Abstract: A priming system including a resilient chamber having flexible walls and a first check valve in a first fluid pathway between the resilient chamber and a fluid reservoir such that a fluid flows through the first check valve only in a direction from the fluid reservoir toward the resilient chamber and the fluid returns to the fluid reservoir through a second fluid pathway between the resilient chamber and the fluid reservoir upon compression of the walls of the resilient chamber.

Abstract: Within both a method for fabricating a split gate field effect transistor and the split gate field effect transistor fabricated employing the method, there is employed a patterned silicon nitride barrier dielectric layer formed covering a first portion of a floating gate and a first portion of a semiconductor substrate adjacent the first portion of the floating gate. Within the first portion of the semiconductor substrate there is eventually formed a source/drain region, and more particularly a source region, when fabricating the split gate field effect transistor. The patterned silicon nitride barrier dielectric layer inhibits when fabricating the split gate field effect transistor ion implant damage of the floating gate and oxidative loss of a floating gate electrode edge.

Abstract: Within both a split gate field effect transistor (FET) device and a method for fabricating the split gate field effect transistor (FET) device there is employed a doped polysilicon floating gate electrode having an central annular portion having a higher dopant concentration than a peripheral annular portion of the doped polysilicon floating gate electrode. The higher dopant concentration within the central annular portion of the doped polysilicon floating gate electrode provides enhanced programming speed properties of the split gate field effect transistor (FET) device. The lower dopant concentration within the peripheral annular portion of the doped polysilicon floating gate electrode provides enhanced erasing speed properties within the split gate field effect transistor (FET) device under certain circumstances of fabrication of the split gate field effect transistor (FET) device.

Abstract: Within both a method for fabricating a split gate field effect transistor and the split gate field effect transistor fabricated employing the method, there is employed a patterned silicon nitride barrier dielectric layer formed covering a first portion of a floating gate and a first portion of a semiconductor substrate adjacent the first portion of the floating gate. Within the first portion of the semiconductor substrate there is eventually formed a source/drain region, and more particularly a source region, when fabricating the split gate field effect transistor. The patterned silicon nitride barrier dielectric layer inhibits when fabricating the split gate field effect transistor ion implant damage of the floating gate and oxidative loss of a floating gate electrode edge.

Abstract: Within both a split gate field effect transistor (FET) device and a method for fabricating the split gate field effect transistor (FET) device there is employed a doped polysilicon floating gate electrode having an central annular portion having a higher dopant concentration than a peripheral annular portion of the doped polysilicon floating gate electrode. The higher dopant concentration within the central annular portion of the doped polysilicon floating gate electrode provides enhanced programming speed properties of the split gate field effect transistor (FET) device. The lower dopant concentration within the peripheral annular portion of the doped polysilicon floating gate electrode provides enhanced erasing speed properties within the split gate field effect transistor (FET) device under certain circumstances of fabrication of the split gate field effect transistor (FET) device.

Abstract: Within a method for fabricating a split gate field effect transistor (FET) within a semiconductor integrated circuit microelectronic fabrication, there is employed a sacrificial self aligned spacer layer which defines a control gate electrode channel within the split gate field effect transistor (FET). The sacrificial self aligned spacer layer is employed as part of an ion implantation mask employed for forming a source/drain region adjoining the control gate electrode channel within the split gate field effect transistor (FET). The sacrificial self aligned spacer layer is stripped from over the control gate electrode channel prior to forming over the control gate electrode channel a control gate electrode within the split gate field effect transistor.