Abstract: An integrated circuit having a fingered capacitor with multiple metal fingers formed in inverted-trapezoid-shaped trenches in a multi-layer structure having a polish stop layer over an ultra-low-K dielectric layer over a low-K dielectric layer over a dielectric cap layer. The ultra-low-K dielectric layer reduces capacitance variations between the fingers, while the polish stop layer prevents metal height variations that would otherwise result from performing CMP directly on the ultra-low-K dielectric layer. The layered structure may include another low-K dielectric layer over the polish stop layer that provides a soft landing for the CMP. The polish stop layer may be removed after the CMP polishing and another ultra-low-K dielectric layer may be formed to encapsulate the tops of the metal fingers in the ultra-low-K dielectric material.

Abstract: An integrated circuit having a fingered capacitor with multiple metal fingers formed in inverted-trapezoid-shaped trenches in a multi-layer structure having a polish stop layer over an ultra-low-K dielectric layer over a low-K dielectric layer over a dielectric cap layer. The ultra-low-K dielectric layer reduces capacitance variations between the fingers, while the polish stop layer prevents metal height variations that would otherwise result from performing CMP directly on the ultra-low-K dielectric layer. The layered structure may include another low-K dielectric layer over the polish stop layer that provides a soft landing for the CMP. The polish stop layer may be removed after the CMP polishing and another ultra-low-K dielectric layer may be formed to encapsulate the tops of the metal fingers in the ultra-low-K dielectric material.

Abstract: An integrated circuit having a fingered capacitor with multiple metal fingers formed in inverted-trapezoid-shaped trenches in a multi-layer structure having a polish stop layer over an ultra-low-K dielectric layer over a low-K dielectric layer over a dielectric cap layer. The ultra-low-K dielectric layer reduces capacitance variations between the fingers, while the polish stop layer prevents metal height variations that would otherwise result from performing CMP directly on the ultra-low-K dielectric layer. The layered structure may include another low-K dielectric layer over the polish stop layer that provides a soft landing for the CMP. The polish stop layer may be removed after the CMP polishing and another ultra-low-K dielectric layer may be formed to encapsulate the tops of the metal fingers in the ultra-low-K dielectric material.

Abstract: An integrated circuit has a first gated diode with one or more diode fingers. Each diode finger has an elevated gate, an underlying p-type diffusion, and an underlying n-type diffusion. Each diffusion has a base region and an annular side region located between the base region and the elevated gate such that the diffusions have increased lateral surface areas that support greater current levels for the diode finger, which enables gated diodes to be implemented with fewer fingers and therefore less layout area than equivalent conventional gated diodes that do not have elevated gates. The first gated diode can be implemented with an analogous second gated diode to form ESD-protection circuitry for the integrated circuit.

Abstract: An integrated circuit having a fingered capacitor with multiple metal fingers formed in inverted-trapezoid-shaped trenches in a multi-layer structure having a polish stop layer over an ultra-low-K dielectric layer over a low-K dielectric layer over a dielectric cap layer. The ultra-low-K dielectric layer reduces capacitance variations between the fingers, while the polish stop layer prevents metal height variations that would otherwise result from performing CMP directly on the ultra-low-K dielectric layer. The layered structure may include another low-K dielectric layer over the polish stop layer that provides a soft landing for the CMP. The polish stop layer may be removed after the CMP polishing and another ultra-low-K dielectric layer may be formed to encapsulate the tops of the metal fingers in the ultra-low-K dielectric material.

Abstract: An integrated circuit has a first gated diode with one or more diode fingers. Each diode finger has an elevated gate, an underlying p-type diffusion, and an underlying n-type diffusion. Each diffusion has a base region and an annular side region located between the base region and the elevated gate such that the diffusions have increased lateral surface areas that support greater current levels for the diode finger, which enables gated diodes to be implemented with fewer fingers and therefore less layout area than equivalent conventional gated diodes that do not have elevated gates. The first gated diode can be implemented with an analogous second gated diode to form ESD-protection circuitry for the integrated circuit.

Abstract: A method of forming a split gate memory cell structure using a substrate includes forming a gate stack comprising a select gate and a dielectric portion overlying the select gate. A charge storage layer is formed over the substrate including over the gate stack. A first sidewall spacer of conductive material is formed along a first sidewall of the gate stack extending past a top of the select gate. A second sidewall spacer of dielectric material is formed along the first sidewall on the first sidewall spacer. A portion of the first sidewall spacer is silicided using the second sidewall spacer as a mask whereby silicide does not extend to the charge storage layer.

Abstract: A method of forming a semiconductor device using a substrate includes forming a first select gate over the substrate, a charge storage layer over the first select gate, over the second select gate, and over the substrate in a region between the first select gate and the second select gate, wherein the charge storage layer is conformal, and a control gate layer over the charge storage layer, wherein the control gate layer is conformal. The method further includes performing a first implant that penetrates through the control gate layer in a middle portion of the region between the first select gate and the second select gate to the substrate to form a doped region in the substrate in a first portion of the region between the first select gate and the second select gate that does not reach the first select gate and does not reach the second select gate.

Abstract: A first doped region extends from a top surface of a substrate to a first depth. An implant into the first doped region forms a second doped region of a second conductivity type. The second doped region extends from the top surface to a second depth that is less than the first depth. A split gate NVM structure has select and control gates over the second doped region. A drain region of the second conductivity type is formed adjacent to the select gate. A source region of the second conductivity type is formed adjacent to the control gate. Angled implants into the second doped region form a third doped region of the first conductivity type under a portion of the select gate and a fourth doped region of the first conductivity type under a portion of the control gate. The drain and source regions adjoin the third and fourth regions.

Abstract: A method of forming a semiconductor device using a substrate includes forming a first select gate over the substrate, a charge storage layer over the first select gate, over the second select gate, and over the substrate in a region between the first select gate and the second select gate, wherein the charge storage layer is conformal, and a control gate layer over the charge storage layer, wherein the control gate layer is conformal. The method further includes performing a first implant that penetrates through the control gate layer in a middle portion of the region between the first select gate and the second select gate to the substrate to form a doped region in the substrate in a first portion of the region between the first select gate and the second select gate that does not reach the first select gate and does not reach the second select gate.

Abstract: A method of forming a split gate memory cell structure using a substrate includes forming a gate stack comprising a select gate and a dielectric portion overlying the select gate. A charge storage layer is formed over the substrate including over the gate stack. A first sidewall spacer of conductive material is formed along a first sidewall of the gate stack extending past a top of the select gate. A second sidewall spacer of dielectric material is formed along the first sidewall on the first sidewall spacer. A portion of the first sidewall spacer is silicided using the second sidewall spacer as a mask whereby silicide does not extend to the charge storage layer.

Abstract: A split gate memory array includes a first row having memory cells; a second row having memory cells, wherein the second row is adjacent to the first row; and a plurality of segments. Each segment includes a first plurality of memory cells of the first row, a second plurality of memory cells of the second row, a first control gate portion which forms a control gate of each memory cell of the first plurality of memory cells, and a second control gate portion which forms a control gate of each memory cell of the second plurality of memory cells. The first control gate portion and the second control gate portion converge to a single control gate portion between neighboring segments of the plurality of segments.

Abstract: A method of making a semiconductor device is described. The method comprises depositing a first polysilicon layer in a non-volatile memory (NVM) region and a logic region of a substrate. A first coating layer is deposited over the first polysilicon layer. The first coating layer and the first polysilicon layer are patterned to form a first gate in the NVM region. A memory cell is formed including the first gate. The first coating layer and the first layer of polysilicon in the logic region are removed and a logic gate polysilicon layer is deposited. The logic gate polysilicon layer is patterned to form a second gate in the logic region while the logic gate polysilicon layer is removed from the NVM region. Source/drain regions of the memory cell and the second gate are implanted concurrently.

Abstract: A method of forming a split gate memory cell structure using a substrate includes forming a gate stack comprising a select gate and a dielectric portion overlying the select gate. A charge storage layer is formed over the substrate including over the gate stack. A first sidewall spacer of conductive material is formed along a first sidewall of the gate stack extending past a top of the select gate. A second sidewall spacer of dielectric material is formed along the first sidewall on the first sidewall spacer. A portion of the first sidewall spacer is silicided using the second sidewall spacer as a mask whereby silicide does not extend to the charge storage layer.

Abstract: A dielectric layer is formed over the substrate in the capacitor region and the memory region and a select gate layer is formed over the dielectric layer. A select gate is formed over the memory region and a plurality of lines of electrodes over the capacitor region from the select gate layer. A charge storage layer is formed over the capacitor region and the memory region including over the select gate and the plurality of lines. A control gate layer is formed over the charge storage layer over the capacitor region and over the memory region. The control gate layer is patterned to form a control gate of a memory cell over the memory region and a first electrode of a capacitor over the capacitor region. The plurality of lines are connected to the capacitor region to form a second electrode of the capacitor.

Abstract: A method for forming a semiconductor device includes forming a select gate over a substrate and forming a charge storage layer and a control gate over the select gate. The charge storage layer and control gate overlap a first sidewall of the select gate and the charge storage layer is between the select gate and the control gate. A protective spacer is formed, wherein the protective spacer has a first portion adjacent a first sidewall of the charge storage layer and on the substrate, and the protective spacer is thinned. After thinning the protective spacer, a sidewall spacer is formed over the protective spacer, wherein the sidewall spacer has a first portion on the substrate, and the first portion of the protective spacer is between the first sidewall of the control gate and the first portion of the sidewall spacer.

Abstract: A charge-storing device includes a charge-storing layer including nanocrystals. The nanocrystals are formed by a deposition technique incorporating deuterated hydrides. The deuterated hydride can be used to form an amorphous semiconductor material that is annealed to form nanoparticles to be incorporated into the charge-storing layer.

Abstract: A first doped region extends from a top surface of a substrate to a first depth. An implant into the first doped region forms a second doped region of a second conductivity type. The second doped region extends from the top surface to a second depth that is less than the first depth. A split gate NVM structure has select and control gates over the second doped region. A drain region of the second conductivity type is formed adjacent to the select gate. A source region of the second conductivity type is formed adjacent to the control gate. Angled implants into the second doped region form a third doped region of the first conductivity type under a portion of the select gate and a fourth doped region of the first conductivity type under a portion of the control gate. The drain and source regions adjoin the third and fourth regions.

Abstract: A semiconductor device and a method for making the semiconductor device are provided. The semiconductor device includes a non-volatile memory cell having a gate dielectric and formed in a non-volatile memory well region; a first transistor type formed using a first gate oxide and formed in a first transistor well region; a second transistor type formed using a second gate oxide and formed in a second transistor well region; and a third transistor type formed using a third gate oxide and formed in a third transistor well region. The gate dielectric and the first and second gate oxides are formed from the same oxide stack. The first, second, and third transistor types include extension implants formed using a first implant dopant, and the non-volatile memory cell includes extension implants formed using a second implant dopant, where the first and second implant dopants are different.

Abstract: A method of making a semiconductor device is described. The method comprises depositing a first polysilicon layer in a non-volatile memory (NVM) region and a logic region of a substrate. A first coating layer is deposited over the first polysilicon layer. The first coating layer and the first polysilicon layer are patterned to form a first gate in the NVM region. A memory cell is formed including the first gate. The first coating layer and the first layer of polysilicon in the logic region are removed and a logic gate polysilicon layer is deposited. The logic gate polysilicon layer is patterned to form a second gate in the logic region while the logic gate polysilicon layer is removed from the NVM region. Source/drain regions of the memory cell and the second gate are implanted concurrently.