  190  is formed on a substrate  105 . Substrate  105  comprises, for example, p− silicon material. The body region  111  has an upper surface  170  and opposing sidewall surfaces  180 . In one embodiment, the PMOS body region  111  is formed of an n− silicon material. A source/emitter region  116 A is formed within the upper surface  170  and the opposing sidewall surfaces  180  of the body region  111  of the PMOS transistor  101 . Similarly, a collector/drain region  116 B (not shown) is formed within the upper surface  170  and the opposing sidewall surfaces  180  of the body region  111  of the PMOS transistor  101 . A doped glass layer  126  encases both the source/emitter region  116 A and the collector/drain region  116 B for the transistor. In one embodiment the doped glass layer  126  is borosilicate glass (BSG). The PMOS transistor  101  further includes a gate oxide layer  130  located on a first one of the opposing sidewalls  180 . A gate  166  is formed on the gate oxide  130  on the first one of the opposing sidewalls  180 . Gate  166  correlates to either gate  158 A or  158 B of FIG. 1A depending on the gate&#39;s  166  doping profile. A body contact  167  is located on the other of the opposing sidewall surfaces  180 . Body contact  167  correlates to either body contact  163 A or  163 B of FIG. 1A depending on the body contact&#39;s  167  doping profile. 
     FIG. 1F is a top view of the transistor shown in FIG. 1E with the doped glass layer  126  cut away for illustrative purposes. FIG. 1F illustrates the source/emitter region  116 A and the collector/drain region  116 B. FIG. 1F also illustrates the gate oxide  130  located on a first one of the opposing sidewall surfaces  180 , and further, the gate  166  formed on the gate oxide  130 . The body contact  167  is shown coupling directly to the other one of the opposing sidewall surfaces  180 . 
     FIG. 1G is a cross-sectional view taken along cut line  1 G— 1 G of FIG.  1 F. This cross-sectional view provides another illustration of the gate  166  formed on the gate oxide  130  on one of the opposing sidewall surfaces  180 . The view likewise shows the body contact  167  coupling directly to the body region  111  through the other opposing sidewall  180 . In one embodiment, the gate  166  and the body contact  167  are biased independently from one another. In an alternative embodiment, the gate  166  and the body contact  167  are coupled to a single source potential. 
     FIG. 1H is a cross-sectional view taken along cut line  1 H— 1 H of FIG.  1 A. FIG. 1H illustrates all four transistors, Q 2 , Q 4 , Q 3 , and Q 1 , coupled together via gate contact  157 . FIG. 1H illustrates more clearly the gates,  159 A and  159 B respectively, coupling to the gate oxides  130  on one of the opposing sidewall surfaces  180 . FIG. 1H shows that the gates,  159 A and  159 B respectively, of transistors Q 2  and Q 4  are both separated from coupling to the source/emitter regions  115 A and the collector/drain regions  115 B by a nitride layer  140  and by doped glass layers  125 . Similarly, FIG. 1H illustrates more clearly that the body contacts,  164 A and  164 B respectively, couple directly to the body regions  110  on the other of the opposing sidewall surfaces  180 . FIG. 1H shows that the body contacts,  164 A and  164 B respectively, of transistors Q 2  and Q 4  are also both separated from coupling to the source/emitter regions  115 A and the collector/drain regions  115 B by a nitride layer  140  and by doped glass layers  125 . 
     FIG. 1H illustrates a similar arrangement for the PMOS transistors, Q 1  and Q 3  respectively. FIG. 1H shows more clearly the gates,  158 A and  158 B respectively, coupling to the gate oxides  130  on one of the opposing sidewall surfaces  180 . FIG. 1H shows that the gates,  158 A and  158 B respectively, of transistors Q 1  and Q 3 , are both separated from coupling to the source/emitter regions  116 A and the collector/drain regions  116 B by doped glass layers  126 . Similarly, FIG. 1H illustrates more clearly that the body contacts,  163 A and  163 B respectively, couple directly to the body regions  111  on the other of the opposing sidewall surfaces  180 . FIG. 1H shows that the body contacts,  163 A and  163 B respectively, of transistors Q 1  and Q 3  are also separated from coupling to the source/emitter regions  116 A and the collector/drain regions  116 B by the doped glass layers  126 . 
     FIG. 1I is a schematic diagram of an inverter  50  according to the teachings of the present invention. The operation of the embodiment of FIG. 1A is described in connection with the schematic diagram of FIG.  1 I. In operation, inverter  50  receives a “high” or “low” voltage input corresponding to a logic “1” or logic “0”, which is carried by the gate contact  157  to all of the gates,  159 A,  159 B,  158 B, and  158 A respectively. The operation of any of the transistors, Q 2 , Q 4 , Q 3 , or Q 1  respectively, is given by the application of this potential to those gates. A potential value is simultaneously applied to the body contacts,  164 A,  164 B,  163 B and  163 A respectively, of the inverter  50 . Conduction then occurs between the source/emitter region,  115 A or  116 A, and the collector/drain region,  115 B or  116 B, of the responsive transistors. 
     At low values of potential applied to the gates, e.g., close to the threshold potential (V t ), the responsive transistors, amongst Q 2 , Q 4 , Q 3 , or Q 1 , exhibit metal-oxide semiconductor (MOS) conduction action and the majority of this conduction occurs in the inversion region adjacent to the gates of the responsive transistors. In this instance, applying a potential to the body contacts serves primarily to change the threshold voltage of the MOS conduction action. For greater potentials applied to the gates, e.g., larger than V t , the responsive transistors, amongst Q 2 , Q 4 , Q 3 , or Q 1 , exhibit distinct bipolar junction transistor (BJT) conduction action in addition to the MOS conduction action. For even higher potentials applied to the gates, e.g., much greater than V t , the BJT conduction action dominates. 
     In the exemplary embodiment, the body contacts  164 A and  163 A of transistors Q 2  and Q 1  couple to the gate contact  157  or to the transistors respective gates  159 A and  158 A. Additionally, these transistors possess a higher threshold voltage level (V t ) than do transistors Q 4  and Q 3 . When off, transistors Q 2  and Q 1  provide a high impedance in the source/emitter regions  115 A and  116 A of transistors Q 4  and Q 3 . This high impedance is also termed a “switched source impedance.” When the gate-body connected transistors Q 2  and Q 1  are turned on their threshold voltage (V t ) magnitude decreases and they can in fact become depletion mode devices with a large excess in the magnitude of gate voltage over V t . In this state the gate-body connected transistors Q 2  and Q 1  have a very low on state resistance and there is only a small degradation in the switching speed of the inverter due to the additional resistance and capacitive load. These circuits do not require extra phase or clock voltages and lines in the cell as synchronous body bias methods and circuits do. 
     FIG. 2 is a schematic diagram illustrating, by way of example and not by way of limitation, an inverter array  201  included as part of a logic circuit  200  according to the teachings of the present invention. Inverter array  201  contains multiple inverters exemplified by inverter  50 . Each transistor, Q 2 , Q 4 , Q 3 , or Q 1  respectively, in inverter  50  has a selected doping profile to achieve a desired threshold voltage. Each transistor in inverter  50  is either an n-channel metal-oxide semiconductor (NMOS) or a p-channel metal-oxide semiconductor (PMOS). The inverter  50  includes two NMOS transistors, Q 2  and Q 4  respectively. The NMOS transistors, Q 2  and Q 4 , are coupled to one another. Also, the inverter  50  includes two PMOS transistors, Q 1  and Q 3  respectively. The PMOS transistors, Q 1  and Q 3 , are likewise coupled to one another. In the exemplary embodiment, NMOS transistors Q 2  and Q 4  possess different doping profiles such that transistor Q 2  has a higher threshold voltage (V t ) than transistor Q 4 . PMOS transistors Q 1  and Q 3  possess different doping profiles such that transistor Q 1  has a higher threshold voltage (V t ) than transistor Q 3 . NMOS transistors, Q 2  and Q 4 , include gates  259 A and  259 B respectively. PMOS transistors, Q 1  and Q 3 , include gates  258 A and  258 B respectively. NMOS transistors, Q 2  and Q 4 , include body contacts  264 A and  264 B respectively. PMOS transistors, Q 1  and Q 3 , include body contacts  263 A and  263 B respectively. The body contacts,  264 B and  263 B, of transistors Q 4  and Q 3  couple to external potential values. Inverter  50  also includes a gate contact  257  which couples to all of the gates,  259 A,  259 B,  258 A, and  258 B respectively, of the NMOS and PMOS transistors. Inverter  50  includes an electrical contact  265  which couples to transistors Q 4  and Q 3  and provides an output to the inverter  50 . In one embodiment, gate contact  257  further couples to the body contacts,  264 A and  263 A, of transistors Q 2  and Q 1 . 
     In one embodiment, the gate contacts  257  and electrical contacts  265  of selected inverters  50  can be interconnected. The selected interconnection is made through a patterned metallization layer  205  which is coupled to inputs and outputs of selected inverters. The order of interconnection of the inverters will determine the output of logic circuit  200 . The metallization layer  205  can be configured to interconnect other transistors such as to perform basic boolean logic functions such as AND, OR and NOT functions. By order of arrangement, the basic boolean logic functions can be combined such that the combination of these transistors and inverter circuit  200  yields desired logic functions. 
     FIG. 3 is a block diagram illustrating a functional circuit  340  according to the teachings of the present invention. FIG. 3 illustrates the use of an inverter in a logic array  320  in a functional circuit  340 . The individual inverters within the logic array  320  are selectively interconnected. The selected interconnection is made through a patternized metallization layer  300  which is coupled to inputs and outputs of selected individual inverters. The selected interconnection of individual inverters in the inverter array  320  through the metallization layer  300  forms logic circuit/device  310 . The logic circuit/device  310  is electrically interconnected to other functional circuit device/components  350 . These other functional circuit devices/components include memory controllers, microprocessors and input/output bus units. 
     Method of Fabrication for the Embodiment 
     FIGS. 4A through 4M illustrate an embodiment of the various processing steps for fabricating a inverter formed from a complementary pair of body contacted and backgated transistors. FIG. 4A begins with a lightly doped p− silicon substrate  400 . A thin screen oxide layer  402  is thermally grown. The oxide layer  402  is formed to a thickness of approximately 10 nanometers (nm). A photoresist is applied and selectively exposed to reveal p-channel metal-oxide semiconductor (PMOS) device regions  405 . Wells of n-type silicon material are formed in the substrate  400  to form the PMOS device regions  405 . The n-wells  410  of n-type material can be formed by any suitable method, such as by ion implantation. The n-wells  410  are formed to a depth of approximately 1.0 micrometer (μm). The photoresist is removed using conventional photoresist stripping techniques. The structure is then annealed, such as by a rapid thermal anneal (RTA) process, to achieve the desired doping profile. The structure is now as it appears in FIG.  4 A. 
     FIG. 4B illustrates the structure after the next sequence of processing steps. A silicon nitride (Si 3 N 4 ) pad layer  411  is deposited on the upper surface  404  of the substrate  400  and the n-wells  410 . The nitride layer  411  is formed by any suitable means, such as by chemical vapor deposition (CVD). The nitride layer  411  is formed to a thickness of approximately 0.4 μm. A photoresist is applied and selectively exposed to mask stripes which define active device region, including both n-channel metal-oxide semiconductor (NMOS) device region  407  and PMOS device regions  405 . The nitride layer  411  in between device regions,  405  and  407 , is removed. The nitride layer  411  is removed by any suitable etching technique, such as by RIE. The exposed n-well  410  and the p− substrate material  400  are etched to a depth of approximately 0.2 μm below the bottom of the n-well  410 /substrate  400  interface. These etching steps leave trenches  414  between the device regions  407  and  405 . The etching is performed though any suitable process, such as by RIE. The structure is now as shown in FIG.  4 B. The photoresist is next stripped, using conventional photoresist stripping techniques. 
     FIG. 4C illustrates the structure after the next series of processing steps. An insulator layer  415  is formed beneath the device regions,  405  and  407  respectively so as to form a semiconductor on insulator (SOI) structure. The insulator layer  415  is formed using, for example, the techniques of U.S. application Ser. No. 08/745,708, entitled Silicon-On-Insulator Islands and Method for Their Formation (the &#39;708 Application), or U.S. Pat. No. 5,691,230, entitled Technique for Producing Small Islands of Silicon on Insulator (the &#39;230 Patent). The &#39;708 Application and the &#39;230 Patent are incorporated by reference. The insulator layer  415  separates from substrate  400  the p− single crystalline silicon structure  412  of the NMOS device region  407 , and the single crystalline silicon structure n-well  410  of the PMOS device region  405 . Any of the nitride layer  411  left on the device regions,  405  and  407  is removed by etching. The etching process may be achieved either by using a selective wet etch or using reactive ion etching (RIE). The structure is now as illustrated in FIG.  4 C. 
     FIG. 4D illustrates the structure following the next series of processing steps. A thin oxide layer  420  is thermally grown on active device regions,  405  and  407 . The oxide layer  420  is grown to a thickness of approximately 20 nanometers (nm). A thin silicon nitride (Si 3 N 4 ) layer  425  is deposited over the entire surface by CVD. The nitride layer  425  is deposited to a thickness of approximately 50 nm. Intrinsic polysilicon  430  is deposited by any suitable methods, such as by CVD, to fill the trenches  414 . Next, the trenches  414  are planarized stopping on the nitride pads  425 . The intrinsic polysilicon  430  in trenches  414  can be planarized by any suitable process, such as by chemical mechanical polishing/planarization (CMP). The intrinsic polysilicon  430  is selectively etched back, such as by RIE, to leave only a thin layer on the bottom of trenches  414 . The structure is now as is shown in FIG.  4 D. 
     FIG. 4E shows the structure following the next sequence of processing steps. Every exposed portion of the nitride layer  425  is removed by either a selective wet etch or reactive ion etching (RIE), leaving only the nitride  425  covered by the intrinsic polysilicon  430  at the bottom of the trenches  414 . The intrinsic polysilicon  430  is then removed by either a selective wet etch or reactive ion etching (RIE). The device regions,  405  and  407  respectively, remain protected by the oxide layer  420 . Next, n-doped glass  432  is deposited, such a by CVD. In one embodiment the n-doped glass  432  is Arsenic silicate glass (ASG). In another embodiment, the n-doped glass  432  is phosphorus silicate glass (PSG). The n-doped glass  432  is deposited to a thickness of approximately 100 nm. A new silicon nitride (Si 3 N 4 ) layer  434  is deposited over the n-doped glass  432 . The new nitride layer  434  is CVD deposited to a thickness of approximately 20 nm. A photoresist is applied and selectively exposed to expose PMOS device regions  405  and to pattern the n-doped glass  432  in the NMOS device regions  407  in the form of future source/emitter and collector/drain regions. The structure is now as is shown in FIG.  4 E. 
     FIG. 4F illustrates the structure following the next series of process steps. The exposed nitride  434  and the underlying n-doped glass  432  are removed by any suitable means, such as by RIE. The nitride located at the bottom of the trenches  414  serves as an etch stop and protects the underlying insulator layer  415 . The photoresist is stripped using conventional stripping techniques. A thin nitride layer  434  remains on the patterned n-doped glass  432  which was shielded by the photoresist. The structure is now as is shown in FIG.  4 F. 
     FIG. 4G illustrates the structure following the next sequence of steps. A p-doped glass  436  is deposited by any suitable means such as, for example, CVD. In one embodiment, the p-doped glass  436  is borosilicate glass (BSG). The p-doped glass  436  is deposited to a thickness of approximately 100 nm. Again, a photoresist is applied and exposed to now expose the NMOS device regions  407  and to pattern the p-doped glass  436  in the PMOS device regions  405  in the form of future source/emitter and collector/drain regions. The structure is now as is shown in FIG.  4 G. 
     FIG. 4H illustrates the structure following the next series of process steps. The exposed p-doped glass  436  is removed by any suitable means, such as by RIE. The nitride located at the bottom of the trenches  414  again serves as an etch stop and protects the underlying insulator layer  415 . Also, the thin nitride layer  434  remaining on patterned n-doped glass  432  portions serves as an etch stop and protects the regions of patterned n-doped glass  432 . The photoresist is stripped using conventional stripping techniques. The structure is now as shown in FIG.  4 H. 
     FIG. 4I provides a perspective view of the structure after next process step. In this step a gate oxide  450  is thermally grown on the p− single crystalline silicon structure  412  of the NMOS device region  407 , and on the n-well single crystalline silicon structure  410  of the PMOS device region  405 . 
     FIG. 4J carries the sequence of process steps further. In FIG. 4J, a thin intrinsic polysilicon layer  455  is deposited, such as by CVD. The intrinsic polysilicon layer  455  is formed to a thickness of approximately 20 nm. A photoresist is applied and masked to expose adjacent portion of NMOS and PMOS device regions,  407  and  405  respectively, which share a common trench  414  between the devices. The exposed intrinsic polysilicon layer  455  and the gate oxide  450  are etched back. The etching is performed by any suitable method and can be accomplished using reactive ion etching (RIE). The structure is now as appears in FIG.  4 J. 
     FIG. 4K illustrates the structure following the next sequence of process steps. The photoresist has been stripped using conventional photoresist stripping techniques. Now, another intrinsic polysilicon layer  460  is deposited across the entire surface. The intrinsic polysilicon layer is deposited by any suitable means, such as by CVD, to a thickness of approximately 100 nm. Next, an n-type dopant, as represented by arrows  467 , is angle implanted, such as by ion implantation at an angle of 45 degrees, in order to dope the intrinsic polysilicon  460  over the gate oxide  450  in the NMOS device region  407 . The n-doped polysilicon  460  acts as a gate over the gate oxide  450  in the NMOS device region. The angled ion implantation simultaneously introduces the n-type dopant into the intrinsic polysilicon  460  on the side of the n-well single crystalline silicon structure  410  opposite the gate oxide  450  side of the PMOS device region  405 . The n-doped polysilicon  460  in this location acts as the body contact to the n-well single crystalline silicon structure  410 . In one embodiment, the n-type dopant is Arsenic (As). In another embodiment, the n-type dopant is Phosphorus (P). 
     In a parallel manner, an p-type dopant, as represented by arrows  469 , is angle implanted in the reciprocal direction, such as by ion implantation at an angle of  45  degrees. This step is performed in order to dope the intrinsic polysilicon  460  over the gate oxide  450  in the PMOS device region  405 . The p-doped polysilicon  460  acts as a gate over the gate oxide  450  in the PMOS device region  405 . The angled ion implantation simultaneously introduces the p-type dopant into the intrinsic polysilicon  460  on the side of the p− single crystalline silicon structure  412  opposite the gate oxide  450  side of the NMOS device region  407 . The p-doped polysilicon  460  in this location acts as the body contact to the p− single crystalline silicon structure  412 . In one embodiment, the p-type dopant is Boron (B). The structure is now as appears in FIG.  4 K. 
     FIG. 4L illustrates the structure following the next series of process steps. Polysilicon  460  is directionally etched to leave the doped polysilicon only on the vertical side walls of the NMOS and PMOS device regions,  407  and  405  respectively. The structure then undergoes an anneal, such as a rapid thermal anneal (RTA), in order to drive the dopant species from the heavily doped polysilicon  460  into the underlying, undoped polysilicon  455  The anneal also serves to drive the dopant into the n-well single crystalline silicon structure  410  and the p− single crystalline silicon structure  412  from the p-doped glass  436  and the n-doped glass  432  respectively. As one skilled in the art will appreciate, the anneal process also cures out the crystal damage induced by the previous ion implant processes. FIG. 4L illustrates that the anneal step has merged the once separate doped polysilicon layer  460  and undoped polysilicon layer  455 . In effect, the anneal step forms a heavily doped n+ gate  461  in the NMOS device region  407 , and forms a heavily doped p+ gate  462  in the PMOS device region  405 . In the same fashion, the anneal step forms a heavily doped n+ body contact  464  in the PMOS device region  405 , and forms a heavily doped p+ body contact  463  in the NMOS device region  407 . 
     FIG. 4L further provides a broader perspective and illustrates full length NMOS and PMOS devices,  470  and  471  respectively. FIG. 4L illustrates the location of the newly formed source/emitter regions,  481  and  482 , and the collector/drain regions,  483  and  484 , for the NMOS and PMOS devices,  470  and  471 . FIG. 4M is a top view of FIG. 4L taken along cut line  4 M— 4 M 
     Finally, in a final sequence of processing steps, and following conventional method, a photoresist is applied and masked to expose any vertical walls where polysilicon,  461  or  462 , is to be removed to terminate gate lines. Such polysilicon,  461  or  462  is then etched back by any suitable method, such as by RIE. The photoresist is stripped using conventional photoresist stripping techniques. An oxide or other insulator is deposited and planarized to fill the trenches  414  between the NMOS and PMOS devices,  470  and  471  respectively. The insulator deposition is performed by any suitable method, such as by CVD. The planarization is also achieved by any suitable technique, such as by CMP. 
     Contact holes and wiring for both the gate contact and the electrical contact are achieved through conventional processing steps. One skilled in the art will recognize the method to these steps and, hence, they are not disclosed as part of this application. 
     Conclusion 
     A CMOS inverter is provided, capable of combination with similar inverters to form an inverter array. The array of inverters can be further combined with a metallization layer to form a logic circuit and to external components to form a functional circuit. The present invention conserves surface space achieves a higher density of surface structures per chip. The structures offer performance advantages from both metal-oxide semiconductor (MOS) and bipolar junction transistor (BJT) designs. The devices can be used in a variety of applications, digital and analog, wherever a more compact structure with low power consumption and fast response time is needed. 
     It is to be understood that the above description is intended to be illustrative, and not restrictive. Combinations of the above embodiments, and other embodiments will be apparent to those of skill in the art upon reviewing the above description. The above structures and fabrication methods have been described, by way of example, and not by way of limitation, with respect to the transistors and inverters. However, the scope of the invention includes any other integrated circuit applications in which the above structures and fabrication methods are used. Thus, the scope of the invention is not limited to the particular embodiments shown and described herein. The scope of the invention should be determined with reference to the appended claims, along with the full scope of equivalents to which such claims are entitled.