Apparatus and other embodiments associated with high speed and high breakdown voltage MOS rectifier are disclosed. A Junction All Around structure, where a deep trench structure surrounds and encloses a P-N junction or a MOS structure, is created and applied in various rectifiers. In one embodiment, multiple deep trenches in concentric ring circles enclosed several horizontal P-N junctions in concentric ring circles. In another embodiment, an enclosed deep trench in ring circle surrounds a horizontal P-N junction, which results in a planar N-channel MOS during forward bias. This structure can be extended to multiple deep trenches with associated horizontal P-N junctions.

Apparatus and other embodiments associated with high speed and high breakdown voltage MOS rectifier are disclosed. A Junction All Around structure, where a deep trench structure surrounds and encloses a P-N junction or a MOS structure, is created and applied in various rectifiers. In one embodiment, an enclosed deep trench in ring shape surrounds a vertical MOS structure plus a shallow trench gate in the center to create a device with very high breakdown voltage and very low leakage current. This structure is extended to multiple deep trenches and shallow trenches alternating each other.

Apparatus and other embodiments associated with high speed and high breakdown voltage MOS rectifier are disclosed. A Junction All Around structure, where a deep trench structure surrounds and encloses a P-N junction or a MOS structure, is created and applied in various rectifiers. In one embodiment, an enclosed deep trench in ring shape surrounds a vertical MOS structure plus a shallow trench gate in the center to create a device with very high breakdown voltage and very low leakage current. This structure is extended to multiple deep trenches and shallow trenches alternating each other.

Semiconductor memory cells, array and methods of operating are disclosed. In one instance, a memory cell includes a bi-stable floating body transistor and an access device; wherein the bi-stable floating body transistor and the access device are electrically connected in series.

Semiconductor memory cells, array and methods of operating are disclosed. In one instance, a memory cell includes a bi-stable floating body transistor and an access device; wherein the bi-stable floating body transistor and the access device are electrically connected in series.

A three-dimensional production method for a functional element structure body according to the invention is a three-dimensional production method for a functional element structure body, which includes an electrical functional element section having a terminal and an insulating member provided on the periphery of the functional element section in a state where at least the terminal is exposed to the outside, and includes a layer formation step of forming one layer in a layer forming region by supplying a first flowable composition containing first particles for the functional element section from a first supply section, and supplying a second flowable composition containing second particles for the insulating member from a second supply section, a shaping step of shaping the functional element structure body by repeating the layer formation step, and a solidification step of performing solidification by applying energy to the first particles and the second particles in the layer.

Apparatus and other embodiments associated with high speed and high breakdown voltage rectifier are disclosed. A Junction All Around structure, where a deep trench structure surrounds and encloses a P-N junction or a MOS structure, is created and applied in various rectifiers. In one embodiment, multiple deep trenches in ring shape enclosed a vertical P-N junction. For each deep trench, a corresponding wider ring-shape P+ region is created on top of a N epi layer. This enclosed deep trench surrounding a vertical P-N junction and a thinner N epitaxial layer allow higher reverse bias voltage and low leakage current. In another embodiment, an enclosed deep trench in ring shape surrounds a horizontal P-N junction, which results in a planar N-channel MOS during forward bias. The structure can be extended to multiple deep trenches with associated horizontal P-N junctions. In a further embodiment, an enclosed deep trench in ring shape surrounds a vertical MOS structure plus a shallow trench gate in the center to create yet another device with very high breakdown voltage and very low leakage current. This structure can be extended to multiple deep trenches and shallow trenches as well.

Apparatus and other embodiments associated with high speed and high breakdown voltage rectifier are disclosed. A Junction All Around structure, where a deep trench structure surrounds and encloses a P-N junction or a MOS structure, is created and applied in various rectifiers. In one embodiment, multiple deep trenches in ring shape enclosed a vertical P-N junction. For each deep trench, a corresponding wider ring-shape P+ region is created on top of a N epi layer. This enclosed deep trench surrounding a vertical P-N junction and a thinner N epitaxial layer allow higher reverse bias voltage and low leakage current. In another embodiment, an enclosed deep trench in ring shape surrounds a horizontal P-N junction, which results in a planar N-channel MOS during forward bias. The structure can be extended to multiple deep trenches with associated horizontal P-N junctions. In a further embodiment, an enclosed deep trench in ring shape surrounds a vertical MOS structure plus a shallow trench gate in the center to create yet another device with very high breakdown voltage and very low leakage current. This structure can be extended to multiple deep trenches and shallow trenches as well.

A semiconductor memory cell includes a floating body region configured to be charged to a level indicative of a state of the memory cell selected from at least first and second states. A first region of the memory cell is in electrical contact with the floating body region. A second region of the memory cell is spaced apart from the first region and is also in electrical contact with the floating body region. A gate is positioned between the first and second regions. A back-bias region is configured to generate impact ionization when the memory cell is in one of the first and second states, and the back-bias region is configured so as not to generate impact ionization when the memory cell is in the other of the first and second states.

A semiconductor memory cell includes a floating body region configured to be charged to a level indicative of a state of the memory cell selected from at least first and second states. A first region of the memory cell is in electrical contact with the floating body region. A second region of the memory cell is spaced apart from the first region and is also in electrical contact with the floating body region. A gate is positioned between the first and second regions. A back-bias region is configured to generate impact ionization when the memory cell is in one of the first and second states, and the back-bias region is configured so as not to generate impact ionization when the memory cell is in the other of the first and second states.