SEMICONDUCTOR DEVICE, THREE-DIMENSIONAL MEMORY AND FABRICATION METHOD OF SEMICONDUCTOR DEVICE

The present disclosure provides a semiconductor device, a three-dimensional memory and a fabrication method of the semiconductor device. The semiconductor device comprises a substrate, a plurality of gates on a first side of the substrate and extending parallelly in a first horizontal direction, a plurality of first contacts each on a corresponding one of the plurality of gates and extending along the first horizontal direction, and a plurality of second contacts on the first side of the substrate, each second contact extends along the first horizontal direction, and is located between adjacent two first contacts and between two corresponding gates.

TECHNICAL FIELD

The present disclosure relates to the technical field of semiconductor memory devices, in particular to a semiconductor device, a three-dimensional (3D) memory, and a fabrication method of the semiconductor device.

BACKGROUND

A 3D memory is a flash memory device with memory cells that are stacked in a three-dimensional form for a higher storage density per unit area comparing with a planar memory. The existing 3D NAND memory cell architectures are generally in a design of vertical channels and horizontal control gate layers, which can increase the integration level manyfold on a unit area wafer.

In a three-dimensional memory device fabricating process, with the increasing number of array layers, the size of a Complementary Metal Oxide Semiconductor (CMOS) chip has a greater influence on the final size of the entire chip, and there are higher requirements on the miniaturization of CMOS, so there is an increasing need for a capacitor structure with a higher capacitance density.

SUMMARY

The present disclosure provides a three-dimensional memory and a fabrication method thereof, so as to achieve a high-density capacitor structure of a semiconductor device and a three-dimensional memory device.

The present disclosure provides a semiconductor device which comprises a substrate, a plurality of gates, first contacts corresponding to a plurality of the gates, and a plurality of second contacts; a plurality of the gates are disposed on a surface of the substrate at intervals, with a spacing region between every two adjacent ones of the gates, and sources located in the spacing regions are disposed on the surface of the substrate, each of the gates comprises a connection face, and one of the first contacts is disposed on the connection face of each of the gates, and orthographic projections of the first contacts on the connection faces are strip-shaped, and a length extending direction of the first contacts is the same as a length direction of the gates; a plurality of the second contacts are disposed on the substrate, located in the spacing regions and connected with the sources, and the second contacts and the first contacts are the same in structure and are disposed in juxtaposition.

The present disclosure further provides a three-dimensional memory, comprising the semiconductor device and a memory array, wherein the semiconductor device and the memory array are electrically connected.

The present disclosure further provides a fabrication method of a semiconductor device, and the method comprises: providing a substrate; forming a plurality of gates and sources on the substrate, with a spacing region between every two ones of the gates, each spacing region being provided with one of the sources, wherein the gates comprising connection faces; forming a contact on the connection face of each of the gates and on the substrate within each of the spacing regions, orthographic projections of the contact on the substrate being strip-shaped, and a length extending direction of the contact being the same as a length direction of the gates.

DETAILED DESCRIPTION

The technical schemes in the implementations of the present disclosure will be described below clearly and completely with reference to the figures in the implementations of the present disclosure. Apparently, the described implementations are merely part of possible implementations of the present disclosure, rather than all implementations. Based on the implementations in the present disclosure, all other implementations obtained by those of ordinary skill in the art without creative work shall fall in the protection scope of the present disclosure.

The existing three-dimensional memory comprises a memory array and a periphery circuit. Memory transistors that are serial in a vertical direction on a lateral substrate are formed in the memory array, and extend in the vertical direction with respect to the substrate. The periphery circuit may be interpreted as a periphery device of the memory, i.e., may be a semiconductor device, which comprises any suitable digital, analog and/or hybrid signal periphery circuit for facilitating memory operation. For example, the periphery device may comprise one or more of a page buffer, a decoder (e.g., a row decoder and a column decoder), a sensing amplifier, a driver, a charge pump, a current or voltage reference, or any active or passive components (e.g., a transistor, a diode, a resistor, or a capacitor) in a circuit. In some fabricating process, the complementary metal oxide semiconductor (CMOS) technology is generally used to form the semiconductor device. An interlayer dielectric (ILD) layer of the semiconductor device formed by such fabrication process can be relatively thin.

The present disclosure provides a semiconductor device, and a three-dimensional memory comprising the semiconductor device and a memory array, and the semiconductor device is electrically connected with the memory array. Referring toFIGS.1and2, the semiconductor device in the implementations of the present disclosure comprises a substrate10, a plurality of gates12, first contacts14corresponding to a plurality of the gates12, and a plurality of second contacts16.

A plurality of the gates12are disposed on a surface101of the substrate10at intervals, with a spacing region102between every two adjacent ones of the gates12, and sources (not shown) located in the spacing regions102are disposed on the surface101of the substrate10.

Each of the gates12comprises a connection face121, and one of the first contacts14is disposed on the connection face121of each of the gates12, and orthographic projections of the first contacts14on the connection faces121are strip-shaped, and a length extending direction of the first contacts14is the same as a length direction of the gates12.

A plurality of second contacts16are disposed on the substrate10, located in the spacing regions102and connected with the sources (not shown). The second contacts16and the first contacts14can have similar structures and can be arranged in parallel.

As shown inFIG.2, particularly, the semiconductor device is a periphery circuit that provides electrical connection to the three-dimensional memory; each gate12is led out through one first contact14to achieve electrical connection; and each source is connected with one of the second contacts16. An ILD layer (not shown) is formed on the substrate10and covers surfaces of the gates12and the substrate10, and the first contacts14and the second contacts16are formed within the ILD layer. In a width direction of the gates12, an orthographic projection of each of the first contacts14and the second contacts16is rectangular, that is, the first contacts14and the second contacts16are in a rectangular plate body shape as viewed perpendicular to a length direction of the gates. The ILD layer is thinner in thickness to better facilitate formation of the first contacts14and the second contacts16in a plate shape form. In the same unit area, the first contacts14and the second contacts16are in a plate shape, rather than in a dot matrix form, to make the area of the first contacts14and the second contacts16increase, so that the capacitance provided by them within the semiconductor device is increased.

Further, as shown inFIG.5, cross sections of the first contacts14in the width direction of the gates12are trapezoids, and the top sides A of the trapezoids are connected with the connection faces of the gates12. Particularly, with reference toFIG.1, the width direction of the gates12is interpreted as an X direction; the length direction of the gates12is a Y direction; a plurality of the gates12are arranged at intervals in the X direction; and a plurality of the first contacts14are arranged at intervals in the X direction. As viewed in the X direction, the first contacts14present as rectangular plate bodies; while as viewed in the Y direction, the sections of the first contacts14are trapezoids, and the shorter top sides of the trapezoids are connected with the connection faces of the gates12. On the premise of ensuring connection performance, the contact area of the first contacts14with the gates12are ensured in the X direction, that is, the surface contact area of the first contacts14with the gates12is large enough. To ensure that the distance between the first contacts14and the second contacts16is decreased, the distance α between the first contacts14and the surface edges of the gates12is above about 50 to 70 nanometers, which ensures that the first contacts can contact with the surfaces of the gates accurately, and can also ensure that the distance between two contacts is decreased.

Further, the distance b between the second contacts16within the spacing regions102and the two gates12forming the spacing regions is about50to 70 nanometers, which can decrease the distance between every two contacts (the first contacts14and the second contacts16) and increase the capacitance. The structure of the second contacts16can be the same as that of the first contacts14. As viewed in the X direction, the second contacts16present as rectangular plate bodies; while as viewed in the Y direction, the sections of the second contacts16are trapezoids, and shorter top sides of the trapezoids are connected with the sources on the substrate10. The dimension c at the end of the second contacts16connecting with the sources on the substrate10are decreased in the X direction, thereby reducing the gate density, increasing the number of the second contacts per unit area, and further increasing the capacitance.

In the present disclosure, the first contacts14and the second contacts16present as rectangular plate bodies. Compared with the disposition form of multiple contacts, the area of the contacts is increased, thereby increasing the capacitance.

Further, the semiconductor device further comprises metal layers18that are formed on the surfaces of a plurality of the first contacts and a plurality of second contacts far away from the substrate and are used to electrically connect the first contacts14and the second contacts16with other devices of the memory. Particularly, the metal layers18comprise first metal layers and second metal layers that are stacked and spaced by insulating layers, and the first metal layers are connected with the second metal layers by through-holes.

A fabrication method of a semiconductor device provided by the present disclosure is introduced below in detail with reference to the foregoing semiconductor device. In other implementations, a semiconductor device obtained by the fabrication method of the semiconductor device may also be different from the semiconductor device of the foregoing implementations.

The present disclosure provides a fabrication method of a semiconductor device, which is characterized by comprising:

Referring toFIG.3, at operation S1, a substrate10is provided for supporting a device structure thereon. In this implementation, the material of the substrate10is monocrystalline silicon (Si). Of course, in other implementations, the material of the substrate10may be an element semiconductor, such as germanium (Ge); a compound semiconductor, such as silicon germanium (SiGe), silicon carbide (SiC), gallium arsenide (GaAs), gallium phosphide (GaP), indium phosphide (InP), indium arsenide (InAs) and/or indium antimonide (InSb); an alloy semiconductor, such as gallium arsenic phosphide (GaAsP), aluminum indium arsenide (AlInAs), aluminum gallium arsenide (AlGaAs), gallium indium arsenide (GaInAs), gallium indium phosphide (GaInP) and/or gallium indium arsenic phosphide (GaInAsP); or a combination thereof. Furthermore, the substrate10may be a “semiconductor on insulator” wafer.

Referring toFIG.4, at operation S2, a plurality of gates12and sources (not shown) are formed on the substrate10, with a spacing region102between every two ones of the gates12, and each spacing region102being provided with one of the sources, wherein the gates12comprise connection faces121. The material of the gates12may be silicon nitride (SixNy, e.g., SiN), amorphous silicon, polysilicon, aluminum oxide, or a combination thereof. The gates12may be formed by means of coating and etching or photomasking. Specifically, gate sacrificial layers are formed first, and will be replaced with metals to serve as the gates in a subsequent process.

Further, the operation of forming a plurality of the gates12and the sources on the substrate10further comprises forming an ILD layer (not shown) that covers the gates12and the sources on the substrate10.

Referring toFIG.5, at operation S3, a first contact14is formed on the connection face121of each of the gates12through masking and etching processes, and orthographic projections of the first contacts14on the connection faces121are strip-shaped, and a length extending direction of the first contacts14is the same as a length direction of the gates12. Also, the orthographic projections of the first contacts14on the connection faces121are within the orthographic projections of the gates12. The first contacts14may be made from W, Ru, Co, or other suitable conductive materials. The first contacts14may be formed by filling through-holes formed in the ILD layer. Specifically, the through-holes may be formed in the ILD layer by a mask in conjunction with an etching method, which will not be described in detail.

This implementation further comprises operation IV: forming a second contact16on the substrate10within each of the spacing regions102by masking and etching processes to make the second contacts16connect with the sources, wherein the second contacts16and the first contacts14are the same in structure and are disposed in juxtaposition. The second contacts16may be made from W, Ru, Co, or other suitable conductive materials. The second contacts16may be formed by filling through-holes formed in the ILD layer. Specifically, the through-holes may be formed in the ILD layer by a mask in conjunction with an etching method, which will not be described in detail.

It should be noted that, when forming the first contacts14, cross sections of the first contacts14in a width direction of the gates12are trapezoids, and top sides of the trapezoids are connected with the gates12; and in the width direction of the gates12, the orthographic projection of each of the first contacts14and the second contacts16is rectangular. In other implementations, the first contacts14and the second contacts15are formed simultaneously.

The fabrication method of the semiconductor device further comprises forming metal layers18that are formed on surfaces of a plurality of the first contacts14and a plurality of second contacts16far away from the substrate10and on the ILD layer, and drains corresponding to the sources are disposed on the metal layers18. The metal layers may be made from Cu, Al, Ru, Co, W, or other suitable conductive materials.

In the semiconductor device provided by the present disclosure, the orthographic projections of the first contacts on the connection faces of the gates are strip-shaped, and the length extending direction of the first contacts is the same as the length direction of the gates; the second contacts and the first contacts are the same in structure, and the individuals of the first contacts and the second contacts are embodied in a non-dot matrix form, so that the unit area of the contacts is increased, and the capacitance may be increased, for achieving a high density capacitor structure of the semiconductor device and the three-dimensional memory device.

The implementations of the present disclosure disclosed above should not limit the scope of the claims of the present disclosure. Those of ordinary skill in the art may understand that implementation of all or part of processes of the above implementations, and equivalent variations made according to the claims of the present disclosure still fall in the scope encompassed by the present disclosure.