Entries |
Document | Title | Date |
20080206931 | NONVOLATILE MEMORY ELEMENT AND PRODUCTION METHOD THEREOF AND STORAGE MEMORY ARRANGEMENT - A nonvolatile memory element and associated production methods and memory element arrangements are presented. The nonvolatile memory element has a changeover material and a first and second electrically conductive electrode present at the changeover material. To reduce a forming voltage, a first electrode has a field amplifier structure for amplifying a field strength of an electric field generated by a second electrode in a changeover material. The field amplifier structure is a projection of the electrodes which projects into the changeover material. The memory element arrangement has multiple nonvolatile memory elements which are arranged in matrix form and can be addressed via bit lines arranged in column form and word lines arranged in row form. | 08-28-2008 |
20080206932 | DATA LINE LAYOUT IN SEMICONDUCTOR MEMORY DEVICE AND METHOD OF FORMING THE SAME - In one aspect, a semiconductor device is provided which includes a data block including M parallel and sequentially arranged data lines numbered {0, 1, 2, . . . n, n+1, . . . , m−1, m}, where M, n and m are positive integers, and where n08-28-2008 | |
20080242006 | METHODS OF FORMING NAND FLASH MEMORY WITH FIXED CHARGE - A string of nonvolatile memory cells connected in series includes fixed charges located between floating gates and the underlying substrate surface. Such a fixed charge affects distribution of charge carriers in an underlying portion of the substrate and thus affects threshold voltage of a device. A fixed charge layer may extend over source/drain regions also. | 10-02-2008 |
20080242007 | METHOD FOR SELECTIVELY ETCHING PORTIONS OF A LAYER OF MATERIAL BASED UPON A DENSITY OR SIZE OF SEMICONDUCTOR FEATURES LOCATED THEREUNDER - The disclosure provides a method for manufacturing a semiconductor device. The method, in one embodiment, includes forming semiconductor features ( | 10-02-2008 |
20090004786 | METHOD FOR FABRICATING A 3-D INTEGRATED CIRCUIT USING A HARD MASK OF SILICON-OXYNITRIDE ON AMORPHOUS CARBON - A method for fabricating a 3-D monolithic memory device. Silicon-oxynitride (Si | 01-01-2009 |
20090042340 | NONVOLATILE STORAGE DEVICE AND METHOD OF MANUFACTURING THE SAME, AND STORAGE DEVICE AND METHOD OF MANUFACTURING THE SAME - A nonvolatile storage device includes a plurality of bit lines | 02-12-2009 |
20090061567 | VIA CONFIGURABLE ARCHITECTURE FOR CUSTOMIZATION OF ANALOG CIRCUITRY IN A SEMICONDUCTOR DEVICE - A semiconductor device having a plurality of layers and a plurality of circuit elements arranged in tiles. At least one of the plurality of layers in the semiconductor device may be a via layer configured to determine the connections of the plurality of circuit elements. The semiconductor device may include an interconnection quilt having a plurality of metal layers disposed to interconnect the plurality of circuit elements. The plurality of circuit elements may be analog circuit element and/or digital circuit elements. The tiles may be analog tiles and digital tiles that form a mixed signal structured array. | 03-05-2009 |
20090075432 | SEMICONDUCTOR MEMORY DEVICE - In a multiport SRAM memory cell of the present invention, an access transistor of a first port is disposed in a p-type well, and an access transistor of a second port is disposed in a p-type well. The gates of all of transistors disposed in a memory cell extend in the same direction. With the configuration, a semiconductor memory device having a low-power consumption type SRAM memory cell with an increased margin of variations in manufacturing, by which a bit line can be shortened in a multiport SRAM memory cell or an associative memory, can be obtained. | 03-19-2009 |
20090162977 | Non-Volatile Memory Fabrication And Isolation For Composite Charge Storage Structures - Fabricating semiconductor-based non-volatile memory that includes composite storage elements, such as those with first and second charge storage regions, can include etching more than one charge storage layer. To avoid inadvertent shorts between adjacent storage elements, a first charge storage layer for a plurality of non-volatile storage elements is formed into rows prior to depositing the second charge storage layer. Sacrificial features can be formed between the rows of the first charge storage layer that are adjacent in a column direction, before or after forming the rows of the first charge layer. After forming interleaving rows of the sacrificial features and the first charge storage layer, the second charge storage layer can be formed. The layers can then be etched into columns and the substrate etched to form isolation trenches between adjacent columns. The second charge storage layer can then be etched to form the second charge storage regions for the storage elements. | 06-25-2009 |
20090258462 | METHOD FOR FORMING DOPED POLYSILICON VIA CONNECTING POLYSILICON LAYERS - The invention provides for polysilicon vias connecting conductive polysilicon layers formed at different heights. Polysilicon vias are advantageously used in a monolithic three dimensional memory array of charge storage transistors. Polysilicon vias according to the present invention can be used, for example, to connect the channel layer of a first device level of charge storage transistor memory cells to the channel layer of a second device layer of such cells formed above the first device level. Similarly, vias according to the present invention can be used to connect the wordline of a first device level of charge storage transistor memory cells to the channel layer of a second device layer of such cells. | 10-15-2009 |
20090291533 | System-On-Chip (SOC), Design Structure and Method - Disclosed is a system-on-chip (SOC) structure that allows for automated integration of multiple intellectual cores. The SOC structure incorporates a plurality of cells connected to a common bus on a chip. Each cell incorporates a functional core and an automated integration unit (AIU) connected to the functional core. Each AIU communicates integration information for its functional core over the common bus to the AIUs in the other cells. The exchange of information between the AIUs is controlled either by the integration units themselves or by a controller. Based on received integration information, each AIU can automatically make any required configuration adjustments for integration. Furthermore, based on this exchange of information, the functional cores can interact, as necessary, during SOC operation. Also disclosed are an associated method of forming such a SOC structure and a design structure for such an SOC structure. | 11-26-2009 |
20100075467 | NON-VOLATILE ELECTROMECHANICAL FIELD EFFECT DEVICES AND CIRCUITS USING SAME AND METHODS OF FORMING SAME - Non-volatile field effect devices and circuits using same. A non-volatile field effect device includes a source, drain and gate with a field-modulatable channel between the source and drain. Each of the source, drain, and gate have a corresponding terminal. An electromechanically-deflectable, nanotube switching element is electrically positioned between one of the source, drain and gate and its corresponding terminal. The others of the source, drain and gate are directly connected to their corresponding terminals. The nanotube switching element is electromechanically-deflectable in response to electrical stimulation at two control terminals to create one of a non-volatile open and non-volatile closed electrical communication state between the one of the source, drain and gate and its corresponding terminal. | 03-25-2010 |
20100184258 | METHOD AND APPARATUS FOR FORMING AN INTEGRATED CIRCUIT ELECTRODE HAVING A REDUCED CONTACT AREA - A method and an apparatus for manufacturing a memory cell having a nonvolatile resistive memory element with a limited size active area. The method comprises a first step of providing a dielectric volume and forming a plug opening within the dielectric volume. A recessed plug of a conductive material is then formed within a lower portion of the opening and a dielectric spacer is formed along the sidewalls of an upper portion of the opening. The spacer is cylindrical and has a central hole. A contact plug is subsequently formed within the central hole, the contact plug electrically coupled to the recessed plug. The contact plug can include a memory element or an additional memory element can be applied over the contact plug. | 07-22-2010 |
20100210075 | TECHNIQUES FOR PROVIDING A SOURCE LINE PLANE - Techniques for providing a source line plane are disclosed. In one particular exemplary embodiment, the techniques may be realized as an apparatus for providing a source line plane. The apparatus may comprise a source line plane coupled to at least one constant voltage source. The apparatus may also comprise a plurality of memory cells arranged in an array of rows and columns, each memory cell including one or more memory transistors. Each of the one or more memory transistors may comprise a first region coupled to the source line plane, a second region coupled to a bit line, a body region disposed between the first region and the second region, wherein the body region may be electrically floating, and a gate coupled to a word line and spaced apart from, and capacitively coupled to, the body region. | 08-19-2010 |
20100216284 | SEMICONDUCTOR MEMORY DEVICE - In a multiport SRAM memory cell of the present invention, an access transistor of a first port is disposed in a p-type well, and an access transistor of a second port is disposed in a p-type well. The gates of all of transistors disposed in a memory cell extend in the same direction. With the configuration, a semiconductor memory device having a low-power consumption type SRAM memory cell with an increased margin of variations in manufacturing, by which a bit line can be shortened in a multiport SRAM memory cell or an associative memory, can be obtained. | 08-26-2010 |
20100248431 | METHOD FOR MANUFACTURING NONVOLATILE STORAGE DEVICE - A method for manufacturing a nonvolatile storage device including: a plurality of first electrodes aligning in a first direction; a plurality of second electrodes aligning in a second direction nonparallel to the first direction and provided above the first electrodes; and a first storage unit provided between the first electrode and the second electrode and including a first storage layer, a resistance of the first storage layer changing by at least one of an applied electric field and an applied current, the method includes: stacking a first electrode film forming a first electrode and a first storage unit film forming a first storage unit on a major surface of a substrate; processing the first electrode film and the first storage unit film into a strip shape aligning in the first direction; burying a sacrifice layer between the processed first electrode films and between the processed first storage unit films; forming a second electrode film forming a second electrode on the first storage unit film and the sacrifice layer; forming a mask layer having a lower etching rate than the sacrifice layer on the second electrode film; processing the second electrode film into a strip shape aligning in the second direction nonparallel to the first direction by using the mask layer as a mask; removing a portion of the first storage unit film exposed from the sacrifice layer by using the mask layer as a mask to process the first storage unit film into a columnar shape including a side wall along the first direction and a side wall along the second direction; removing the sacrifice layer to expose the first storage unit film having been covered with the sacrifice layer; and removing the exposed first storage unit film. | 09-30-2010 |
20100261317 | OFFSET NON-VOLATILE STORAGE - A plurality of non-volatile storage elements on a common active layer are offset from neighbor non-volatile storage elements. This offsetting of non-volatile storage elements helps reduce interference from neighbor non-volatile storage elements. A method of manufacture is also described for fabricating the offset non-volatile storage elements. | 10-14-2010 |
20100273299 | METHOD FOR FABRICATING NON-VOLATILE STORAGE WITH INDIVIDUALLY CONTROLLABLE SHIELD PLATES BETWEEN STORAGE ELEMENTS - A method for fabricating non-volatile storage having individually controllable shield plates between storage elements. The shield plates are formed by depositing a conductive material such as doped polysilicon between storage elements and their associated word lines, and providing contacts for the shield plates. The shield plates reduce electromagnetic coupling between floating gates of the storage elements, and can be used to optimize programming, read and erase operations. In one approach, the shield plates provide a field induced conductivity between storage elements in a NAND string during a sense operation so that source/drain implants are not needed in the substrate. In some control schemes, alternating high and low voltages are applied to the shield plates. In other control schemes, a common voltage is applied to the shield plates. | 10-28-2010 |
20100279472 | MANUFACTURING METHOD OF NON-VOLATILE MEMORY - In a manufacturing method of a non-volatile memory, a substrate is provided, and strip-shaped isolation structures are formed in the substrate. A first memory array including memory cell columns is formed on the substrate. Each memory cell column includes memory cells connected in series with one another, a source/drain region disposed in the substrate outside the memory cells, select transistors disposed between the source/drain region and the memory cells, control gate lines extending across the memory cell columns and in a second direction, and first select gate lines respectively connecting the select transistors in the second direction in series. First contacts are formed on the substrate at a side of the first memory array and arranged along the second direction. Each first contact connects the source/drain regions in every two adjacent active regions. | 11-04-2010 |
20100297814 | ELECTRONIC SYSTEM MODULES AND METHOD OF FABRICATION - A trace routing method for a multi-layer interconnection circuit includes the steps of providing stacked contacts with trace stubs at input/output pads of said interconnection circuit, and limiting contacts between conductive layers to two-level contacts in routing areas where maximum routing density is desired. | 11-25-2010 |
20100323480 | MULTIPLE SELECT GATES WITH NON-VOLATILE MEMORY CELLS - Multiple select gates in association with non-volatile memory cells are described. Various embodiments include multiple select gate structure, process, and operation and their applicability for memory devices, modules, and systems. In one embodiment a memory array is described. The memory array includes a number of select gates coupled in series to a number of non-volatile memory cells. A first select gate includes a control gate and a floating gate electrically connected together and a second select gate includes a control gate and a floating gate which are electrically separated by a dielectric layer. | 12-23-2010 |
20110092029 | SRAM Cell with Different Crystal Orientation than Associated Logic - An integrated circuit containing logic transistors and an array of SRAM cells in which the logic transistors are formed in semiconductor material with one crystal orientation and the SRAM cells are formed in a second semiconductor layer with another crystal orientation. A process of forming an integrated circuit containing logic transistors and an array of SRAM cells in which the logic transistors are formed in a top semiconductor layer with one crystal orientation and the SRAM cells are formed in an epitaxial semiconductor layer with another crystal orientation. A process of forming an integrated circuit containing logic transistors and an array of SRAM cells in which the SRAM cells are formed in a top semiconductor layer with one crystal orientation and the logic transistors are formed in an epitaxial semiconductor layer with another crystal orientation. | 04-21-2011 |
20110151628 | Configuration of gate to drain (GD) clamp and ESD protection circuit for power device breakdown protection - A semiconductor power device supported on a semiconductor substrate comprising a plurality of transistor cells each having a source and a drain with a gate to control an electric current transmitted between the source and the drain. The semiconductor further includes a gate-to-drain (GD) clamp termination connected in series between the gate and the drain further includes a plurality of back-to-back polysilicon diodes connected in series to a silicon diode includes parallel doped columns in the semiconductor substrate wherein the parallel doped columns having a predefined gap. The doped columns further include a U-shaped bend column connect together the ends of parallel doped columns with a deep doped well disposed below and engulfing the U-shaped bend. | 06-23-2011 |
20110171787 | MULTIPLE-LAYER NON-VOLATILE MEMORY DEVICES, MEMORY SYSTEMS EMPLOYING SUCH DEVICES, AND METHODS OF FABRICATION THEREOF - In multiple-layered memory devices, memory systems employing the same, and methods of forming such devices, a second memory device layer on a first memory device layer comprises a second substrate including a second memory cell region. The second substrate includes only a single well in the second memory cell region, the single well of the second memory cell region comprising a semiconducting material doped with impurity of one of a first type and second type. The single well defines an active region in the second memory cell region of the second substrate. Multiple second cell strings are arranged on the second substrate in the second active region. Although the second memory cell region includes only a single well, during a programming or erase operation of the memory cells of the second layer, requiring a high voltage to be applied to the single well in the substrate of the second layer, the high voltage will not interfere with the operation of the peripheral transistors of the first layer, second layer, or other layers, since they are isolated from each other. As a result, the substrate of the second layer can be prepared to have a thinner profile, and with fewer processing steps, resulting in devices with higher-density, greater reliability, and reduced fabrication costs. | 07-14-2011 |
20110256672 | NONVOLATILE SEMICONDUCTOR MEMORY DEVICE AND METHOD OF MANUFACTURING THE SAME - A nonvolatile semiconductor memory device comprises a memory string, and a wiring. The memory string comprises a semiconductor layer, a charge storage layer, and a plurality of first conductive layers. The plurality of first conductive layers comprises a stepped portion formed in a stepped shape such that positions of ends of the plurality of first conductive layers differ from one another. The wiring comprises a plurality of second conductive layers extending upwardly from an upper surface of the first conductive layers comprising the stepped portion. The plurality of second conductive layers are formed such that upper ends thereof are aligned with a surface parallel to the substrate, and such that a diameter thereof decreases from the upper end thereof to a lower end thereof. The plurality of second conductive layers are formed such that the greater a length thereof in the perpendicular direction, the larger a diameter of the upper end thereof. | 10-20-2011 |
20120015486 | Semiconductor Constructions And Methods Of Forming Patterns - Some embodiments include methods of forming patterns. A semiconductor substrate is formed to comprise an electrically insulative material over a set of electrically conductive structures. An interconnect region is defined across the electrically conductive structures, and regions on opposing sides of the interconnect region are defined as secondary regions. A two-dimensional array of features is formed over the electrically insulative material. The two-dimensional array extends across the interconnect region and across the secondary regions. A pattern of the two-dimensional array is transferred through the electrically insulative material of the interconnect region to form contact openings that extend through the electrically insulative material and to the electrically conductive structures, and no portions of the two-dimensional array of the secondary regions is transferred into the electrically insulative material. | 01-19-2012 |
20120070944 | Methods of Manufacturing Three Dimensional Semiconductor Devices - Provided are methods of manufacturing a three dimensional semiconductor device. The method includes providing a substrate including a cell array region and a peripheral circuit region, forming a peripheral structure on the peripheral circuit region, forming a cell structure being thicker than the peripheral structure in the cell array region, forming an interlayer dielectric to cover the peripheral structure and the cell structure, forming a polishing stop layer on the interlayer dielectric, and planarizing the interlayer dielectric using the polishing stop layer as a planarization stop. | 03-22-2012 |
20120258574 | COUPLINGS WITHIN MEMORY DEVICES - A memory device includes a first bit line coupled to a first source/drain region of a first multiplexer gate, a second bit line coupled to a first source/drain region of a second multiplexer gate, and a sensing device having an input coupled to a second source/drain region of the first multiplexer gate and a second source/drain region of the second multiplexer gate. The input of the sensing device is formed at a vertical level that is different than a vertical level at which at least one of the first and second bit lines is formed. | 10-11-2012 |
20120302013 | SRAM CELL WITH DIFFERENT CRYSTAL ORIENTATION THAN ASSOCIATED LOGIC - An integrated circuit containing logic transistors and an array of SRAM cells in which the logic transistors are formed in semiconductor material with one crystal orientation and the SRAM cells are formed in a second semiconductor layer with another crystal orientation. A process of forming an integrated circuit containing logic transistors and an array of SRAM cells in which the logic transistors are formed in a top semiconductor layer with one crystal orientation and the SRAM cells are formed in an epitaxial semiconductor layer with another crystal orientation. A process of forming an integrated circuit containing logic transistors and an array of SRAM cells in which the SRAM cells are formed in a top semiconductor layer with one crystal orientation and the logic transistors are formed in an epitaxial semiconductor layer with another crystal orientation. | 11-29-2012 |
20120329215 | Methods of Forming Memory Arrays - Some embodiments include methods of forming memory arrays. A stack of semiconductor material plates may be patterned to subdivide the plates into pieces. Electrically conductive tiers may be formed along sidewall edges of the pieces. The pieces may then be patterned into an array of wires, with the array having vertical columns and horizontal rows. Individual wires may have first ends joining to the electrically conductive tiers, may have second ends in opposing relation to the first ends, and may have intermediate regions between the first and second ends. Gate material may be formed along the intermediate regions. Memory cell structures may be formed at the second ends of the wires. A plurality of vertically-extending electrical interconnects may be connected to the wires through the memory cell structures, with individual vertically-extending electrical interconnects being along individual columns of the array. Some embodiments include memory arrays incorporated into integrated circuitry. | 12-27-2012 |
20130171777 | PROCESSING UNIT COMPRISING INTEGRATED CIRCUITS INCLUDING A COMMON CONFIGURATION OF ELECTRICAL INTERCONNECTS - A processing unit comprises a plurality of individual integrated circuits (ICs) electrically connected to one another via a common configuration of electrical interconnects (e.g., through-silicon vias). At least two of the ICs may be configured for a different function. In some examples, the processing unit is formed by selecting the ICs from stored groups of ICs. The stored ICs can be, for example, modular ICs in that the ICs can be mixed and matched in any suitable number or type in order to meet a particular set of functional requirements for the processing unit, which may depend on the application for the processing unit. Electrical coupling of these individual ICs via the electrical interconnects of the ICs results in a single processing unit that is configured to perform functions specifically suited for a particular application or set of applications. | 07-04-2013 |
20130295726 | Integrated Memory Arrays, And Methods Of Forming Memory Arrays - Some embodiments include methods of forming memory arrays. A stack of semiconductor material plates may be patterned to subdivide the plates into pieces. Electrically conductive tiers may be formed along sidewall edges of the pieces. The pieces may then be patterned into an array of wires, with the array having vertical columns and horizontal rows. Individual wires may have first ends joining to the electrically conductive tiers, may have second ends in opposing relation to the first ends, and may have intermediate regions between the first and second ends. Gate material may be formed along the intermediate regions. Memory cell structures may be formed at the second ends of the wires. A plurality of vertically-extending electrical interconnects may be connected to the wires through the memory cell structures, with individual vertically-extending electrical interconnects being along individual columns of the array. Some embodiments include memory arrays incorporated into integrated circuitry. | 11-07-2013 |
20130302948 | 3D ARRAY WITH VERTICAL TRANSISTOR - A memory array includes a base circuitry layer and a plurality of memory array layers stacked sequentially to form the memory array. Each memory array layer is electrically coupled to the base circuitry layer. Each memory array layer includes a plurality of memory units. Each memory unit includes a vertical pillar transistor electrically coupled to a memory cell. | 11-14-2013 |
20140030856 | THREE DIMENSIONAL MEMORY AND METHODS OF FORMING THE SAME - Some embodiments include a memory device and methods of forming the memory device. One such memory device includes a first group of memory cells, each of the memory cells of the first group being formed in a cavity of a first control gate located in one device level of the memory device. The memory device also includes a second group of memory cells, each of the memory cells of the second group being formed in a cavity of a second control gate located in another device level of the memory device. Additional apparatus and methods are described. | 01-30-2014 |
20140065772 | METHOD OF MAKING INTEGRATED CIRCUIT EMBEDDED WITH NON-VOLATILE PROGRAMMABLE MEMORY HAVING VARIABLE COUPLING - A programmable non-volatile device is made with a floating gate that functions as a FET gate that overlaps a portion of a source/drain region and allows for variable coupling through geometry and/or biasing conditions. This allows a programming voltage for the device to be imparted to the floating gate through variable capacitive coupling, thus changing the state of the device. Multi-state embodiments are also possible. The invention can be used in environments such as data encryption, reference trimming, manufacturing ID, security ID, and many other applications. | 03-06-2014 |
20140154845 | COMPLEMENTARY SOI LATERAL BIPOLAR FOR SRAM IN A CMOS PLATFORM - An example embodiment is a memory array. The memory array includes a SOI substrate and lateral bipolar junction transistors (BJTs) fabricated on the SOI substrate. The BJTs form first and second inverters cross coupled to form a memory cell. A read circuit outputs the binary state of the memory cell. A power supply is configured to supply a Vdd voltage to the read circuit and to supply a Vcc and a Vee voltage to the first set of lateral bipolar transistors and the second set of lateral bipolar transistors, wherein the Vee voltage is at least zero volts and the Vcc voltage is greater than the Vee voltage and is equal to or less than the Vdd voltage. | 06-05-2014 |
20140179068 | NON-VOLATILE MEMORY HAVING 3D ARRAY OF READ/WRITE ELEMENTS WITH LOW CURRENT STRUCTURES AND METHODS THEREOF - A three-dimensional array read/write (R/W) memory elements is formed across multiple layers of planes positioned at different distances above a semiconductor substrate. It is preferable to operate the R/W elements with low current and high resistive states. The resistance of these resistive states depends also on the dimension of the R/W elements and is predetermined by the process technology. A sheet electrode in series with the R/W element and a method of forming it provide another degree of freedom to adjust the resistance of the R/W memory element. The thickness of the sheet electrode is adjusted to obtain a reduced cross-sectional contact in the circuit path from the word line to the bit line. This allows the R/W memory element to have a much increased resistance and therefore to operate with much reduced currents. The sheet electrode is formed with little increase in cell size. | 06-26-2014 |
20140322870 | SRAM CELL WITH DIFFERENT CRYSTAL ORIENTATION THAN ASSOCIATED LOGIC - An integrated circuit containing logic transistors and an array of SRAM cells in which the logic transistors are formed in semiconductor material with one crystal orientation and the SRAM cells are formed in a second semiconductor layer with another crystal orientation. A process of forming an integrated circuit containing logic transistors and an array of SRAM cells in which the logic transistors are formed in a top semiconductor layer with one crystal orientation and the SRAM cells are formed in an epitaxial semiconductor layer with another crystal orientation. A process of forming an integrated circuit containing logic transistors and an array of SRAM cells in which the SRAM cells are formed in a top semiconductor layer with one crystal orientation and the logic transistors are formed in an epitaxial semiconductor layer with another crystal orientation. | 10-30-2014 |
20140370664 | WORD LINE AND BIT LINE PROCESSING FOR CROSS-POINT MEMORIES - Techniques for fabricating cross-point memory devices are disclosed in which word line (WL) and/or bit line (BL) processing is separate from cross-point memory memory-material processing, thereby providing an advantageous increase in thickness of the WL and/or BL metal that avoids an increase in the WL and BL resistances as feature sizes for cross-point memories scale smaller. | 12-18-2014 |
20160027790 | Three-Dimensional Printed Memory - As technology scales, the mask cost rises sharply. The present invention discloses a three-dimensional printed memory (3D-P). It uses shared data-masks to print data. Because a shared data-mask does not contain the mask-patterns for identical mass-contents, the share of the data-mask cost on each mass-content is significantly reduced. For mass publication, the minimum feature size of the 3D-P is preferably less than 45 nm. | 01-28-2016 |
20160027791 | Three-Dimensional Offset-Printed Memory - The present invention discloses a three-dimensional offset-printed memory (3D-oP). Compared with a conventional three-dimensional mask-programmed read-only memory (3D-MPROM), it has a lower data-mask count and thereby a lower data-mask cost. The mask-patterns for different memory levels/bits-in-a-cell are merged onto a multi-region data-mask. At different printing steps, a wafer is offset by different values with respect to said data-mask. Accordingly, data-patterns are printed into different memory levels/bits-in-a-cell from a same data-mask. | 01-28-2016 |