Some embodiments include an integrated assembly having an active region which contains semiconductor material. The active region includes first, second and third source/drain regions within the semiconductor material, includes a first channel region within the semiconductor material and between the first and second source/drain regions, and includes a second channel region within the semiconductor material and between the second and third source/drain regions. The semiconductor material includes at least one element selected from Group 13 of the periodic table. A digit line is electrically coupled with the second source/drain region. A first transistor gate is operatively proximate the first channel region. A second transistor gate is operatively proximate the second channel region. A first storage-element is electrically coupled with the first source/drain region. A second storage-element is electrically coupled with the third source/drain region. Some embodiments include methods of forming integrated assemblies.

A semiconductor structure, a method for manufacturing a semiconductor structure, and a memory are provided. The semiconductor structure includes: a plurality of first semiconductor pillars, a plurality of second semiconductor pillars, a first support layer, and a storage structure. The plurality of first semiconductor pillars are arranged in an array in a first direction and in a second direction. Each of the first direction and the second direction is perpendicular to an extending direction of each first semiconductor pillar, and the first direction intersects with the second direction. The first support layer covers sidewalls of top portions of the plurality of first semiconductor pillars. Each second semiconductor pillar is arranged on a respective one of the plurality of first semiconductor pillars. The storage structure is arranged around at least sidewalls of the plurality of first semiconductor pillars and sidewalls of the plurality of second semiconductor pillars.

A capacitor structure is provided, which includes a contact layer, an insulating layer, a bottom conductive plate, a dielectric layer and a top conductive plate. The contact layer has first, second, third, fourth and fifth portions arranged from periphery to center. The insulating layer is disposed over the contact layer and has an opening exposing the contact layer. The bottom conductive plate is disposed in the opening and including first, second and third portions extending along a depth direction of the opening and separated from each other and in contact with the first, third and fifth portions of the contact layer, respectively. The dielectric layer is conformally disposed on the bottom conductive plate and in contact with the second and fourth portions of the contact layer. The top conductive plate is disposed on the dielectric layer. A method of manufacturing the capacitor is also provided.

A capacitor structure is provided, which includes a contact layer, an insulating layer, a bottom conductive plate, a dielectric layer and a top conductive plate. The contact layer has first, second, third, fourth and fifth portions arranged from periphery to center. The insulating layer is disposed over the contact layer and has an opening exposing the contact layer. The bottom conductive plate is disposed in the opening and including first, second and third portions extending along a depth direction of the opening and separated from each other and in contact with the first, third and fifth portions of the contact layer, respectively. The dielectric layer is conformally disposed on the bottom conductive plate and in contact with the second and fourth portions of the contact layer. The top conductive plate is disposed on the dielectric layer. A method of manufacturing the capacitor is also provided.

Certain aspects of the present disclosure provide a capacitor assembly, a stacked capacitor assembly, an integrated circuit (IC) assembly comprising such a stacked capacitor assembly, and methods for fabricating the same. One exemplary capacitor assembly generally includes a first array of trench capacitors and a second array of trench capacitors. The second array of trench capacitors may be disposed adjacent to and electrically coupled to the first array of trench capacitors. Additionally, the second array of trench capacitors may be inverted with respect to the first array of trench capacitors.

A method of forming a tier of an array of memory cells within an array area, the memory cells individually comprising a capacitor and an elevationally-extending transistor, the method comprising using two, and only two, sacrificial masking steps within the array area of the tier in forming the memory cells. Other methods are disclosed, as are structures independent of method of fabrication.

Certain aspects of the present disclosure provide a capacitor assembly, a stacked capacitor assembly, an integrated circuit (IC) assembly comprising such a stacked capacitor assembly, and methods for fabricating the same. One exemplary capacitor assembly generally includes a first array of trench capacitors and a second array of trench capacitors. The second array of trench capacitors may be disposed adjacent to and electrically coupled to the first array of trench capacitors. Additionally, the second array of trench capacitors may be inverted with respect to the first array of trench capacitors.

A method of manufacturing a capacitor structure includes the following. A first, second, third, fourth, fifth, sixth and seventh portions of a contact layer arrange from periphery to center. A first-conductive layer contacting the first portion forms in an opening. A first-dielectric layer contacting the second portion forms on the first-conductive layer. A second-conductive layer forms on the first-dielectric layer. A second-dielectric layer contacting the third portion forms on the second-conductive layer. A third-conductive layer contacting the fourth portion forms on the second-dielectric layer. A third-dielectric layer contacting the fifth portion forms on the third-conductive layer. A fourth-conductive layer contacting the second-conductive layer forms on the third-dielectric layer. A fourth-dielectric layer contacting the sixth portion forms on the fourth-conductive layer. A fifth-conductive layer contacting the seventh portion forms on the fourth-dielectric layer. A fifth-dielectric layer forms on the fourth-dielectric layer and the fifth-conductive layer.

Certain aspects of the present disclosure provide a capacitor assembly, a stacked capacitor assembly, an integrated circuit (IC) assembly comprising such a stacked capacitor assembly, and methods for fabricating the same. One exemplary capacitor assembly generally includes a first array of trench capacitors and a second array of trench capacitors. The second array of trench capacitors may be disposed adjacent to and electrically coupled to the first array of trench capacitors. Additionally, the second array of trench capacitors may be inverted with respect to the first array of trench capacitors.

Some embodiments include an integrated assembly having an active region which contains semiconductor material. The active region includes first, second and third source/drain regions within the semiconductor material, includes a first channel region within the semiconductor material and between the first and second source/drain regions, and includes a second channel region within the semiconductor material and between the second and third source/drain regions. The semiconductor material includes at least one element selected from Group 13 of the periodic table. A digit line is electrically coupled with the second source/drain region. A first transistor gate is operatively proximate the first channel region. A second transistor gate is operatively proximate the second channel region. A first storage-element is electrically coupled with the first source/drain region. A second storage-element is electrically coupled with the third source/drain region. Some embodiments include methods of forming integrated assemblies.