Abstract:
A compact switching device for applications in integrated circuits is disclosed. The switching device comprises a P-type conductive channel and an N-type conductive channel, both formed on a very-thin semiconductor film. A lightly doped portion in each of said conductive channels is controlled by a single gate electrode formed on a dielectric layer above the channel regions. These lightly doped portions are designed to provide an enhanced conductive state by accumulating majority carriers at the surface, and a non-conductive state by fully depleting majority carriers from the entire thin-film thickness from the single gate electrode provided. Both gate electrodes are coupled to a common input, and both drain nodes are coupled to a common output. Design parameters are optimized to provide complementary devices side-by-side on a single geometry of the thin film, merged at the common drain node.

Description:
This application is a division of application Ser. No. 10/413,809 filed on Apr. 14, 2003 now U.S. Pat. No. 6,855,988, which claims priority from Provisional Application Ser. No. 60/393,763 filed on Jul. 08, 2002, Provisional Application Ser. No. 60/397,070 filed on Jul. 22, 2002, Provisional Application Ser. No. 60/400,007 filed on Aug. 01, 2002, Provisional Application Ser. No. 60/402,573 filed on Aug. 12, 2002, and Provisional Application Ser. No. 60/449,011 filed on Feb. 24, 2003, all of which list as inventor Mr. R. U. Madurawe and the contents of which are incorporated-by-reference. 
     This application is related to application Ser. No. 10/267,484, application Ser. No. 10/267,483 now abandoned, and application Ser. No. 10/267,511 now U.S. Pat. No. 6,747,478, all of which were filed on Oct. 08, 2002 and list as inventor Mr. R. U. Madurawe, the contents of which are incorporated-by-reference. 
     This application is also related to a new IGFET device disclosed in the application Ser. No. 10/413,808, filed on Apr. 14, 2003, and list as inventor Mr. R. U. Madurawe, the contents of which are incorporated-by-reference. 
    
    
     BACKGROUND 
     The present invention relates to semiconductor switching devices. 
     A switching device includes a four terminal device, which couples its output node to any one of two available voltage sources based on an input level. A three terminal switch in electrical applications is a light bulb switch: output connects to power when the input is on, and open circuit when the input is off. Common 4 terminal switches in the semiconductor industry include single input inverters and 2:1 MUXs. The inverter and MUX output switches between two voltage levels based on the input voltage level. In the inverter, the output voltage has an opposite polarity to the input voltage. Inverters can be classified into three types: full CMOS inverter, resistor load inverter, and thin film PMOS load inverter. A Depletion load inverter is not commonly used in sub micron geometries. It is not discussed in detail in this disclosure. The common inverter is used for boosting signal levels, and constructing latches. A latch consists of two inverters connected back to back and allows storing digital data when the latch is powered. These latches are used to build static random access memory (SRAM) devices. Very high density SRAM memory is used in Integrated Circuits to store and access large amounts of digital data very quickly. 
     A switching device fabrication in single crystal Silicon (Si) has two different methods. The most popular CMOS inverter in  FIG. 1  has two MOSFET transistors. Fabrication comprises a simple Logic Process flow with no special processing needed. Both transistors are located in a substrate single crystal Silicon, and have high mobilities for electron and hole conduction. This inverter area is large, standby current is negligible and the output current drive is very good. This inverter configuration is used for high cost, least power, fastest access SRAM memory, and for data buffering and high current output drivers. 
     In  FIG. 1 , the inverter contains two voltage sources  103  and  104 . These are typically V D  (power) and V S  (ground) respectively, but do not need to be so. The switch has an input voltage  101 , and an output voltage  102 . A PMOS  110  is connected between voltage source  103  and output node  102 , and an NMOS  120  is connected between output node  102  and voltage source  104 . Both transistor gates are tied together for a common input  101 . When the input is at logic 1 (V D ), the NMOS device is on and the PMOS device is off, connecting voltage source  104  to output  102 . When the input is at logic 0 (V S ), the NMOS is off and PMOS is on connecting source  103  to output  102 . As both NMOS and PMOS have high mobility, the current drives via the transistors are very high. The output is driven very strongly to one of the two voltage supply levels. Any deviations from these values are corrected very quickly via the conducting transistors. If V D  and V S  were two other voltage levels V 1  and V 2 , the device in  FIG. 1  is a 2:1 CMOS MUX with input  101  and output  102 . 
     The CMOS inverter consumes a relatively large amount of Silicon area.  FIGS. 2A and 2B  show a conventional CMOS inverter fabricated using a conventional twin well process. Both PMOS and NMOS devises comprises a conducting path and a gate. In  FIG. 2A , NMOS conducting path is  220 , while PMOS conducting path is  210 . Both NMOS and PMOS share a common gate  201 . NMOS conducting path  220  is inside a P-well  230 , while PMOS conducting path  210  is inside an N-well  240 . PMOS source and drain diffusions  211  and  212  are P+ diffusion regions, while NMOS source and drain diffusions  214  and  213  are N+ diffusion regions. Conducting path include these source and drain diffusions. Due to potential latch-up conditions, a separation distance Y is maintained between the two conducting paths  210  and  220 . Hence the two devices are constructed on two separate active geometries on the substrate  250 . Both Nwell  240  and Pwell  230  are constructed on a substrate  250  of the device, which could be P-type or N-type. Latch-up arises from the P+/N-well/P-Well regions  212 / 240 / 230  and N+/P-Well/N-well regions  213 / 230 / 240  bipolar parasitic transistors near the well boundary as shown in  FIG. 2B . In  FIG. 2B , PMOS source  211  and body  240  are tied to V D    203 , and NMOS source  213  and body  230  are tied to V S    204 . In other applications, the body may be separately biased. The Pwell  230  has to be biased to the lowest potential, while the Nwell  240  has to be biased to the highest potential. 
     In addition to the CMOS approach, the inverter can be fabricated as a Resistor-load inverter and a TFT PMOS-load inverter. They both have the pull-up device vertically integrated and require special poly-crystalline (poly) silicon for the load device construction. The pull-up devices in  FIGS. 3A and 3B  are poly Silicon resistor  310 , and TFT PMOS  3010  respectively, and are not built on single crystal silicon. The pull-down NMOS device conducting paths  320  and  3020  remain in single crystal silicon. The vertically integrated pull-up device allows elimination of N-wells in the substrate, and a smaller inverter construction area. Latches constructed with these inverters consume standby power as one inverter is always conducting, and the power consumption is determined by the resistor value. For 1 Meg density of latches and 1 mA standby current, a resistor value of 1 GOhms is needed. High value intrinsic poly-silicon resistors are hard to build, and TFT PMOS devices offer better manufacturability. TFT PMOS can be also used as active weak PMOS pull-up devices similar to regular PMOS in  FIG. 1  to eliminate stand-by current. As the pull-up device  310  or  3010  drive current is very weak, these inverters cannot drive a strong logic one. These configurations of inverters are only used to build latches to construct low cost, high density, higher power, and medium access SRAM memory. Such memories need complex dual ended sense amplifiers to read the latch data. 
     Inverters in  FIGS. 1 and 3  can be constructed with Metal-Oxide-Semiconductor-Field-Effect-Transistor (MOSFET) devices, which is a sub-class of more generic Insulated-Gate Field-Effect Transistor (IGFET). The inverter in  FIG. 1  cannot be constructed with Junction Field Effect Transistors (JFET) due to the voltage restrictions on the gate as discussed below. 
     The MOSFET operates by conducting current between its drain and source through a conducting surface channel created by the presence of a gate voltage.  FIG. 4  shows a cross section of an N-MOSFET (NMOS) conducting channel  410  with a depletion region shown shaded. In  FIG. 4 , an NMOS transistor body  400  is P− doped, isolating an N+ doped source region  414  and an N+ doped drain region  413 . Source and drain diffusions are connected to terminals  404  and  403  respectively. The result is the formation of two N+/P− back-to-back reverse-biased diodes. For this discussion, the source  404  is assumed at zero (V S ). When the voltage  402  at gate  412  is zero, the N+/P− back-to-back reverse-biased diodes do not conduct and the transistor is off. There is no surface channel  410 , and the body surface under insulator  405  next to gate  412  is in accumulation of majority hole carriers. The conduction path between source and drain is now substantially non-conductive. In the embodiment of  FIG. 4 , the gate  412  includes a salicided region  422 . A spacer  420  is formed adjacent to gate  412 . Source and drain salicidation is not shown in  FIG. 4 . When the gate voltage  402  is greater than a threshold voltage (V T ) of the transistor, an inversion occurs near the surface, shown by channel  410 , completing an electron carrier path between the source  414  and drain  413  regions causing current flow. The conducting path now include source  414 , channel  410  and drain  413  and is substantially conductive. In addition to the inversion layer, charge depletion occurs adjacent to the body region  400  due to the gate, source and drain voltages. The component of this depleted charge from the gate voltage determines the magnitude of the V T . Trapped oxide charge and Silicon defects affect the V T  transistor parameter. The more positive the voltage is at the gate, the stronger is the conduction. At all levels, the substrate  400  potential is kept at the lowest voltage level. In most applications, the substrate and source are held at V S . Substrate can be pumped to negative voltages for special applications. 
     A PMOS device is analogous to an NMOS device, with the device operational polarity and doping types reversed. PMOS source is typically tied to V D . A PMOS is on when the gate is at V S , and off when the gate is at V D . Conducting path includes a P+ doped source and drain, and a surface inversion layer in the Nwell body region. The Nwell is biased to the highest potential, and in most applications the source and Nwell are held at V D . 
     As discussed in U.S. Pat. No. 5,537,078, conventional JFET transistors are of two main types: P-channel (PJFET) and N-channel (NJFET). In NJFET,  FIG. 5 , a semiconductor channel  506  which has been doped N− is positioned between two N+ diffusions  513  and  514 . Conducting path includes diffusion  513 , resistive channel  506  and diffusion  514 . Terminals  503  and  504  are coupled to diffusions  513  and  514 . The terminal supplying the majority carrier to the channel (which is the lowest potential) is designated the source (S) while the other terminal is designated the drain (D). Across the N-channel  506  there are two diffused gates which are referred to as the top gate  512  and the bottom gate  522 . Those are connected to terminals  502  and  532  respectively. Each gate is doped with P+ type dopant to create two back to back P+/N− diodes. When drain and source voltages are different, the drain to source current passes entirely through the conducting N-channel  506 . This current increases with higher voltage drop between the terminals, reaching a saturation value at high biases. The gates are biased to keep the gate to channel P+/N− junctions reversed biased. The reversed biased voltage creates depletion regions  510  and  520  that penetrate into the channel reducing the channel height available for current flow. The depletion regions merge at drain end  530  to cause current saturation at high drain bias. The gate voltages also control the flow of current between the source and drain by modulating the channel height. When the gate reverse bias is sufficiently large, the entire channel is pinched-off causing no current flow between drain and source. Conducting path is then substantially non-conductive. In both on and off states of a JFET, there is no current flow through the gate terminal due to reverse bias junction voltages, except for junction leakage current. For the device in  FIG. 5  a negative gate voltage (lower than V S ) creates the channel off condition. Such a negative gate voltage increases the operating voltage of this process, a draw back for JFET scheme. 
     A PJFET device is analogous to an NJFET device, with the device operational polarity and doping types reversed. PJFET source is held at V D . A PJFET is on when the gate is at V D , and off when the gate is more positive than V D  increasing the voltage level of the process. Conducting path includes P+ doped source and drain regions, and a P− doped channel sandwiched between two N+ doped gate regions. For terminals at voltages V S  and V D , operating range of NJFET gate is less than V S  to V S , while the operating range for PJFET gate is V D  to more than V D . This non-overlapping gate voltage prevents having a common gate input. 
     Compared to the non-conducting body  400  of MOSFET on  FIG. 4 , the JFET has a conducting channel  406  between source and drain. Due to non-overlapping gate voltages and the high voltage range thus needed, a complementary JFET process is impractical to realize. Hence there is no low cost process that provides CJFET devices analogous to CMOS devices. Compared to the MOSFET in  FIG. 4 , a JFET conducting channel is formed inside the body of the switching device. This channel current is not affected by trapped oxide charges near the gate, a draw back with MOSFETs. Compared to MOSFETs, JFETs also have poorer switching characteristics due to higher depleted charge stored in the channel and the transient times required to accumulate and disperse this depletion charge. Reverse biased junctions hurt JFET device ease of use and popularity in modern day ICs. 
     For the discussion that follows, the terminology Gated-FET device is used. A gated-FET device is defined as a mixed device between a conventional MOSFET device and a conventional JFET device. The Gated-FET device conducting channel is like that of JFET devices: entirely comprising of a thin film resistive channel between the source and drain regions. There is no inversion layer like in a MOSFET to conduct current. The Gated-FET device gate is like that of a MOSFET device: the gate constructed above a dielectric material and capable of modulating the thin film channel conduction. There is no gate junction like in a JFET to reverse bias the channel. The Gated-FET device is disclosed in detail in the application “Insulated-Gate Field-Effect Thin Film Transistors”. 
     SUMMARY 
     In one aspect, a switching device includes a conducting path of a first device coupled between a first supply voltage and a common output; and a conducting path of a second device coupled between a second supply voltage and said common output; and a common input to control said first and second devices; and said first and second devices comprised of a Gated-FET device. Conducting path of said Gated-FET device is comprised of a source, a resistive channel and a drain region wherein, said resistive channel is formed in between said source and drain regions comprised of same dopant type as said source and drain regions, and said resistive channel is modulated to a substantially non-conductive state by a first voltage level of said common input, and said resistive channel is modulated to a substantially conductive state by a second voltage level of said common input. 
     In a second aspect, a switching device includes a conducting path of a first device coupled between a first supply voltage and a common output; and a conducting path of a second device coupled between a second supply voltage and said common output; and a common input to control said first and second devices; and said conductive paths of first and said second devices comprised of a single geometry of a semiconductor material. 
     Advantages of the invention may include one or more of the following. A switching device uses Gated-FET transistors with no increase in voltage range compared to JFET. A switching device has a smaller area by eliminating the latch-up spacing requirement of a twin-well process. The two devices in a switch are constructed in one semiconductor geometry. A switching device is constructed with all semiconductor thin film transistors. The switching device is constructed in a second semiconductor plane, different from a first plane used for logic transistor construction. The switching device is a CMOS inverter. The switching device is a Complementary Gated-FET (CGated-FET) inverter. The CGated-FET inverter is constructed with a common gate with identical voltage range to power and ground voltage levels. The switching device is a mixed MOSFET and Gated-FET inverter. A latch is constructed with two inverters connected back to back. A thin film transistor body is fully depleted. The transistors have fully salicided source and drain regions adjacent to lightly doped source and drain tip regions. The switching devices and latches consume less silicon area. Large latch arrays have a lower cost in spite of the added wafer cost for process complexity. 
     The method of fabricating the new switch may have one or more of following advantages. The new switch is fabricated as thinned down crystalline Silicon layer in SOI technology, having very high performance. The new switch is fabricated in poly-crystalline silicon layers using thin films and thin film transistors (TFT). A latch may be constructed with a conventional inverter, and a new inverter vertically integrated. A TFT module layer may be inserted to a logic process module. The TFT module layer may be inserted to SOI process module. 
     Implementation of the new switch may have one or more following advantages. Latches are vertically integrated to a logic process for FPGA applications. A split latch is constructed with a conventional inverter in a first layer, and a new inverter in a second layer connected back to back. A split latch is used to construct high density SRAM memory. A split SRAM memory is used for high memory content FPGA applications. The split level latch cells have very high performance similar to full CMOS latches. The split level latches have very low power consumption similar to full CMOS SRAM memory. New latches can be used for very fast access embedded memory applications. Thinned down split latch SOI memory allows very high memory densities. The latch can be used in embedded memory or high density memory. The complete TFT latch can be stacked above logic transistors, further reducing silicon area and cost. Full TFT latches have longer access times, but useful for slow memory applications. Slow TFT latches can be used in PLDs (Programmable Logic Devices) and subsequently mapped to ASICs (Application Specific Integrated Circuit). The PLDs are used for prototyping and low volume production, while the ASICs are used for high volume production. In PLDs, programmable TFT latches are used. In ASICs the latches are replaced with hard-wired metal. 
     The invention thus provides an attractive solution for two separate industries: (i) very high density stand alone or embedded low power, fast access SRAM memory and (ii) high-density, low-cost SRAM for PLD and FPGA with convertibility to ASIC. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
         FIG. 1  shows a conventional CMOS inverter (switch). 
         FIGS. 2A and 2B  show conventional CMOS inverter fabricated using a conventional twin well process. 
         FIGS. 3A and 3B  shows a conventional resistor load inverter and a conventional TFT PMOS load inverter. 
         FIG. 4  shows a conventional NMOS transistor conduction channel. 
         FIG. 5  shows a conventional NJFET transistor conduction channel. 
         FIGS. 6A and 6B  show embodiments of switching devices. 
         FIG. 7  shows a smaller area embodiment of a switching device. 
         FIGS. 8A ,  8 B and  8 C show CMOS inverter fabricated using a thin film process. 
         FIGS. 9A and 9B  show a Complementary Gated-FET inverter fabricated using a thin film process. 
         FIGS. 10A and 10B  show a top view and a cross-sectional view of a Gated-PFET transistor. 
         FIG. 11  show constructional cross sections of processing steps showing fabrication of one embodiment of the TFT switch. 
     
    
    
     DESCRIPTION 
     The terms wafer and substrate used in the following description include any structure having an exposed surface with which to form the switch 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. The term layer is used for processing steps used in the manufacturing process. The term layer also includes each of the masking layers of the process. Both wafer and substrate include doped and undoped semiconductors, epitaxial semiconductor layers supported by a base semiconductor or insulator, SOI material 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 term conducting path defines conductors and semiconductors connected in series. A conducting path includes multiple semiconductor regions having different dopant levels. A conducting path may be conductive or non-conductive based on the semiconductor properties in the conducting path. The term geometry is used to define an isolated pattern of a masking layer. Thus one mask layer is a collection of geometries in the mask pattern. The term module includes a structure that is fabricated using a series of predetermined process steps. The boundary of the structure is defined by a first step, one or more intermediate steps, and a final step. The resulting structure is formed on a substrate. The following detailed description is, therefore, not to be taken in a limiting sense. 
     The switches shown in  FIGS. 1 ,  2 , and  3  are schematically shown in  FIG. 6 . The switch shown in  FIG. 6A  has not been constructed with JFET devices due to voltage limitations. In the conventional CMOS switching device shown in  FIG. 1  and  FIG. 6A , the conducting path  610  allows current flow between terminal  603  and output  602 , while conducting path  620  allows current flow between terminal  604  and output  602 . The conducting paths  610  and  620  are constructed in single crystal semiconductor active geometries. These active geometries are physically separated to allow for the latch up related well rules discussed earlier. First device comprises gate  612  and conducting path  610 . Second device comprises gate  612  and conducting path  620 . Conducting path  610  couples output  602  to first voltage source  603 . Conducting path  620  couples output  602  to second voltage source  604 . Voltage level at common gated input  601  selects which of the two voltage sources  603  or  604  is coupled to output  602 . In the conventional resistor load switching device shown in  FIG. 3A  and  FIG. 6B , the conducting path for current flow is via the resistor and the single crystal active regions. The conducting path  6010  is the resistor or the TFT resistor itself. Second device comprises gate  6012  and conducting path  6020 . Conducting paths  6010  and  6020  are physically separated to facilitate the vertical integration. Conducting path  6010  permanently couples a first voltage source  6003  to output  6002 , while conducting path  6020  couples output  6002  to second voltage source  6004 . Voltage level at common input  6001  couples the output  6002  to one of two voltage sources  6003  or  6004 . In both cases the two conducting paths are constructed in two separate semiconductor geometries and connected together at the common node by either metal contacts, or buried contacts. 
     In a first embodiment of the new switching device the transistors are constructed as Gated-FET devices. The switching device in  FIG. 6A  comprises a conducting path  610  of a first device coupled between a first supply voltage  603  and a common output  602 ; and a conducting path  620  of a second device coupled between a second supply voltage  603  and said common output  602 ; and a common input  601  to control said first and second devices. Conducting paths  610  and  620  of Gated-FET devices comprises a source, a resistive channel and a drain region wherein, said resistive channel is formed in between said source and drain regions comprised of same dopant type as said source and drain regions, and said resistive channel is modulated to a substantially non-conductive state by a first voltage level of said common input  601 , and said resistive channel is modulated to a substantially conductive state by a second voltage level of said common input  601 . 
     The switching device in  FIG. 6A  further comprises a common input  601  voltage at a first level turning said conducting path  610  of first device off and said conducting path  620  of second device on to couple said second supply voltage  604  to said common output  602 ; and said common input  601  voltage at a second level turning said conducting path  610  of first device on and said conducting path  620  of second device off to couple said first supply voltage  603  to said common output  602 . 
     In a second embodiment of the new switching device, the conducting paths of first and second devices are constructed in one plane of single semiconductor geometry. The new switching device in  FIG. 7A  comprises a conducting path  710  of a first device coupled between a first supply voltage  703  and a common output  702 ; and a conducting path  720  of a second device coupled between a second supply voltage  704  and said common output  702 ; and a common input  701  to control said first and second devices; and said conductive paths  710  and  720  of first and said second devices comprised of a single geometry of a semiconductor material. The device in  FIG. 7  is further comprised of said conducting path modulated to a non-conductive state by a first voltage level of said common input  701 ; and said conducting path modulated to a conductive state by a second voltage level of said common input  701 . 
     In one embodiment of a new switch, all of the transistors are constructed using thin film MOSFET transistors.  FIGS. 8A ,  8 B and  8 C show the top view and cross sectional view of a thin film CMOS MOSFET inverter in accordance with aspects of the present invention. Comparing  FIGS. 2A  with  8 A, the spacing Y=0 for TFT CMOS inverter. There is also no N-well and no P-well. TFT PMOS  810  is butted against TFT NMOS  820  at the common output node  802 . Common gate node,  860  having a common input terminal  801  ties the PMOS gate region  852  to NMOS gate region  855 . Both devices are built on single semiconductor geometry  850  as shown in  FIG. 8B , but have multiple implant regions: PMOS source  851 , PMOS body  852 , PMOS drain  853 , NMOS drain  854 , NMOS body  855 , and NMOS source  856 . The NMOS gate above  855  is doped N+ while the PMOS gate above  852  is doped P+ to achieve the threshold voltages (V T ) for the MOSFETs. For each device, Gate, Drain and Source dopant type is the same. One N+ implant for NMOS and one P+ implant for PMOS can dope Gate, Drain and Source regions after the gates are etched and spacers are formed. The body doping levels P− for NMOS  855  and N− for PMOS  852  are chosen to achieve the desirable V T .  FIGS. 8B and 8C  are two different embodiments of the present invention. In  FIGS. 8B &amp; 8C  gates  860  are salicided. In  FIG. 8B  drain &amp; source regions are either partially salicided or not salicided. N+ and P+ dopant is needed to define drain and source regions. In  FIG. 8C , source and drain regions are completely salicided as region  870  to reduce the source &amp; drain resistance. When fully salicided, the source &amp; drain regions are defined by the self aligned tip implants  881 ,  883 ,  884  and  886  shown under the spacer oxides adjacent to the gate regions in  FIG. 8C , and no N+ or P+ implants are needed. The body regions  852  and  855  are unchanged between  FIGS. 8B and 8C . 
     The first semiconductor geometry  850  forming the conducting paths for devices  810  and  820  can be a thinned down SOI single crystal Silicon film, or a deposited thin Poly-crystalline silicon film, or a post laser annealed as deposited amorphous Poly-crystalline silicon film. The thickness of the first layer and doping are optimized with the gate oxide thickness to get the required V T , on-current and off-current for these devices. The first layer thickness is further optimized to contain the conducting full inversion layer within the film thickness and to ensure a fully depleted body for the MOSFET when the device is on. A thickness parameter X for a semiconductor material is defined by:
 
 X=q   2 /(2 *kT*ε   S ) Angstroms   (EQ 1)
 
     Where, q is electron charge, kT/q is the thermal voltage and ε S  is the permittivity of the semiconductor material that is used for the conducting body of the MOSFET. For Si semiconductor at 300 Kelvin, X=299 Angstroms. In this embodiment, the first layer thickness t P1  in Angstroms and first layer doping D in Atoms/Angstroms 3  are chosen such that it satisfies the following inequalities:
 
1/( D*t   P1   2 )&lt; X  Angstroms   (EQ 2)
 
1/( D*t   P1   2 )&gt;0.5 *X /Ln( D/N   i ) Angstroms   (EQ3)
 
     Where, N i  is the intrinsic carrier concentration of the semiconductor material. For Silicon at room temperature, N i =1.45e-14 Atoms/A 3 . For 250 A thick first silicon film doped to 5E-7 Atoms/A 3 , the left hand ratio of Eq-2 and Eq-3 becomes 32 A, while X is 299 A (rounded to 300 A for simplicity) and the right hand side of Eq-3 is 8.6 Angstroms. Both of the inequalities are thus satisfied. For a practical range of gate oxide thicknesses in the range 30 A to 100 A, the body region needs to be doped &gt;1E16 Atoms/cm 3  to achieve the correct threshold voltage: For that minimum doping density, the right hand side of Eq-3 becomes 11 Angstroms. The first inequality in Eq-2 ensures that when the MOSFET is on, the inversion layer is fully contained inside the first layer. The second condition in Eq-3 ensures that the first layer is fully depleted when the MOSFET is on. The first thin layer and second gate layer salicidation is achieved in one salicidation process step. The deposited Nickel or Cobalt thickness and Rapid Thermal Anneal cycle optimization will allow full consumption of first layer during salicidation. The functionality of the new inverter is identical to the conventional inverter shown in  FIG. 2 , but occupies much less area. 
     Other embodiments may use gate and substrate materials different from silicon. Gate dielectrics can be oxide, oxy-nitride, nitride, or multi-layered insulators. The semiconductor material may be silicon, silicon-germanium, gallium-arsenide, germanium, or any other III–V material. The gate material may be poly-silicon, aluminum, tungsten, or any other metal. The value of X in equation-1 will change based on the physical properties of the materials chosen to form the MOSFET device. The device threshold voltage is designed to be in the range ⅕ to ⅓ of Vcc value and the gate oxide thickness is optimized and surface charge density is controlled to achieve that. 
     In another embodiment of the inverter, all of the thin film transistors are constructed using complementary Gated-FETs, while maintaining the logic voltage level of the process.  FIGS. 9A and 9B  show the top view and cross sectional view of a TFT Gated-FET inverter in accordance with aspects of the present invention. Compared to the JFET device in  FIG. 5 , the Gated-JFET device in  FIG. 10  has an identical conducting body, but the double diffused gate is replaced by a single insulated-Gate like that in MOSFET  FIG. 4 . 
     In  FIG. 9 , a Gated-PFET device  910  and a Gated-NFET device  920  (as detailed in  FIGS. 9A &amp; 9B ) are merged at a common node  902 . The Gated-PFET source is connected to a first voltage source  103  (V D ) and Gated-NFET source is connected to a second voltage source  104  (V S ). These could be power and ground terminals respectively. There is also no N-well and no P-well. Common gate node  960  having a common input Vin  901  ties the Gated-PFET gate region  952  to Gated-NFET gate region  955 . During operation, if the gate is zero, the Gated-PFET device  910  is on, and the Gated-NFET device  920  is off, and the common node  902  is coupled to V D  so that the output is at logic one. If the gate is at logic one, the Gated-PFET device  910  is off and the Gated-NFET device  920  is on, and the common node  902  is coupled to V S  to provide a logic zero at the output. Compared to conventional JFET shown in  FIG. 5 , the thin film Gated-FET can be built with a common gate by appropriate control of layer  950  thickness. One aspect of this invention is the ability to have a complementary gate input for Gated-FET inverter with identical voltage range. 
     Both devices are built on a single semiconductor geometry  950  as shown in  FIG. 9B , but have multiple implant regions: Gated-PFET source  981 , Gated-PFET body  952 , Gated-PFET drain  983 , Gated-NFET drain  984 , Gated-NFET body  955 , and Gated-NFET source  986 . A second aspect of this invention is the ability to have a single geometry for both conducting paths. The Gated-NFET gate above  955  is doped P+ while the Gated-PFET gate above  952  is doped N+ to achieve the threshold voltages (V T ) for the Gated-FETs. The channel doping levels N− for Gated-NFET  955  and P− for Gated-PFET  952  are chosen to achieve the desirable conduction on and off current levels. In  FIG. 9B  gate  960  is partially salicided while source and drain regions are completely salicided like region  970  to reduce the source &amp; drain resistance. When fully salicided, the source &amp; drain regions are defined by the self aligned tip implants  981 ,  983 ,  984  and  986  shown under the spacer oxides adjacent to the gate regions in  FIG. 9C , and no N+ or P+ implants are needed. 
     Compared to  FIG. 8 , the Gated-FET gates in  FIG. 9  are doped opposite to Source/Drain dopant type. This is easily achieved in the fully salicided source/drain embodiment shown in FIG.  9 B. The Gated-NFET and Gated-PFET gate regions are first doped P+ and N+ respectively before the gates are etched. After gates are etched, prior to spacer formation, Gated-NFETs are implanted with N tip implant and Gated-PFETs are implanted with P tip implant. The tip-implant dose is much lower than the gate doping to affect gate doping type. The Source &amp; Drain regions are now defined by the self aligned tip implants shown under the spacer oxides adjacent to the gate regions. As the drain and source regions outside the spacer are fully consumed by salicide, those regions do not need heavy doping. The channel doping levels N− for Gated-NFET and P− for Gated-PFET are chosen to achieve the desirable V T . The Gated-NFET is off with zero bias on the gate by fully depleting the first thin film region under the gate, and is on when the gate is at V D . The Gated-PFET is off with V D  bias on the gate by fully depleting the first thin film region under the gate, and is on when the gate is at V S . The first semiconductor layer forming the body for  910  and  920  can be thinned down SOI single crystal Silicon material, or a first thin-film Polysilicon layer. A thicker first film allows higher current. The thickness is further optimized to allow the entire film to conduct in its on state, and the entire film to be depleted in its off state. A thickness parameter Y for a semiconductor material is defined by:
 
 Y=q /(2*ε S *Φ MS ) Angstroms   (EQ 4)
 
     Where, q is electron charge and ε S  is the permittivity of the semiconductor material that is used for the conducting body of the Gated-FET and Φ MS  is the gate to body work function. When there is fixed charge in the oxide, Φ MS  in EQ-4 is replaced by V FB , the flat band voltage for the device. For Φ MS ˜1 Volt, and Si semiconductor material, Y is 7.7 Angstroms. In this embodiment, the first layer thickness t P1  is in Angstroms, first layer doping D in Atoms/Angstroms 3 , gate dielectric thickness t G  in Angstroms and permittivity ε G  are chosen such that they satisfy the following inequality:
 
1 /[D *( t   P1 +(ε S /ε G )* t   P1 ) 2   ]&gt;Y  Angstroms   (EQ 5)
 
     For Si-oxide systems with Φ MS ˜1 Volt, Eq-5 reduces to:
 
1 /[D *( t   P1 +3 *t   OX ) 2 ]7.7 Angstroms   (EQ 6)
 
     Eq-5 and Eq-6 ensures that the first layer is fully depleted when the Gated-FET is off. For 70A thick gate oxide, P+ doped poly-silicon top gate at zero potential, Gated-NFET body N− doped to 5E17 Atoms/cm 3 , the left hand side of Eq-6 allows a maximum first film thickness of 300 A. A more rigorous surface potential and depletion thickness calculation yields a surface potential of 0.454 volts, and a maximum depletion of 343 Angstroms, in good agreement with this result. 
       FIGS. 10A and 10B  shows a top view and cross section of a Gated-PFET built in two thin film layers separated by a gate dielectric  1025 , grown either thermally or deposited by PECVD. The first thin film layer  1006  (P1) forms the body of the transistor. In one embodiment, this is thinned down single crystal SOI layer. In another embodiment this is a deposited polysilicon layer. The P1 layer is deposited above the insulator layer  1060 . A P1 mask is used to define and etch these P1 islands. Gated-PFET regions are mask selected and implanted with P− doping, the channel doping level required for Gated-PFET devices. Gated-NFET gets an N− implant. The gate  1002  is deposited after the gate insulator  1025  is deposited as a second thin film layer (P2). In the embodiment shown, the second thin film layer is a ploysilicon layer. The Gated-PFET gate poly  1002  is mask selected and implanted N+ prior to gate definition and etch. Gated-NFET gate region is doped P+. The gate regions are then defined and etched. A P tip implant region  1050  is defined and implanted for Gated-PFET, while an N tip is defined and implanted for Gated-NJFET. This can be done by open selecting Gated-PFET devices, and not selecting Gated-NFET device. The N+ doped gates are not affected by the lower P implant level. Gate  1002  blocks P tip implant getting into channel region  1040 , and only P1 regions outside P2 gets this P implant. Spacer oxide regions  1025  are formed on either side of gate by conventional oxide deposition and etch back techniques. In  FIG. 10A , the P2 gate  1002  is perpendicular to P1 body  1006 . The P2 gate and spacers  1025  sub-divide the P1 body into five regions: (1) source region  1003 , (2) source spacer region  1026  doped with P tip implant, (3) channel region  1040  doped with P− implant, (4) drain spacer region  1026  also doped with P tip implant and (5) drain region  1004 . The source and drain regions are fully salicided and need no implant. After the spacer etch, exposed P2 and P1 regions are reacted with deposited Nickel (or Cobalt) and salicided using Rapid Thermal Annealing. The P tip implant after P2 etch forms self-aligned P Source/Drain tip regions and salicidation after spacer etch forms self aligned Source/Drain salicide regions. 
     The total resistance of the conducting body region for Gated-PFET and Gated-NFET is determined as follows:
 
 R=ρ   P1   *L   P2 /( W   P1   *t   P1 )   (EQ7)
 
     where, ρ P1  is the resistivity of lightly doped P1 region in the resistive channel, L P2  is poly resistor length  1040  in  FIG. 10B , W P1  is the width of P1  1040  in  FIG. 10A , and t P1  is P1 thickness ( FIG. 9B ). Gate voltage and channel depletion heavily modulates resistivity ρ P1 . Parameters are chosen for R to be in the 1 KOhm to 1 Meg-Ohm range, preferably 10 KOhm to 100 KOhms, when the channel is on and Vds=Vcc. As an example, for P− doping 2E17 atoms/cm 3 , neglecting the effect of channel modulation in the P− region, the resistivity for single crystal Silicon is 0.12 Ohm-cm. When L P2 =0.3μ, W P1 =0.3μ, t P1 =400 Angstroms, R is 30 KOhms. This is the conducting path resistance under flat band conditions. When V DS =0.3V, the channel current I ON  is 10 μA. Poly-silicon mobility is lower than single crystal silicon degrading the on current, while surface accumulation from the gate bias can enhance the on current. Gated-FETs allow thicker P1 film thicknesses compared to MOSFETs in thin film devices, and hence higher currents. 
     The usage of thin films eliminates the need for diode gates and associated forward biased diode currents in Gated-FETs. Thus, the voltage level is not increased. It also allows forming Gated-NFET and Gated-PFET in the same process, and combining those to form logic inverters with a common thin film node. Moreover, the P1 film isolates N− body and P− body from one another, minimizing latch-up possibilities allowing a smaller inverter layout area. Other embodiments may use gate and substrate materials different from silicon. Gate dielectrics can be oxide, oxy-nitride, nitride, or multi-layered insulators. The semiconductor material may be silicon, germanium-silicon, gallium-arsenide, or germanium. The gate material may be poly-silicon, aluminum, tungsten, or any other metal. The device threshold voltage is designed to be in the range ⅕ to ⅓ of Vcc value. 
     In other embodiments in accordance with the current invention, the inverter can be made by combining MOSFET and Gated-FET devices. In one embodiment, a PMOS pull up device- 1  and Gated-NFET pull down device- 2  can form the inverter. In another embodiment, a Gated-PFET pull up device- 1  and an NMOS pull down device  2  can form the inverter. The pull-up device source is connected to V D  and pull-down device source is connected to V S  for both inverters. These mixed mode inverter pairs allow first thin-film body to be doped with the same dopant type, facilitating device optimization with a no mask, blanket, first thin film implant. The tip implant type and gate implant type differentiate between the two device types. 
     For the devices  710  and  720  in  FIG. 7  a high quality P1 film is beneficial. As used herein, P1 refers to the first semiconductor layer in  FIG. 7  and P2 refers to the second semiconductor layer in  FIG. 7  forming the gate. An ideal film is a single crystal silicon with a precise thickness control over an insulator. In SOI technology, the single crystal silicon layer above an insulator meets this criterion. Inside the latch array, P1 is mask selected and thinned down to the required thickness as defined by Eq-2, 3 or Eq-5. 
     The following terms used herein are acronyms associated with certain manufacturing processes. The acronyms and their abbreviations are as follows: 
     V T  Threshold voltage 
     LDN Lightly doped NMOS drain 
     LDP Lightly doped PMOS drain 
     LDD Lightly doped drain 
     RTA Rapid thermal annealing 
     Ni Nickel 
     Ti Titanium 
     TiN Titanium-Nitride 
     W Tungsten 
     S Source 
     D Drain 
     G Gate 
     ILD Inter layer dielectric 
     C1 Contact-1 
     M1 Metal-1 
     P1 Poly-1 
     P− Positive light dopant (Boron species, BF 2 ) 
     N− Negative light dopant (Phosphorous, Arsenic) 
     P+ Positive high dopant (Boron species, BF 2 ) 
     N+ Negative high dopant (Phosphorous, Arsenic) 
     Gox Gate oxide 
     C2 Contact-2 
     LPCVD Low pressure chemical vapor deposition 
     CVD Chemical vapor deposition 
     ONO Oxide-nitride-oxide 
     LTO Low temperature oxide 
     A logic process is used to fabricate CMOS devices on a substrate layer. These CMOS devices may be used to build AND gates, OR gates, inverters, adders, multipliers, memory and other logic functions in an integrated circuit. A CMOSFET TFT module layer or a CGated-FET TFT module layer may be inserted to a logic process at a first contact mask to build a second set of TFT MOSFET or Gated-FET devices. An exemplary logic process may include one or more following steps: 
     P-type substrate starting wafer 
     Shallow Trench isolation: Trench Etch, Trench Fill and CMP 
     Sacrificial oxide 
     PMOS V T  mask &amp; implant 
     NMOS V T  mask &amp; implant 
     Pwell implant mask and implant through field 
     Nwell implant mask and implant through field 
     Dopant activation and anneal 
     Sacrificial oxide etch 
     Gate oxidation/Dual gate oxide option 
     Gate poly (GP) deposition 
     GP mask &amp; etch 
     LDN mask &amp; implant 
     LDP mask &amp; implant 
     Spacer oxide, deposition &amp; spacer etch 
     N+ mask and NMOS N+ G, S, D implant 
     P+ mask and PMOS P+ G, S, D implant 
     Ni deposition 
     RTA anneal—Ni salicidation (S/DIG regions &amp; interconnect) 
     Unreacted Ni etch 
     ILD oxide deposition &amp; CMP 
       FIG. 11  shows an exemplary process for fabricating a thin film MOSFET latch in a module layer. In one embodiment the process in  FIG. 11  forms the latch in a layer substantially above the substrate layer. The processing sequence in  FIGS. 11.1  through  11 . 7  describes the physical construction of a MOSFET device shown in  FIG. 7 , and  FIG. 9 . The process of  FIG. 11  includes adding one or more following steps to the logic process after ILD oxide CMP step. 
     C1 mask &amp; etch 
     W-Silicide plug fill &amp; CMP 
     ˜300 A poly P1 (crystalline poly-1) deposition 
     P1 mask &amp; etch 
     Blanket Vtn P− implant (NMOS Vt) 
     Vtp mask &amp; N− implant (PMOS Vt) 
     TFT Gox (70 A PECVD) deposition 
     500 A P2 (crystalline poly-2) deposition 
     P2 mask &amp; etch 
     Blanket LDN NMOS N− tip implant 
     LDP mask and PMOS P− tip implant 
     Spacer LTO deposition 
     Spacer LTO etch to form spacers &amp; expose P1 
     Blanket N+ implant (NMOS G/S/D &amp; interconnect) 
     P+ mask &amp; implant (PMOS G/S/D &amp; interconnect) 
     Ni deposition 
     RTA salicidation and poly recrystallization (G/S/D regions &amp; interconnect) 
     Dopant activation anneal 
     Excess Ni etch 
     ILD oxide deposition &amp; CMP 
     C2 mask &amp; etch 
     W plug formation &amp; CMP 
     M1 deposition and back end metallization 
     The TFT process technology consists of creating NMOS &amp; PMOS poly-silicon transistors in the embodiment in  FIG. 11 , the module insertion is after the substrate device gate poly etch and the ILD film is deposition. In other embodiments the insertion point may be after M1 and the ILD is deposition, prior to V 1  mask, or between two metal definition steps. 
     After gate poly of regular transistors are patterned and etched, the poly is salicided using Nickel &amp; RTA sequences. Then the ILD is deposited, and polished by CMP techniques to a desired thickness. In the shown embodiment, the contact mask is split into two levels. The first C1 mask contains all contacts that connect latch outputs to substrate transistor gates and active nodes. Then the C1 mask is used to open and etch contacts in the ILD film. Ti/TiN glue layer followed by W-Six plugs, W plugs, or Si plugs may be used to fill the plugs, then CMP polished to leave the fill material only in the contact holes. The choice of fill material is based on the thermal requirements of the TFT module. 
     Then, a first P1 poly layer, amorphous or crystalline, is deposited by LPCVD to a desired thickness as shown in  FIG. 11.1 . The P1 thickness is between 50 A and 1000 A, and preferably 250 A. This poly layer P1 is used for the channel, source, and drain regions for both NMOS and PMOS TFT&#39;s. It is patterned and etched to form the transistor body regions. In other embodiments, P1 is used for contact pedestals. NMOS transistors are blanket implanted with P− doping, while the PMOS transistor regions are mask selected and implanted with N− doping. This is shown in  FIG. 11.2 . The implant doses and P1 thickness are optimized to get the required threshold voltages for PMOS &amp; NMOS devices under fully depleted transistor operation, and maximize on/off device current ratio. The pedestals implant type is irrelevant at this point. In another embodiment, the V T  implantation is done with a mask P− implant followed by masked N− implant. First doping can also be done in-situ during poly deposition or by blanket implant after poly is deposited. 
     Patterned and implanted P1 may be subjected to dopant activation and crystallization. In one embodiment, RTA cycle is used to activate &amp; crystallize the poly after it is patterned to near single crystal form. In a second embodiment, the gate dielectric is deposited, and buried contact mask is used to etch areas where P1 contacts P2 layer. Then, Ni is deposited and salicided with RTA cycle. All of the P1 in contact with Ni is salicided, while the rest poly is crystallized to near single crystal form. Then the unreacted Ni is etched away. In a third embodiment, amorphous poly is crystallized prior to P1 patterning with an oxide cap, metal seed mask, Ni deposition and MILC (Metal-Induced-Lateral-Crystallization). 
     Then the TFT gate dielectric layer is deposited followed by P2 layer deposition. The dielectric is deposited by PECVD techniques to a desired thickness in the 30–200 A range, desirably 70 A thick. The gate may be grown thermally by using RTA. This gate material could be an oxide, nitride, oxynitride, ONO structure, or any other dielectric material combination used as gate dielectric. The dielectric thickness is determined by the voltage level of the process. At this point an optional buried contact mask (BC) may be used to open selected P1 contact regions, etch the dielectric and expose P1 layer. BC could be used on P1 pedestals to form P1/P2 stacks over C1. In the P1 salicided embodiment using Ni, the dielectric deposition and buried contact etch occur before the crystallization. In the preferred embodiment, no BC is used. 
     Then second poly P2 layer, 300 A to 2000 A thick, preferably 500 A is deposited as amorphous or crystalline poly-silicon by LPCVD as shown in  FIG. 11.3 . P2 layer is defined into NMOS &amp; PMOS gate regions intersecting the P1 layer body regions, C1 pedestals if needed, and local interconnect lines and then etched. The P2 layer etching is continued until the dielectric oxide is exposed over P1 areas uncovered by P2 (source, drain, P1 resistors). As shown in  FIG. 10A , the source &amp; drain P1 regions orthogonal to P2 gate regions are now self aligned to P2 gate edges. The S/D P2 regions may contact P1 via buried contacts. NMOS devices are blanket implanted with LDN N− dopant. Then PMOS devices are mask selected and implanted with LDP P− dopant as shown in  FIG. 11.4 . The implant energy ensures full dopant penetration through the residual oxide into the S/D regions adjacent to P2 layers. 
     A spacer oxide is deposited over the LDD implanted P2 using LTO or PECVD techniques. The oxide is etched to form spacers  1025  shown in residual oxide over P1 in a first embodiment, and completely removes oxide over exposed P1 in a second embodiment. The latter allows for P1 salicidation at a subsequent step. Then NMOS devices &amp; N+ poly interconnects are blanket implanted with N+. The implant energy ensures full or partial dopant penetration into the 100 A residual oxide in the S/D regions adjacent to P2 layers. This doping gets to gate, drain &amp; source of all NMOS devices and N+ interconnects. The P+ mask is used to select PMOS devices and P+ interconnect, and implanted with P+ dopant as shown in  FIG. 11.5 . PMOS gate, drain &amp; source regions receive the P+ dopant. This N+/P+ implants can be done with N+ mask followed by P+ mask. The V T  implanted P1 regions are now completely covered by P2 layer and spacer regions, and form channel regions of NMOS &amp; PMOS transistors. 
     After the P+/N+ implants, Nickel is deposited over P2 and salicided to form a low resistive refractory metal on exposed poly by RTA. Un-reacted Ni is etched as shown in  FIG. 11.6 . This 100 A-500 A thick Co-salicide connects the opposite doped poly-2 regions together providing low resistive poly wires for data. In one embodiment, the residual gate dielectric left after the spacer prevents P1 layer salicidation. In a second embodiment, as the residual oxide is removed over exposed P1 after spacer etch, P1 is salicided. The thickness of Ni deposition may be used to control fill or partial salicidation of P1 regions in  FIG. 10  and  FIG. 11.6 . Fully salicided S/D regions up to spacer edge facilitate high drive current due to lower source and drain resistances. 
     An LTO film is deposited over P2 layer, and polished flat with CMP. A second contact mask C2 is used to open contacts into the TFT P2 and P1 regions in addition to all other contacts to substrate transistors. In the shown embodiment, C1 contacts connecting latch outputs to substrate transistor gates require no C2 contacts. Contact plugs are filled with tungsten, CMP polished, and connected by metal as done in standard contact metallization of IC&#39;s as shown in  FIG. 11.7 . 
     A TFT process sequence similar to that shown in  FIG. 11  can be used to build complementary Gated-FET thin film devices shown in  FIGS. 9 and 10 . The process steps facilitate the device doping differences between MOSFET and Gated-FET devices, and simultaneous formation of complementary Gated-FET TFT devices. A detailed description for this process was provided when describing  FIG. 10  earlier. An exemplary CGated-FET process sequence may use one or more of the following steps: 
     C1 mask &amp; etch 
     W-Silicide plug fill &amp; CMP 
     ˜300 A poly P1 (crystalline poly-1) deposition 
     P1 mask &amp; etch 
     Blanket Vtn N− implant (Gated-NFET V T ) 
     Vtp mask &amp; P− implant (Gated-PFET V T ) 
     TFT Gox (70 A PECVD) deposition 
     500 A P2 (crystalline poly-2) deposition 
     Blanket P+ implant (Gated-NFET gate &amp; interconnect) 
     N+ mask &amp; implant (Gated-PFET gate &amp; interconnect) 
     P2 mask &amp; etch 
     Blanket LDN Gated-NFET N tip implant 
     LDP mask and Gated-PFET P tip implant 
     Spacer LTO deposition 
     Spacer LTO etch to form spacers &amp; expose P1 
     Ni deposition 
     RTA salicidation and poly re-crystallization (exposed P1 and P2) 
     Fully salicidation of exposed P1 S/D regions 
     Dopant activation anneal 
     Excess Ni etch 
     ILD oxide deposition &amp; CMP 
     C2 mask &amp; etch 
     W plug formation &amp; CMP 
     M1 deposition and back end metallization 
     In another embodiment, thinned down SOI is used to construct the latch shown in  FIG. 7 . A logic process used to fabricate CMOS devices on a substrate layer is modified to accommodate thinned down latch regions. These periphery devices may be used to build AND gates, OR gates, inverters, adders, multipliers, memory and other logic functions in an integrated circuit. Latch devices may be constructed to integrate a high density of latches or memory into the first fabrication module. A thinned down module is inserted to an exemplary logic process that may include one or more of following steps: 
     SOI substrate wafer 
     Shallow Trench isolation: Trench Etch, Trench Fill and CMP 
     Sacrificial oxide 
     Periphery PMOS V T  mask &amp; implant 
     Periphery NMOS V T  mask &amp; implant 
     Periphery Pwell implant mask and implant through field 
     Periphery Nwell implant mask and implant through field 
     Latch mask and silicon etch 
     Latch NMOS V T  mask and implant 
     Latch PMOS V T  mask and implant 
     Dopant activation and anneal 
     Sacrificial oxide etch 
     Gate oxidation/Dual gate oxide option 
     Gate poly (GP) deposition 
     GP mask &amp; etch 
     LDN mask &amp; N− implant 
     LDP mask &amp; P− implant 
     Spacer oxide deposition &amp; spacer etch 
     N+ mask and N+ implant 
     P+ mask and P+ implant 
     Ni deposition 
     RTA anneal—Ni salicidation (S/DIG regions &amp; interconnect) 
     Dopant activation 
     Unreacted Ni etch 
     ILD oxide deposition &amp; CMP 
     C mask and etch 
     In this embodiment, the latch body doping is independently optimized for performance, but shares the same LDN, LDP, N+ and P+ implants. The SOI thickness is assumed to be large to warrant well implants for peripheral CMOS devices. Based on dopant type selection, the latch can be complementary MOSFET or Gated-FET devices. In the Gated-FET embodiment, the Gated-FET gates are separately doped N+ &amp; P+ prior to gate etch, and blocked during N+/P+ implants of peripheral devices. In other embodiments, latch devices and periphery devices may share one or more V T  implants. One P2 is used for latch and peripheral device gates. In another embodiment, SOI substrate devices may be integrated with a TFT latch module. This allows for a SOI inverter and TFT inverter to be vertically integrated to build high density, fast access memory devices. 
     Processes described in the incorporated-by-reference Provisional Application Ser. Nos. 60/393,763 and 60/397,070 support poly-film TFT-SRAM cell and anti-fuse construction. This new usage differs from the process of  FIG. 11  in doping levels and film thicknesses optimized for switch applications. The thin-film transistor construction and the Thin-Film Anti-Fuse construction may exist side by side with this Thin-Film Latch element if the design parameters overlap. 
     These processes can be used to fabricate a generic field programmable gate array (FPGA) with the inverters connecting to form latches and SRAM memory. Such memory in a TFT module may be replaced with hard wired connections to form an application specific integrated circuit (ASIC). Multiple ASICs can be fabricated with different variations of conductive patterns from the same FPGA. The memory circuit and the conductive pattern contain one or more substantially matching circuit characteristics. The process can be used to fabricate a high density generic static random access memory (SRAM) with inverters connecting to form latches and SRAM memory. A TFT module may be used to build a vertically integrated SRAM cell with one inverter on a substrate layer, and a second inverter in a TFT layer. 
     Although an illustrative embodiment of the present invention, and various modifications thereof, have been described in detail herein with reference to the accompanying drawings, it is to be understood that the invention is not limited to this precise embodiment and the described modifications, and that various changes and further modifications may be effected therein by one skilled in the art without departing from the scope or spirit of the invention as defined in the appended claims.