Abstract: A method for setting voltages in a flash memory for high temperature operating life (HTOL) testing is provided. The flash memory includes a substrate, a source, and a control gate. The method includes adjusting the voltages that are applied to the source, the control gate, and the substrate, such that there is no voltage difference between the control gate and the source, and no voltage difference between the control gate and the substrate. Specifically, adjusting the voltages includes setting the voltage that is applied to the source to a ground voltage, setting the voltage that is applied to the control gate to the ground voltage, and setting the voltage that is applied to the substrate to a power supply voltage.

Abstract: A method for setting voltages in a flash memory for high temperature operating life (HTOL) testing is provided. The flash memory includes a substrate, a source, and a control gate. The method includes adjusting the voltages that are applied to the source, the control gate, and the substrate, such that there is no voltage difference between the control gate and the source, and no voltage difference between the control gate and the substrate. Specifically, adjusting the voltages includes setting the voltage that is applied to the source to a ground voltage, setting the voltage that is applied to the control gate to the ground voltage, and setting the voltage that is applied to the substrate to a power supply voltage.

Abstract: A high voltage integrated circuit device includes a semiconductor substrate having a surface region with a contact region, which is coupled to a source/drain region. The device has a plasma enhanced oxide overlying the surface region, a stop layer overlying the plasma enhanced oxide, and a contact opening through a portion of the stop layer and through a portion of the plasma enhanced oxide layer. The contact opening exposes a portion of the contact region without damaging it. The device has a silicide layer overlying the contact region to form a silicided contact region and an interlayer dielectric overlying the silicided contact region to fill the contact opening and provide a thickness of material overlying the stop layer. An opening in the interlayer dielectric layer is formed through a portion of the thickness to expose a portion of the silicided contact region and expose a portion of the stop layer.

Abstract: A high voltage integrated circuit device includes a semiconductor substrate having a surface region with a contact region, which is coupled to a source/drain region. The device has a plasma enhanced oxide overlying the surface region, a stop layer overlying the plasma enhanced oxide, and a contact opening through a portion of the stop layer and through a portion of the plasma enhanced oxide layer. The contact opening exposes a portion of the contact region without damaging it. The device has a silicide layer overlying the contact region to form a silicided contact region and an interlayer dielectric overlying the silicided contact region to fill the contact opening and provide a thickness of material overlying the stop layer. An opening in the interlayer dielectric layer is formed through a portion of the thickness to expose a portion of the silicided contact region and expose a portion of the stop layer.