Abstract: A dynamic random access memory cell is described which can operate either in volatile or nonvolatile mode. When operating in a volatile mode, the memory cell operates in the same manner as a conventional dynamic random access memory cell, that is, with charge being stored and discharged from a capacitor in the memory cell. Upon receipt of a suitable signal, however, the cell can be switched to a nonvolatile mode of operation. In this mode of operation, a pulse applied to the capacitor can place a ferroelectric film in the desired polarization state to represent the binary data. The ferroelectric film will hold its polarization state until the data is recalled and the cell reverts to operating in a volatile mode.

Abstract: A capacitor with a metal-oxide dielectric layer is formed with an upper electrode layer that is electrically connected to an underlying circuit element. The capacitor may be used in forming storage capacitors for DRAM and NVRAM cells. After forming an underlying circuit element, such as a source/drain region of a transistor, a metal-oxide capacitor is formed over the circuit element. An opening is formed through the capacitor and extends to the circuit element. An insulating spacer is formed, and a conductive member is formed that electrically connects the circuit element to the upper electrode layer of the metal-oxide capacitor. Devices including DRAM and NVRAM cells and methods of forming them are disclosed.

Abstract: A capacitor with a metal-oxide dielectric layer is formed with an upper electrode layer that is electrically connected to an underlying circuit element. The capacitor may be used in forming storage capacitors for DRAM and NVRAM cells. After forming an underlying circuit element, such as a source/drain region of a transistor, a metal-oxide capacitor is formed over the circuit element. An opening is formed through the capacitor and extends to the circuit element. An insulating spacer is formed, and a conductive member is formed that electrically connects the circuit element to the upper electrode layer of the metal-oxide capacitor. Devices including DRAM and NVRAM cells and methods of forming them are disclosed.

Abstract: An electrical ceramic oxide capacitor utilizable in an integrated circuit memory device, and a method for making same is presented. A transistor is fabricated on a semiconductor substrate according to conventional techniques. A diffusion barrier is deposited over the transistor to protect it from subsequent process steps. Metal contacts are formed to contact the active transistor regions in the substrate, and additional barriers are formed to insulate the metal contacts. In a vertical embodiment, the barriers above the metal contacts can serve as bottom electrodes for the capacitor. In a lateral embodiment, the barriers on the side of the metal contacts serve as electrodes for the capacitor. Electrical ceramic oxide material is deposited between the electrode plates.

Abstract: A method for forming an air region or an air bridge overlying a base layer (12). Air regions (20a, 20b, 28a, and 48) are formed overlying the base layer (12) to provide for improved dielectric isolation of adjacent conductive layers, provide air-isolated conductive interconnects, and/or form many other microstructures or microdevices. The air regions (20a, 20b, 28a, and 48) are formed by either selectively removing a sacrificial spacer (16a and 16b) or by selectively removing a sacrificial layer (28, 40). The air regions (20a, 20b, 28a, and 48) are sealed, enclosed, or isolated by either a selective growth process or by a non-conformal deposition technique. The air regions (20a, 20b, 28a, and 48) may be formed under any pressure, gas concentration, or processing condition (i.e. temperature, etc.). The air regions (20a, 20b, 28a, and 48) may be formed at any level within an integrated circuit.

Abstract: The present invention includes a semiconductor device having a layer including an elemental metal and its conductive metal oxide, wherein the layer is capable being oxidized or reduced preferentially to an adjacent region of the device. The present invention also includes processes for forming the devices. Substrate regions, silicon-containing layers, dielectric layers, electrodes, barrier layers, contact and via plugs, interconnects, and ferroelectric capacitors may be protected by and/or formed with the layer. Examples of elemental metals and their conductive metal oxides that may be used with the present invention are: ruthenium and ruthenium dioxide, rhenium and rhenium dioxide, iridium and iridium dioxide, osmium and osmium tetraoxide, or the like.

Abstract: The present invention includes a semiconductor device having a layer including an elemental metal and its conductive metal oxide, wherein the layer is capable being oxidized or reduced preferentially to an adjacent region of the device. The present invention also includes processes for forming the devices. Substrate regions, silicon-containing layers, dielectric layers, electrodes, barrier layers, contact and via plugs, interconnects, and ferroelectric capacitors may be protected by and/or formed with the layer. Examples of elemental metals and their conductive metal oxides that may be used with the present invention are: ruthenium and ruthenium dioxide, rhenium and rhenium dioxide, iridium and iridium dioxide, osmium and osmium tetraoxide, or the like.

Abstract: An electrical ceramic oxide capacitor utilizable in an integrated circuit memory device, and a method for making same is presented. A transistor is fabricated on a semiconductor substrate according to conventional techniques. A diffusion barrier is deposited over the transistor to protect it from subsequent process steps. Metal contacts are formed to contact the active transistor regions in the substrate, and additional barriers are formed to insulate the metal contacts. In a vertical embodiment, the barriers above the metal contacts can serve as bottom electrodes for the capacitor. In a lateral embodiment, the barriers on the side of the metal contacts serve as electrodes for the capacitor. Electrical ceramic oxide material is deposited between the electrode plates.

Abstract: A method for forming an air region or an air bridge overlying a base layer (12). Air regions (20a, 20b, 28a, and 48) are formed overlying the base layer (12) to provide for improved dielectric isolation of adjacent conductive layers, provide air-isolated conductive interconnects, and/or form many other microstructures or microdevices. The air regions (20a, 20b, 28a, and 48) are formed by either selectively removing a sacrificial spacer (16a and 16b) or by selectively removing a sacrificial layer (28, 40). The air regions (20a, 20b, 28a, and 48) are sealed, enclosed, or isolated by either a selective growth process or by a non-conformal deposition technique. The air regions (20a, 20b, 28a, and 48) may be formed under any pressure, gas concentration, or processing condition (i.e. temperature, etc.). The air regions (20a, 20b, 28a, and 48) may be formed at any level within an integrated circuit.

Abstract: The endurance of ferroelectric capacitors can be extended by refreshing the ferroelectric material. The ferroelectric material is refreshed by impressing a voltage across the ferroelectric capacitor, which voltage is higher than that which the capacitor experiences during normal operation. A memory array having ferroelectric capacitive cells can be refreshed by first reading the memory cells, temporarily storing the data in associated sense amplifiers, refreshing the memory cells by impressing a higher-than-normal voltage across the ferroelectric cell capacitors, then rewriting the temporarily stored data back into the memory cells. Refresh circuits connected between the drive line and bit line common to a number of cells are driven with voltages which are higher than the memory cell experiences during normal read operations. A V.sub.cc to ground pulse train is applied to the drive line, while an inverted waveform thereof is applied to the bit line during refresh operations.

Abstract: A circuit and technique for accessing a ferroelectric memory to read polarization states without destruction thereof. A small-amplitude positive polarity pulse is applied to the ferroelectric capacitor, and the resultant positive charge read therefrom. Thereafter, a small-amplitude negative polarity pulse is applied to the ferroelectric capacitor, and the resultant negative charge read therefrom. Because of the nonlinear hysteresis characteristics of the ferroelectric capacitor, the positive and negative readout charges are of different amplitudes. Sense amplifier circuits produce a summation of the positive and negative readout signals, with a resulting summation polarity defining the polarization state initially stored in the ferroelectric capacitor.