A split gate nonvolatile memory cell which is highly scalable includes a cell formed in a triple well. A select transistor can have a source which also acts as the emitter of a lateral bipolar transistor. The lateral bipolar transistor operates as a charge injector. The charge injector may provide electrons for substrate hot electron injection of electrons onto the floating gate for programming.

A nonvolatile memory cell which is highly scalable includes a cell formed in a triple well. A pair of sources for a pair of cells on adjacent word lines each acts as the emitter of a lateral bipolar transistor. The lateral bipolar transistor of one cell operates as a charge injector for the other cell. The charge injector provides carriers for substrate hot carrier injection onto a floating gate.

A method of manufacturing wells comprises the step of providing a p-type substrate and then sequentially forming a p-well and n-well with low dosage in the p-type substrate. Thereafter, energy is used to dope n-type ions into the p-well. The triple well formed in the present invention has low dosage ions, hence the DRAM formed on the triple well in subsequent process can have a faster refresh time.

A triple poly nonvolatile memory cell which is highly scalable includes a cell formed in a triple well. A select transistor can have a source which also acts as the emitter of a lateral bipolar transistor. The lateral bipolar transistor operates as a charge injector. The charge injector may provide electrons for substrate hot electron injection of electrons onto the floating gate for programming. The select transistor may include a gate formed as a self-aligned sidewall spacer on said sense transistor.

The memory cell is formed in a body of a P-type semiconductor material forming a channel region and housing N-type drain and source regions at two opposite sides of the channel region. A floating gate region extends above the channel region. A P-type charge injection region extends in the body contiguously to the drain region, at least in part between the channel region and the drain region. An N-type base region extends between the drain region, the charge injection region, and the channel region. The charge injection region and the drain region are biased by special contact regions so as to forward bias the PN junction formed by the charge injection region and the base region. The holes thus generated in the charge injection region are directly injected through the base region into the body, where they generate, by impact, electrons that are injected towards the floating gate region.