The present disclosure relates generally to the field of semiconductor devices and specifically to transistor circuits including fringeless transistors and methods of making the same.
Peripheral (i.e., driver) circuitry for a memory device includes multiple types of field effect transistors configurated to operate at different operating voltages. Providing field effect transistors that operate at different operating voltages at a high device density is a challenge.
According to an aspect of the present disclosure, a semiconductor structure comprising a first field effect transistor is provided. The first field effect transistor comprises a first active region having a pair of lengthwise sidewalls and a pair of widthwise sidewalls that contact sidewalls of, and are laterally surrounded by, a first portion of a trench isolation structure. The first active region comprises a first source region, a first drain region, and a first channel region located between the first source region and the first drain region. A first gate structure including a first gate dielectric, a first gate electrode, a first planar dielectric spacer plate, and a first conductive gate cap structure overlies the first channel region. The first gate dielectric and the first gate electrode contact a sidewall of a protruding region of the first portion of the trench isolation structure that laterally extends along a first horizontal direction. The first planar dielectric spacer plate contacts a first portion of a top surface of the first gate electrode. The first conductive gate cap structure comprises a first segment that contacts a second portion of the top surface of the first gate electrode, a second segment that overlies the first planar dielectric spacer plate, and a connecting segment that contacts a first sidewall of the first planar dielectric spacer plate and connecting the first segment and the second segment.
According to another aspect of the present disclosure, a method of forming a semiconductor structure is provided. The method comprises: forming a first gate dielectric layer and a semiconductor gate material layer over a semiconductor material layer; forming a trench isolation structure through the semiconductor gate material layer and the first gate dielectric layer, wherein patterned portions of the semiconductor gate material layer and the first gate dielectric layer comprise a stack of a first gate dielectric plate and a first gate electrode material plate that is laterally surrounded by a first portion of the trench isolation structure; forming a planar dielectric spacer layer over the first gate electrode; physically exposing a top surface of a portion of the first semiconductor gate material layer by patterning the planar dielectric spacer layer; and forming a first conductive gate cap structure on the physically exposed portion of the top surface of the first gate electrode material plate; and patterning the stack of the first gate dielectric plate and the first gate electrode material plate into a stack of a first gate dielectric and a first gate electrode.
According to yet another aspect of the present disclosure, a semiconductor structure comprising a first field effect transistor and a second field effect transistor is provided. The first field effect transistor and the second field effect transistor comprise a first active region and a second active region, respectively, wherein the first active region and the second active region contact sidewalls of, and are laterally surrounded by, a trench isolation structure, wherein a laterally-extending portion of the trench isolation structure is located between the first active region and the second active region. A stack of a first gate dielectric and a first gate electrode overlies a first channel region within the first active region and contacts a first sidewall of the laterally-extending portion of the trench isolation structure. A stack of a second gate dielectric and a second gate electrode overlies a second channel region within the second active region and contacts a second sidewall of the laterally-extending portion of the trench isolation structure. A conductive gate connection structure contacting a top surface of the first gate electrode, a top surface of the second gate electrode, and a portion of a top surface of the laterally-extending portion of the trench isolation structure, and comprising a pair of widthwise sidewalls that laterally extend along a first horizontal direction and a pair of lengthwise sidewalls that laterally extend along a second horizontal direction. Lengthwise sidewalls of the first gate electrode and the second gate electrode are vertically coincident with the pair of lengthwise sidewalls of the conductive gate connection structure.
According to still another aspect of the present disclosure, a semiconductor structure comprises a first field effect transistor. The first field effect transistor comprises a first active region including a source region, a drain region and a channel region located between the source region and the drain region, a first gate dielectric overlying the active region, a first gate electrode overlying the first gate dielectric, and a trench isolation region surrounding the first active region, the first field effect transistor does not include a fringe region in which the first gate electrode extends past the active region in a horizontal direction which is perpendicular to the source region to the drain region direction, the first gate electrode does not overlie a portion of the trench isolation region, and an entire foot print of the first gate electrode is located over and within a lateral boundary of the first active region.
According to still another aspect of the present disclosure, a method of forming a semiconductor structure is provided. The method comprises: forming a gate dielectric layer and a semiconductor gate material layer over a semiconductor material layer; forming a trench isolation structure through the semiconductor gate material layer and the gate dielectric layer, wherein patterned portions of the semiconductor gate material layer and the gate dielectric layer comprise a first stack of a first gate dielectric plate and a first gate electrode material plate overlying a first active region of the semiconductor material layer and a second stack of a second gate dielectric plate and a second gate electrode material plate overlying a second active region of the semiconductor material layer; forming a conductive gate connection material layer over the first gate electrode material plate, the second gate electrode material plate, and the trench isolation structure; patterning the conductive gate connection material layer into a conductive gate connection structure; anisotropically etching portions of the first gate electrode material plate and the second gate electrode material plate that are not covered with the conductive gate connection structure, wherein patterned portions of the first gate electrode material plate and the second gate electrode material plate comprise a first gate electrode and a second gate electrode; and patterning the first gate dielectric plate and the second gate dielectric plate into a first gate dielectric and a second gate dielectric, respectively.
Embodiments of the present disclosure provide transistor circuits including fringeless transistors and methods of making the same, the various aspects of which are described below. Such high density transistor circuits including fringeless transistors may be employed in various applications such as sense amplifier and peripheral low voltage driver circuits of memory device, such as a three-dimensional memory array.
The drawings are not drawn to scale. Multiple instances of an element may be duplicated where a single instance of the element is illustrated, unless absence of duplication of elements is expressly described or clearly indicated otherwise. Ordinals such as “first,” “second,” and “third” are employed merely to identify similar elements, and different ordinals may be employed across the specification and the claims of the instant disclosure. The same reference numerals refer to the same element or similar element. Unless otherwise indicated, elements having the same reference numerals are presumed to have the same composition. As used herein, a first element located “on” a second element can be located on the exterior side of a surface of the second element or on the interior side of the second element. As used herein, a first element is located “directly on” a second element if there exist a physical contact between a surface of the first element and a surface of the second element.
As used herein, a “layer” refers to a material portion including a region having a thickness. A layer may extend over the entirety of an underlying or overlying structure, or may have an extent less than the extent of an underlying or overlying structure. For example, a layer may be located between any pair of horizontal planes between, or at, a top surface and a bottom surface of the continuous structure. A layer may extend horizontally, vertically, and/or along a tapered surface. A substrate may be a layer, may include one or more layers therein, and/or may have one or more layer thereupon, thereabove, and/or therebelow.
As used herein, a “layer stack” refers to a stack of layers. As used herein, a “line” or a “line structure” refers to a layer that has a predominant direction of extension, i.e., having a direction along which the layer extends the most.
As used herein, a “semiconducting material” refers to a material having electrical conductivity in the range from 1.0×10−6 S/cm to 1.0×105 S/cm. As used herein, a “semiconductor material” refers to a material having electrical conductivity in the range from 1.0×10−6 S/cm to 1.0×105 S/cm in the absence of electrical dopants therein, and is capable of producing a doped material having electrical conductivity in a range from 1.0 S/cm to 1.0×105 S/cm upon suitable doping with an electrical dopant. As used herein, an “electrical dopant” refers to a p-type dopant that adds a hole to a valence band within a band structure, or an n-type dopant that adds an electron to a conduction band within a band structure. As used herein, a “conductive material” refers to a material having electrical conductivity greater than 1.0×105 S/cm. As used herein, an “insulator material”, “insulating material” or a “dielectric material” refers to a material having electrical conductivity less than 1.0×10−6 S/cm. As used herein, a “heavily doped semiconductor material” refers to a semiconductor material that is doped with electrical dopant at a sufficiently high atomic concentration to become a conductive material, i.e., to have electrical conductivity greater than 1.0×105 S/cm. A “doped semiconductor material” may be a heavily doped semiconductor material, or may be a semiconductor material that includes electrical dopants (i.e., p-type dopants and/or n-type dopants) at a concentration that provides electrical conductivity in the range from 1.0×10−6 S/cm to 1.0×105 S/cm. An “intrinsic semiconductor material” refers to a semiconductor material that is not doped with electrical dopants. Thus, a semiconductor material may be semiconducting or conductive, and may be an intrinsic semiconductor material or a doped semiconductor material. A doped semiconductor material can be semiconducting or conductive depending on the atomic concentration of electrical dopants therein. As used herein, a “metallic material” refers to a conductive material including at least one metallic element therein. All measurements for electrical conductivities are made at the standard condition.
As used herein, a “field effect transistor” refers to any semiconductor device having a semiconductor channel through which electrical current flows with a current density modulated by an external electrical field. As used herein, a “channel region” refers to a semiconductor region in which mobility of charge carriers is affected by an applied electrical field. A “gate electrode” refers to a conductive material portion that controls electron mobility in the channel region by application of an electrical field. A “source region” refers to a doped semiconductor region that supplies charge carriers that flow through the channel region. A “drain region” refers to a doped semiconductor region that receives charge carriers supplied by the source region and passes through the channel region. A “source/drain region” may be a source region or a drain region. An “active region” collectively refers to a source region, a drain region, and a channel region of a field effect transistor. A “source extension region” refers to a doped semiconductor region that is a portion of a source region and having a lesser dopant concentration than the rest of the source region. A “drain extension region” refers to a doped semiconductor region that is a portion of a drain region and having a lesser dopant concentration than the rest of the drain region. An “active region extension” refers to a source extension region or a drain extension region.
Referring to
The semiconductor substrate 2 can include a substrate semiconductor layer 4 that includes a lightly doped semiconductor material portion, on which at least one field effect transistor can be formed. In one embodiment, the entirety of the semiconductor substrate 2 may be the substrate semiconductor layer 4. In another embodiment, the substrate semiconductor layer 4 may comprise an upper portion of the semiconductor substrate 2, such as doped well in a silicon wafer. The substrate semiconductor layer 4 may include a lightly doped semiconductor material including electrical dopants at an atomic concentration in a range from 1.0×1014/cm3 to 1.0×1018/cm3, such as from 1.0×1015/cm3 to 1.0×1017/cm3, although lesser and greater atomic concentrations can also be employed.
The semiconductor material of the substrate semiconductor layer 4 can be an elemental semiconductor material (such as silicon) or an alloy of at least two elemental semiconductor materials (such as a silicon-germanium alloy), or can be a compound semiconductor material (such as a III-V compound semiconductor material or a II-VI compound semiconductor material), or can be an organic semiconductor material. The thickness of the substrate semiconductor layer 4 can be in a range from 0.5 mm to 2 mm in case the semiconductor substrate 2 is a bulk semiconductor substrate. In case the semiconductor substrate 2 is a semiconductor-on-insulator substrate, the thickness of the substrate semiconductor layer 4 may be in a range from 100 nm to 1,000 nm, although lesser and greater thicknesses can also be employed.
Various doped wells (5, 6) can be formed in an upper portion of the semiconductor substrate 2 (e.g., in the substrate semiconductor layer 4). The various doped wells (5, 6) may include p-type wells 5 having a respective p-type doping and n-type wells 6 having a respective n-type doping. For example, the p-type wells 5 may include a first p-type well 6A, a second p-type well 5B, a third p-type well 5C, etc. The n-type wells 6 may include a first n-type well 6A, a second n-type well 6B, a third n-type well 6C, a fourth n-type well 6D, etc. The regions including the various doped wells (5, 6) may be employed to form various semiconductor devices. For example, the region including the first n-type well 6A may comprise a first p-type field effect transistor region 100 in which first p-type field effect transistors including p-doped source and drain regions are to be subsequently formed; the region including the first p-type well 5A may comprise a first n-type field effect transistor region 200 in which first n-type field effect transistors including n-doped source and drain regions are to be subsequently formed; the region including the second n-type well 6B may comprise a second p-type field effect transistor region 300 in which second p-type field effect transistors including p-doped source and drain regions are to be subsequently formed; the region including the second p-type well 5B may comprise a second n-type field effect transistor region 400 in which second n-type field effect transistors including n-doped source and drain regions are to be subsequently formed; the region including the third n-type well 6C may comprise a third p-type field effect transistor region 500 in which third p-type field effect transistors including p-doped source and drain regions are to be subsequently formed; and the region including the third p-type well 5C may comprise a third n-type field effect transistor region 600 in which third n-type field effect transistors including n-doped source and drain regions are to be subsequently formed. Optionally, the region including the fourth n-doped well 6D may comprise a first passive device region 700 in which a first passive device such as a resistor is subsequently formed. Optionally, a region in which the substrate semiconductor layer 4 is physically exposed may be employed for a passive device region, such as a second passive device region 800, in which a second passive device such as a capacitor is subsequently formed. For example, regions 100 and 200 may contain low voltage transistors, regions 300 and 400 may contain very low voltage transistors which operate at a lower voltage than the low voltage transistors, and regions 500 and 600 may contain high voltage transistors which operate at a higher voltage than the low voltage transistors.
The various device regions may be arranged in any pattern on a top surface of the semiconductor substrate 2. While the present disclosure is described employing an embodiment in which the direction of semiconductor channels (i.e., the direction of current flow in the channel regions of the field effect transistors) is parallel to a first horizontal direction hd1 and perpendicular to a second horizontal direction hd2, it is understood that the direction of the semiconductor channel may be oriented along any direction for each field effect transistor to be subsequently formed. The depth of each doped well (5, 6) and the dopant concentration in each doped well (5, 6) may be suitably selected. For example, the dopant concentration in each doped well (5, 6) may be in a range from 1.0×1014/cm3 to 1.0×1018/cm3, such as from 1.0×1015/cm3 to 1.0×1017/cm3, although lesser and greater atomic concentrations can also be employed. The depth of each well (5, 6) may be in a range from 50 nm to 2,000 nm, although lesser and greater depths may also be employed.
Referring to
A polish stop pad layer 23L and a semiconductor gate material layer 24L may be formed over the first and second gate dielectric layers (22L, 20L). The polish stop pad layer 23L may comprise any suitable sacrificial material, such as silicon nitride and/or a bilayer of silicon nitride and silicon oxide, which may be used as a polish stop. The semiconductor gate material layer 24L may comprise a heavily doped polysilicon layer. Optionally, the polish stop pad layer 23L may also be formed on top of the semiconductor gate material layer 24L. The thickness of layers (23L, 24L) may be in a range from 50 nm to 300 nm, such as from 100 nm to 200 nm, although lesser and greater thicknesses may also be employed.
Referring to
Referring to
Referring to
The remaining portions of the at least one trench fill material layer 8L filling the trenches 7 constitute trench isolation structures 8, which may be a continuous structure contacting the semiconductor material of the semiconductor substrate 2 with dielectric surfaces and providing electrical isolation between adjacent semiconductor devices to be subsequently formed. The trench isolation structures 8 include deep trench isolation structures 8D located in the deep trenches 7D and shallow trench isolation structures 8S located in the shallow trenches 7S.
Generally, a trench isolation structure 8 can be formed through the plates (23L, 24L) and the gate dielectric layers (22L, 20L). Patterned portions of the semiconductor gate material layer 24L and the first gate dielectric layer 22L comprise stacks of a gate dielectric plate 22 and a gate electrode material plate 24 that is laterally surrounded by a respective portion of the trench isolation structure 8.
Referring to
Referring to
An anisotropic etch process can be performed to remove unmasked portions of the planar semiconductor spacer layer 34L and the planar dielectric spacer layer 30L. Top surfaces of the plates 23 and the trench isolation structure 8 can be physically exposed in the third p-type field effect transistor region 500 and the third n-type field effect transistor region 600. In one embodiment, an opening through the planar semiconductor spacer layer 34L and the planar dielectric spacer layer 30L in the first p-type field effect transistor region 100 and in the first n-type field effect transistor region 200 may include an area of a portion of the shallow trench isolation structure 8S, an area of a portion of a first gate electrode material plate 24, and an area of a portion of another first gate electrode material plate 24.
Generally, the planar semiconductor spacer layer 34L and the planar dielectric spacer layer 30L can be patterned employing an etch process that employs an etch mask, such as a patterned photoresist layer. A portion of the top surface of the first semiconductor gate material layer 24L (comprising a portion of the top surface of a first semiconductor gate material plate 24) is physically exposed by patterning the planar semiconductor spacer layer 34L and the planar dielectric spacer layer 30L. The photoresist layer can be subsequently removed, for example, by ashing.
Referring to
A gate cap dielectric layer 50L can be subsequently deposited over the conductive gate cap layer 40L. The gate cap dielectric layer 50L includes a dielectric material, such as silicon nitride. The thickness of the gate cap dielectric layer 50L can be in a range from 20 nm to 100 nm, such as from 30 nm to 50 nm, although lesser and greater thicknesses may also be employed.
Referring to
A first anisotropic etch process can be performed to transfer the pattern in the first photoresist layer 55 through the gate cap dielectric layer SOL, the conductive gate cap layer 40L, the planar semiconductor spacer layer 34L, and portions of the plates 23 located outside the areas of the planar dielectric spacer layer 30L, which include portions of plates 23 located within the third p-type field effect transistor region 500 and the third n-type field effect transistor region 600. The planar dielectric spacer layer 30L, the second gate dielectric plate 20, and the trench isolation structure 8 can function as etch stop structures for the first anisotropic etch process. In case the planar dielectric spacer layer 30L, the second gate dielectric plate 20, and the trench isolation structure 8 comprise silicon oxide, the etch chemistry of the terminal step of the first anisotropic etch process can etch the semiconductor materials of the planar semiconductor spacer layer 34L and the plates 23 selective to silicon oxide.
Each patterned portion of the gate cap dielectric layer SOL comprises a gate cap dielectric 50. Each patterned portion of the conductive gate cap layer 40L comprises a conductive gate cap structure 40. Each patterned portion of the planar semiconductor spacer layer 34L comprises a planar semiconductor spacer plate 34.
A contiguous combination of a first gate cap dielectric 50, a first conductive gate cap structure 40, and a first planar semiconductor spacer plate 34 can be formed on a top surface of each gate electrode material plate 24 in the first p-type field effect transistor region 100 and/or in the first n-type field effect transistor region 200. In this case, the first conductive gate cap structure 40 can be formed on the physically exposed top surface of a portion of the first gate electrode material plate 24. According to an aspect of the present disclosure, a first conductive gate cap structure 40 in the first p-type field effect transistor region 100 or in the first n-type field effect transistor region 200 comprises a first segment that contacts portion of the top surface of an underlying gate electrode material plate 24; a second segment that overlies the first planar dielectric spacer layer 34L; and a connecting segment that contacts a first sidewall of the first planar dielectric spacer layer 34L and connecting the first segment and the second segment.
According to an aspect of the present disclosure, a portion of the first conductive gate cap structure 40 covers a portion of a top surface of an underlying portion of the shallow trench isolation structure 8, and a portion of a bottom surface of the first conductive gate cap structure 40 contacts the portion of the top surface of the underlying portion of the shallow trench isolation structure 8. A first sidewall of the first planar semiconductor spacer plate 34 overlies, and is vertically coincident with, the first sidewall of the planar dielectric spacer layer 30L, and contacts the connecting segment of the first conductive gate cap structure 40. The first planar semiconductor spacer plate 34 can be formed on a top surface of the planar dielectric spacer layer 30L while a semiconductor gate plate 24 (i.e., a portion of the semiconductor gate material layer 24L) is covered with the planar dielectric spacer layer 30L. The first conductive gate cap structure 40 is formed directly on the first planar semiconductor spacer plate 34. The first photoresist layer 55 can be subsequently removed, for example, by ashing.
Referring to
Referring to
Generally, stacks of a first gate dielectric plate 22 and a gate electrode material plate 24 can be patterned into a stack of a first gate dielectric 12 and a first gate electrode 14. The gate electrode material plate 24 is patterned into the gate electrode 14 by the second anisotropic etch process employing the photoresist layer 57 as a patterned etch mask. The first gate dielectric plate 22 and the planar dielectric spacer layer 30L can be patterned into the first gate dielectric 12 and a first planar dielectric spacer plate 30, respectively, by a same etch process such as the second anisotropic etch process.
A first planar dielectric spacer plate 30 covers a first portion of a top surface of the gate electrode 14 upon patterning the first gate electrode material plate 24 into the first gate electrode 14. A first portion of a top surface of the gate electrode 14 contacts a bottom surface of the first planar dielectric spacer plate 30. A first conductive gate cap structure 40 comprises a first segment that contacts a second portion of the top surface of the gate electrode 14 a second segment that overlies the first planar dielectric spacer plate 30, and a connecting segment that contacts a first sidewall of the first planar dielectric spacer plate 30 and connecting the first segment and the second segment.
Referring to
The anisotropic etch process may be extended to etch unmasked portions of the dielectric materials of the second gate dielectric plates 20 and the trench isolation structures 8 selective to the materials of the gate electrodes 14. In this case, the second gate dielectric plates 20 can be patterned into second gate dielectrics 10 (which may comprise portions of a composite silicon nitride/silicon oxide gate dielectrics (10, 13) for the high voltage transistors in regions 500 and 600), and the physically exposed top surfaces of the trench isolation structures 8 can be vertically recessed. In one embodiment, an outer sidewall of each second gate dielectric 10 can be vertically coincident with an outer sidewall of a respective one of the gate dielectric spacers 56. As used herein, a first surface and a second surface are vertically coincident with each other if the first surface and the second surface overlie or underlie each other, and are located within a same vertical plane. In one embodiment, the recessed portions of the top surfaces of the trench isolation structure 8 may be at, or about, the height of the top surfaces of the third doped wells (5C, 5D) in the third field effect transistor regions (500, 600).
In one embodiment, a first dielectric gate spacer 56 located within a first field effect transistor region (100 or 200) comprises an upper portion that laterally surrounds and contacts a first conductive gate cap structure 40 and the planar semiconductor spacer plate 34, and contacts a portion of a top surface of the first planar dielectric spacer plate 30. The first dielectric gate spacer 56 contacts a first sidewall of the first semiconductor spacer plate 34 that is vertically coincident with a first sidewall of the first planar dielectric spacer plate 30, and a second sidewall of the first planar semiconductor spacer plate 34 that is laterally offset from a second sidewall of the first planar dielectric spacer plate 34. An outer sidewall of the first dielectric gate spacer 56 can be vertically coincident with the second sidewall of the first planar dielectric spacer plate 30.
The first planar semiconductor spacer plate 34 can contact a top surface of the first planar dielectric spacer plate 30, can have a lesser area than the first planar dielectric spacer plate 30, and can contact a bottom surface of the second segment of the first conductive gate cap structure 40 that overlies the stack of the first planar dielectric spacer plate 30 and the first planar semiconductor spacer plate 34. A portion of the first conductive gate cap structure 40 covers a top surface of a first portion of the shallow trench isolation structure 8 that surrounds a portion of a first doped well (5A or 6A) that underlies a gate structure (12, 14, 30, 34, 40, 50) and the first gate dielectric spacer 56. As shown in
A first gate structure (12, 14, 30, 34, 40, 50) including a first gate dielectric 12, a first gate electrode 14, a first planar dielectric spacer plate 30, and a first conductive gate cap structure 40 overlies a first channel region 15 of a first (e.g., low voltage or very low voltage) field effect transistor in regions 100 and 200, as shown in
In one embodiment, the first gate dielectric 12 and the first gate electrode 14 contact a sidewall of a protruding region (i.e., a protruding segment) 8P2 of the portion of the trench isolation structure 8. The sidewall laterally extends along a first horizontal direction hd1. The first planar dielectric spacer plate 30 contacts a first portion of a top surface of the first gate electrode 14, and the first conductive gate cap structure 40 comprises a first segment that contacts a second portion of the top surface of the first gate electrode 14, a second segment that overlies the first planar dielectric spacer plate 30, and a connecting segment that contacts a first sidewall of the first planar dielectric spacer plate 30 and connecting the first segment and the second segment.
In one embodiment, the first gate dielectric 12 comprises a first sidewall that contacts the sidewall of the protruding region 8P2 of the first portion of the trench isolation structure 8. The first gate electrode 14 comprises a first sidewall that contacts the sidewall of the protruding region 8P2 of the first portion of the trench isolation structure 8. A second sidewall of the first gate dielectric 12 and a second sidewall of the first gate electrode 14 that laterally extend along the first horizontal direction hd1 contacts a sidewall of a lower portion of the first dielectric gate spacer 56. Additional sidewalls of the first gate dielectric 12 and the first gate electrode 14 contact additional sidewalls of the lower portion of the first dielectric gate spacer 56 that laterally extends along a second horizontal direction hd2 that is perpendicular to the first horizontal direction hd1.
A second gate structure (10, 13, 40, 50) including a second composite silicon nitride/silicon oxide gate dielectric (13, 10), a second gate electrode 40 (which comprises a second conductive gate cap structure 40) overlies a second channel region 17 of a second (e.g., high voltage) field effect transistor in regions 500 and 600, as shown in
Referring to
In one embodiment, configurations for increasing the breakdown voltage of field effect transistors may be employed in device regions in which high-voltage field effect transistors are formed such as the third field effect transistor regions (500, 600). In this case, the p-doped source/drain regions 65 may include inner p-doped source/drain regions 651 and outer p-doped source/drain regions 650 that are laterally spaced apart by an additional trench isolation structure 8 (e.g., deep trench isolation structure 8D), which may be disjoined from the trench isolation structure 8 (e.g., shallow trench isolation structure 8S) in the first field effect transistor regions (100, 200). Further, the n-doped source/drain regions 66 may include inner n-doped source/drain regions 661 and outer n-doped source/drain regions 660 that are laterally spaced apart by another additional trench isolation structure 8. Optionally, a well contact source/drain region 65W may be employed to facilitate biasing of a doped well.
In one embodiment, gate electrodes 14 located within the low and very low voltage field effect transistor regions (100, 200, 300, 400) may be doped with p-type dopants or n-type dopants to form doped gate electrodes (25, 26) that are doped with p-type dopants or n-type dopants. The doped gate electrodes (25, 26) include p-doped second gate electrodes 25 formed in the p-type field effect transistor regions (100, 300) and n-doped second gate electrodes 26 formed in the n-type field effect transistor regions (200, 400). Alternatively or in addition, the polysilicon gate electrodes 14 and/or heavily doped semiconductor (e.g., heavily doped polysilicon) conductive gate cap structures 40 may be silicided by forming a metal on the polysilicon 14 and annealing the metal to form a metal silicide on the exposed top surfaces of the polysilicon.
Generally, various field effect transistors having different gate dielectric thicknesses, different gate lengths (i.e., different lateral distances between a source region and a drain region), and different configurations can be formed in the various field effect transistor regions (100, 200, 300, 400, 500, 600).
Referring to
The contact-level dielectric layer 70 overlies and laterally surrounds each of the field effect transistors. In one embodiment shown in
The contact via structures (76A, 76G, 86A, 86G, 96A, 96G, 96R, 96C) comprise first source/drain region contact via structures 76A contacting source/drain regions (65, 66) within the first field effect transistor regions (100, 200), as shown in
Generally, a first field effect transistor can be formed in a first field effect transistor region (100 or 200). The first field effect transistor comprises a first active region having a pair of lengthwise sidewalls and a pair of widthwise sidewalls that contact sidewalls of and are laterally surrounded by a first portion of a trench isolation structure 8. The first active region comprises a first source region, a first drain region, and a first channel region located between the first source region and the first drain region. The first field effect transistor can comprise a first gate structure (12, 14, 25 or 26, 30, 34, 40, 50).
A second field effect transistor can be formed in a second field effect transistor region (300 or 400). The second field effect transistor comprises a second active region having a pair of lengthwise sidewalls and a pair of widthwise sidewalls that contact sidewalls of and are laterally surrounded by a second portion of the trench isolation structure 8. A second gate structure (12, 25 or 26) including a second gate dielectric 12 and a second gate electrode (25 or 26) overlies the second active region. The contact-level dielectric layer 70 overlies the first gate structure (12, 14, 25 or 26, 30, 34, 40, 50) and the second gate structure (12, 25 or 26). At least one gate contact structure (such as a second gate contact via structures 86G) is in contact with a portion of a top surface of the second gate electrode (25 or 26). An entirety of the top surface of the second gate electrode (25 or 26) that is not in contact with the at least one gate contact structure 86G is in contact with the contact-level dielectric layer 70.
The first exemplary structure can comprise an additional field effect transistor such as a third field effect transistor formed in a third field effect transistor region (500 or 600). The additional field effect transistor comprises an additional active region having a pair of lengthwise sidewalls and a pair of widthwise sidewalls that contact sidewalls of and are laterally surrounded by an additional portion of the trench isolation structure 8. The additional field effect transistor comprises an additional gate structure (10, 13, 40, 50) overlies the additional active region. The additional gate structure (10, 13, 40, 50) can include an additional composite gate dielectric comprising a silicon oxide sublayer 10 having a greater thickness than the first gate dielectric 12, and a silicon nitride sublayer 13, and an additional conductive gate cap structure 40 having a same thickness and a same material composition as the first segment of the first conductive gate cap structure 40. An entirety of a top surface of the silicon nitride portion 13 is in contact with a bottom surface of the additional conductive gate cap structure 40.
In one embodiment, the first exemplary structure may further comprise a passive device, which may be selected from a capacitor, a resistor, or any other passive device known in the art. The passive device comprises a layer stack including, from bottom to top, a first dielectric layer (such as another instance of a silicon oxide gate dielectric 12 and a silicon nitride portion 13), a second dielectric layer (such as a planar dielectric spacer plate 30), a semiconductor plate (such as a planar semiconductor spacer plate 34), and a metallic plate (such as a conductive gate cap structure 40). The second dielectric layer has a same material composition and a same thickness as the first planar dielectric spacer plate 30. The metallic plate has a same material composition and a same thickness as the first segment of the first conductive gate cap structure 40.
Referring to
Generally, at least one gate dielectric layer and at least one semiconductor gate material layer over a semiconductor material layer within the semiconductor substrate 2, and a trench isolation structure 8 can be formed through the at least one semiconductor gate material layer and the at least one gate dielectric layer. As shown in
The first stack (22A, 24A) and the second stack (22B, 24B) can be located within a same field effect transistor region such as the first n-type field effect transistor region 200. The trench isolation structure 8 comprises a frame portion 8F that laterally surrounds the first active region 51 and the second active region 52 continuously. A laterally-extending portion 8L of the trench isolation structure 8 can be located between the first active region 51 and the second active region 52.
Referring to
Referring to
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Referring to
Referring to
A first anisotropic etch process can be performed to transfer the pattern in the first photoresist layer 55 through the gate cap dielectric layer 50L, the conductive gate cap layer 40L, the planar semiconductor spacer layer 34L, and portions of the plates 23 located outside the areas of the planar dielectric spacer layer 30L located within the third p-type field effect transistor region 500 and the third n-type field effect transistor region 600. The planar dielectric spacer layer 30L, the second gate dielectric plate 20, and the trench isolation structure 8 can function as etch stop structures for the first anisotropic etch process. In case the planar dielectric spacer layer 30L, the second gate dielectric plate 20, and the trench isolation structure 8 comprise silicon oxide, the etch chemistry of the terminal step of the first anisotropic etch process can etch the semiconductor materials of the planar semiconductor spacer layer 34L and the silicon nitride plates 23 selective to silicon oxide.
Each patterned portion of the gate cap dielectric layer SOL comprises a gate cap dielectric 50. Each patterned portion of the conductive gate cap layer 40L comprises a conductive gate cap structure 40. Each patterned portion of the planar semiconductor spacer layer 34L comprises the planar semiconductor spacer plate 34. Each patterned portion of the gate electrode material plates 126 constitutes a gate electrode 116.
Generally, a first gate electrode material plate 126 can be provided over a first active region 51 and a second gate electrode material plate 126 can be provided over a second active region 52 that is spaced from the first active region by a portion 8L of the trench isolation structure 8. Portions of the first gate electrode material plate 126 and the second gate electrode material plate 126 can be anisotropically etched. Patterned portions of the first gate electrode material plate 126 and the second gate electrode material plate 126 comprise a first gate electrode 116 and a second gate electrode 116, respectively.
According to an aspect of the present disclosure, a sidewall of a conductive gate cap structure 40 can be formed adjacent to a sidewall of the planar semiconductor spacer layer 34L as formed at the processing steps of
A contiguous combination of a first gate cap dielectric 50, a first conductive gate cap structure 40, a first planar semiconductor spacer plate 34, and a pair of first gate electrodes 116 can be formed across a pair of active regions (51, 52) in the first n-type field effect transistor region 200. Generally, each first conductive gate cap structure 40 constitutes a conductive gate connection structure that provide an electrically conductive path between an underlying pair of first gate electrodes 116 overlying the pair of active regions (51, 52) separated by the trench isolation structure 8L. Thus, the conductive gate connection material layer which comprises the conductive gate cap layer 40L can be patterned into conductive gate connection structure which comprises the first conductive gate cap structures 40. The first photoresist layer 55 can be subsequently removed, for example, by ashing.
Referring to
Referring to
Subsequently, another anisotropic etch process may be optionally performed to pattern the gate dielectric plates 22 located within the first field effect transistor regions (100, 200). Portions of the gate dielectric plates 22 that do not underlie a gate electrode 126 can be etched, and remaining portions of the gate dielectric plates 22 in the first field effect transistor regions (100, 200) constitute gate dielectrics 12.
A stack of a first gate dielectric 12 and a first gate electrode 116 overlies a first channel region within the first active region 51 in a first field effect transistor region (100 or 200) and contacts a first sidewall of the laterally-extending portion 8F of the trench isolation structure 8. A stack of a second gate dielectric 12 and a second gate electrode 116 overlies a second channel region within the second active region 52 and contacts a second sidewall of the laterally-extending portion 8F of the trench isolation structure 8. A conductive gate connection structure (comprising the first conductive gate cap structure 40) contacts a top surface of the first gate electrode 116, a top surface of the second gate electrode 116, and a portion of a top surface of the laterally-extending portion 8F of the trench isolation structure 8. The conductive gate connection structure comprising the first conductive gate cap structure 40 comprises a pair of widthwise sidewalls that laterally extend along a first horizontal direction hd1 and a pair of lengthwise sidewalls that laterally extend along a second horizontal direction hd2.
The trench isolation structure 8 comprises a frame portion 8F that laterally surrounds the first active region and the second active region continuously. The conductive gate connection structure comprising the first conductive gate cap structure 40 comprises a first end portion and a second end portion that overlies and contacts a respective segment of a top surface of the frame portion 8F of the trench isolation structure 8. Lengthwise sidewalls of the first gate electrode 116 and the second gate electrode 116 are vertically coincident with the pair of lengthwise sidewalls of the conductive gate connection structure that laterally extend along the second horizontal direction hd2.
A first widthwise sidewall (extending along the first horizontal direction hd1) of the first gate dielectric 12 and a first widthwise sidewall (extending along the first horizontal direction hd1) of the first gate electrode 116 are vertically coincident with each other and contact a first sidewall of the laterally-extending portion 8L of the trench isolation structure 8. A first widthwise sidewall (extending along the first horizontal direction hd1) of the second gate dielectric 12 and a first widthwise sidewall (extending along the first horizontal direction hd1) of the second gate electrode 116 are vertically coincident with each other and contact a second sidewall of the laterally-extending portion 8L of the trench isolation structure 8.
A second widthwise sidewall (extending along the first horizontal direction hd1) of the first gate dielectric 12 and a second widthwise sidewall (extending along the first horizontal direction hd1) of the first gate electrode 116 are vertically coincident with each other and contact a first sidewall of the frame portion 8F of the trench isolation structure 8. A second widthwise sidewall (extending along the first horizontal direction hd1) of the second gate dielectric 12 and a second widthwise sidewall (extending along the first horizontal direction hd1) of the second gate electrode 116 are vertically coincident with each other and contact a second sidewall of the frame portion 8F of the trench isolation structure 8.
In one embodiment, the conductive gate connection structure comprises a metallic gate connection structure 40 having a first thickness over a predominant segment of the first gate electrode 116, over the laterally-extending portion 8L of the trench isolation structure 8, and over an entire area of the second gate electrode 116, and having a second thickness that is greater than the first thickness over a complementary segment of the first gate electrode 116.
Referring to
The anisotropic etch process may be extended to etch unmasked portions of the dielectric materials of the second gate dielectric plates 20 and the trench isolation structures 8 selective to the materials of the gate electrodes 116. The planar dielectric spacer plates 30 in the second field effect transistor regions (300, 400) can be collaterally etched during the anisotropic etch process. In this case, the second gate dielectric plates 20 in the third field effect transistor regions (500, 600) can be patterned into second gate dielectrics 10, and the physically exposed top surfaces of the trench isolation structures 8 can be vertically recessed. In one embodiment, an outer sidewall of each second gate dielectric 10 can be vertically coincident with an outer sidewall of a respective one of the gate dielectric spacers 56. In one embodiment, the recessed portions of the top surfaces of the trench isolation structure 8 may be at, or about, the height of the top surfaces of the third doped wells (5C, 6C) in the third field effect transistor regions (500, 600).
In one embodiment, a first dielectric gate spacer 56 located within a first field effect transistor region (100 or 200) comprises an upper portion laterally surrounding the conductive gate connection structure comprising first conductive gate cap structure 40, and four lower portions vertically extending between a horizontal plane including a top surface of frame portion 8F of the trench isolation structure 8 and a horizontal plane including top surfaces of the first active region and the second active region and contacting a respective lengthwise sidewall of one of the first gate electrode 116 and the second gate electrode 116.
Referring to
In one embodiment, configurations for increasing the breakdown voltage of field effect transistors may be employed in device regions in which high-voltage field effect transistors are formed such as the third field effect transistor regions (500, 600). In this case, the p-doped source/drain regions 65 may include inner p-doped source/drain regions 651 and outer p-doped source/drain regions 650 that are laterally spaced apart by an additional trench isolation structure 8, which may be disjoined from the trench isolation structure 8 in the first field effect transistor regions (100, 200). Further, the n-doped source/drain regions 66 may include inner n-doped source/drain regions 661 and outer n-doped source/drain regions 660 that are laterally spaced apart by another additional trench isolation structure 8. Optionally, a well contact source/drain region 65W may be employed to facilitate biasing of a doped well.
Referring to
The contact via structures (76A, 76G, 86A, 86G, 96A, 96G, 96R, 96C) comprise first source/drain region contact via structures 76A contacting source/drain regions (65, 66) within the first field effect transistor regions (100, 200), first gate contact via structures 76G contacting top surfaces of conductive gate cap structures 40 within the first field effect transistor regions (100, 200), second source/drain region contact via structures 86A contacting source/drain regions (65, 66) within the second field effect transistor regions (300, 400), second gate contact via structures 86G contacting the second gate electrodes (25, 26), third source/drain region contact via structures 96A contacting source/drain regions (65, 66) within the third field effect transistor regions (500, 600), and third gate contact via structures 96G contacting top surfaces of conductive gate cap structures 40 within the third field effect transistor regions (500, 600). Further, the contact via structures (76A, 76G, 86A, 86G, 96A, 96G, 96R, 96C) can comprise first passive device contact via structures 96R that contact first passive devices such as resistors, and second passive device contact via structures 96C that contact second passive devices such as capacitors.
Generally, various field effect transistors having different gate dielectric thicknesses, different gate lengths (i.e., different lateral distances between a source region and a drain region), and different configurations can be formed in the various field effect transistor regions (100, 200, 300, 400, 500, 600). A dielectric gate spacer 56 may overlie a periphery region of a source/drain region (65, 66) of field effect transistors in the second field effect transistor regions (300, 400), and contact sidewalls of a respective portion of the trench isolation structure 8.
The second exemplary structure can include a combination of a first field effect transistor and a second field effect transistor located in a first field effect transistor region (100 or 200). The first field effect transistor and the second field effect transistor comprise a first active region 51 and a second active region 52, respectively. The first active region and the second active region contact sidewalls of, and are laterally surrounded by, a trench isolation structure 8. A laterally-extending portion 8L of the trench isolation structure 8 is located between the first active region 51 and the second active region 52.
The second exemplary structure may comprise a third field effect transistor located in a second field effect transistor region (300 or 400). The third field effect transistor comprises: a third active region that is laterally surrounded by an additional portion of the trench isolation structure 8, a stack of a third gate dielectric 12 and a third gate electrode (116 or 115) having widthwise sidewalls contacting sidewalls of the additional portion of the trench isolation structure 8 and laterally extending along the first horizontal direction hd1, additional dielectric gate spacers 56 having a respective opening therethrough and contacting a respective subset of sidewalls of the additional portion of the trench isolation structure 8 and a respective lengthwise sidewall (which laterally extends along the second horizontal direction hd2) of the third gate electrode (116 or 115).
The first gate electrode 116 and the second gate electrode 116 do not contact the contact-level dielectric layer 70, and are spaced from the contact-level dielectric layer 70 by a first dielectric gate spacer 56 and a conductive gate connection structure (as embodied as a conductive gate cap structure 40). The third gate electrode (116 or 115) can have a same thickness as the first gate electrode 116 and the second gate electrode 116. A portion of a top surface of the third gate electrode (116 or 115) is in direct contact with the contact-level dielectric layer 70.
At least one gate contact structure (such as a first gate contact via structure 76G) extends through the contact-level dielectric layer 70 and contacts a top surface of the portion of the conductive gate connection structure comprising the conductive gate cap structure 40 which at least partially overlies the underlying first gate electrode 116, and at least one additional gate contact structure (such as a second gate contact via structure 86G) extends through the contact-level dielectric layer 70 and contacts a portion of a top surface of the third gate electrode 116. An entirety of the top surface of the third gate electrode 116 is in contact with the at least one additional gate contact structure or the contact-level dielectric layer 70.
The second exemplary structure can comprise an additional field effect transistor such as a fourth field effect transistor formed in a third field effect transistor region (500 or 600). The additional field effect transistor comprises an additional active region having a pair of lengthwise sidewalls and a pair of widthwise sidewalls that contact sidewalls of, and are laterally surrounded by, an additional portion of the trench isolation structure 8. The additional field effect transistor comprises an additional gate structure (10, 13, 40, 50) overlies the additional active region. The additional gate structure (10, 13, 40, 50) can include an additional composite gate dielectric (10, 13) comprising a silicon oxide sublayer 10 having a greater thickness than the first gate dielectric 12, and a silicon nitride sublayer 13, and an additional conductive gate cap structure 40 having a same thickness and a same material composition as the first segment of the first conductive gate cap structure 40. An entirety of a top surface of the silicon nitride sublayer 13 is in contact with a bottom surface of the additional conductive gate cap structure 40.
In one embodiment, the second exemplary structure may comprise a passive device, which may be selected from a capacitor, a resistor, or any other passive device known in the art. The passive device comprises a layer stack including, from bottom to top, a first dielectric layer (such as another instance of a silicon oxide gate dielectric 12 and a silicon nitride gate dielectric 13), a second dielectric layer (such as a planar dielectric spacer plate 30), a second semiconductor plate (such as a planar semiconductor spacer plate 34), and a metallic plate (such as a conductive gate cap structure 40). The first dielectric layer has a same material composition and a same thickness as the first gate dielectric 12. The first semiconductor plate may a same thickness as the first gate electrode (14, 25 or 26). The second dielectric layer has a same material composition and a same thickness as the first planar dielectric spacer plate 30. The metallic plate has a same material composition and a same thickness as the first segment of the first conductive gate cap structure 40.
Referring to
Generally, at least one gate dielectric layer and at least one semiconductor gate material layer over a semiconductor material layer within the semiconductor substrate 2, and a trench isolation structure 8 can be formed through the at least one semiconductor gate material layer and the at least one gate dielectric layer. Patterned portions of the at least one semiconductor gate material layer and the at least one gate dielectric layer comprise a first stack (22, 24) of a first gate dielectric plate 22 and a first gate electrode material plate 24 overlying a first active region of the semiconductor material layer and a second stack (22, 24) of a second gate dielectric plate 22 and a second gate electrode material plate 24 overlying a second active region of the semiconductor material layer. The first stack (22, 24) and the second stack (22, 24) can be located within a same field effect transistor region such as the first n-type field effect transistor region 200. The trench isolation structure 8 comprises a frame portion 8F that laterally surrounds the first active region and the second active region continuously. A laterally-extending portion 8L of the trench isolation structure 8 can be located between the first active region and the second active region. Optionally, masked ion implantation processes can be performed to dope any portion of the gate electrode material plates 24 with suitable conductivity types.
Referring to
Referring to
Referring to
Referring to
Referring to
Referring to
A stack of a first gate dielectric 12 and a first gate electrode 14 overlies a first channel region within the first active region 51 in a first field effect transistor region (100 or 200) and contacts a first sidewall of the laterally-extending portion 8F of the trench isolation structure 8. A stack of a second gate dielectric 12 and a second gate electrode 14 overlies a second channel region within the second active region 52 and contacts a second sidewall of the laterally-extending portion 8F of the trench isolation structure 8. A first conductive gate connection structure comprising the semiconductor gate cap structure 236 and the conductive gate cap structure 240 contacts a top surface of the first gate electrode 14, a top surface of the second gate electrode 14, and a portion of a top surface of the laterally-extending portion 8F of the trench isolation structure 8. The first conductive gate connection structure comprising the first conductive gate cap structure 240 comprises a pair of widthwise sidewalls that laterally extend along a first horizontal direction hd1 and a pair of lengthwise sidewalls that laterally extend along a second horizontal direction hd2. An entirety of a top surface of the first gate electrode 14 and an entirety of a top surface of the second gate electrode 14 contact a bottom surface of the conductive gate connection structure (236, 240), such as the bottom surface of the semiconductor gate cap structure 236.
The trench isolation structure 8 comprises a frame portion 8F that laterally surrounds the first active region 51 and the second active region 52 continuously. The first conductive gate connection structure comprising as a stack of a semiconductor gate cap structure 236 and a conductive gate cap structure 240 comprises a first end portion and a third end portion that overlies and contacts a respective segment of a top surface of the frame portion 8F of the trench isolation structure 8, as shown in
A first widthwise sidewall (extending along the first horizontal direction hd1) of the first gate dielectric 12 and a first widthwise sidewall (extending along the first horizontal direction hd1) of the first gate electrode 14 are vertically coincident with each other and contact a first sidewall of the laterally-extending portion 8L of the trench isolation structure 8. A first widthwise sidewall (extending along the first horizontal direction hd1) of the second gate dielectric 12 and a first widthwise sidewall (extending along the first horizontal direction hd1) of the second gate electrode 14 are vertically coincident with each other and contact a second sidewall of the laterally-extending portion 8L of the trench isolation structure 8.
A second widthwise sidewall (extending along the first horizontal direction hd1) of the first gate dielectric 12 and a second widthwise sidewall (extending along the first horizontal direction hd1) of the first gate electrode 14 are vertically coincident with each other and contact a first sidewall of the frame portion 8F of the trench isolation structure 8. A second widthwise sidewall (extending along the first horizontal direction hd1) of the second gate dielectric 12 and a second widthwise sidewall (extending along the first horizontal direction hd1) of the second gate electrode 14 are vertically coincident with each other and contact a second sidewall of the frame portion 8F of the trench isolation structure 8.
In one embodiment, the first conductive gate connection structure comprises a metallic gate connection structure includes the conductive gate cap structure 240 having a uniform thickness over the entirety of the first gate electrode 14 (which includes a predominant segment of the first gate electrode 14), over the laterally-extending portion 8L of the trench isolation structure 8, and over the entirety of the second gate electrode 14.
In one embodiment, the first conductive gate connection structure further comprises a semiconductor gate connection structure comprising the semiconductor gate cap structure 236 having a uniform thickness throughout and contacting top surfaces of the first gate electrode 14, the laterally-extending portion of the trench isolation structure 8L, and the second gate electrode 14. In one embodiment, the first conductive gate connection structure also comprises a metallic gate connection structure comprising the conductive gate cap structure 240 contacting an entirety of a top surface of the semiconductor gate connection structure and having a same area as the semiconductor gate structure.
According to an aspect of the present disclosure, second conductive gate connection structure can be provided within the second field effect transistor region (300 and/or 400). The second conductive gate connection structure comprises a stack of a second semiconductor gate cap structure 236 and a second conductive gate cap structure 240. The second semiconductor gate cap structure 236 comprises a first segment that contacts portion of the top surface of an underlying gate electrode 14; a second segment that overlies a planar dielectric spacer plate 34; and a connecting segment that contacts a first sidewall of the planar dielectric spacer plate 34 and connecting the first segment and the second segment.
Referring to
The anisotropic etch process may be extended to etch unmasked portions of the dielectric materials of the first gate dielectrics 12, the second gate dielectric plates 20 and the trench isolation structures 8 selective to the materials of the gate electrodes 14. The planar dielectric spacer plates 30 in the second field effect transistor regions (300, 400) can be collaterally etched during the anisotropic etch process. In this case, the second gate dielectric plates 20 in the third field effect transistor regions (500, 600) can be patterned into second gate dielectrics 10, and the physically exposed top surfaces of the trench isolation structures 8 can be vertically recessed. In one embodiment, an outer sidewall of each second gate dielectric 10 can be vertically coincident with an outer sidewall of a respective one of the gate dielectric spacers 56. In one embodiment, the recessed portions of the top surfaces of the trench isolation structure 8 may be at, or about, the height of the top surfaces of the third doped wells (5C, 6C) in the third field effect transistor regions (500, 600).
In one embodiment, a first dielectric gate spacer 56 located within a first field effect transistor region (100 or 200) comprises an upper portion laterally surrounding the conductive gate connection structure (comprising the stack of the semiconductor gate cap structure 236 and the conductive gate cap structure 240), and four lower portions vertically extending between a horizontal plane including a top surface of frame portion 8F of the trench isolation structure 8 and a horizontal plane including top surfaces of the first active region and the second active region and contacting a respective lengthwise sidewall of one of the first gate electrode 14 and the second gate electrode 14 and contacting a top surface of a respective one of the first active region and the second active region.
Referring to
In one embodiment, configurations for increasing the breakdown voltage of field effect transistors may be employed in device regions in which high-voltage field effect transistors are formed such as the third field effect transistor regions (500, 600). In this case, the p-doped source/drain regions 65 may include inner p-doped source/drain regions 651 and outer p-doped source/drain regions 650 that are laterally spaced apart by an additional trench isolation structure 8, which may be disjoined from the trench isolation structure 8 in the first field effect transistor regions (100, 200). Further, the n-doped source/drain regions 66 may include inner n-doped source/drain regions 661 and outer n-doped source/drain regions 660 that are laterally spaced apart by another additional trench isolation structure 8. Optionally, a well contact source/drain region 65W may be employed to facilitate biasing of a doped well.
Referring to
The contact via structures (76A, 76G, 86A, 86G, 96A, 96G, 96R, 96C) comprise first source/drain region contact via structures 76A contacting source/drain regions (65, 66) within the first field effect transistor regions (100 or 200), first gate contact via structures 76G contacting top surfaces of conductive gate cap structures 240 within the first field effect transistor regions (100 or 200), second source/drain region contact via structures 86A contacting source/drain regions (65, 66) within the second field effect transistor regions (300 or 400), second gate contact via structures 86G contacting the second gate electrodes (25, 26), third source/drain region contact via structures 96A contacting source/drain regions (65, 66) within the third field effect transistor regions (500, 600), and third gate contact via structures 96G contacting top surfaces of conductive gate cap structures 240 within the third field effect transistor regions (500, 600). Further, the contact via structures (76A, 76G, 86A, 86G, 96A, 96G, 96R, 96C) can comprise first passive device contact via structures 96R that contact first passive devices such as resistors, and second passive device contact via structures 96C that contact second passive devices such as capacitors.
Generally, various field effect transistors having different gate dielectric thicknesses, different gate lengths (i.e., different lateral distances between a source region and a drain region), and different configurations can be formed in the various field effect transistor regions (100, 200, 300, 400, 500, 600). A dielectric gate spacer 56 may overlie a periphery region of a source/drain region (65, 66) of field effect transistors in the second field effect transistor regions (300 or 400), and contact sidewalls of a respective portion of the trench isolation structure 8.
The third exemplary structure can include a combination of a first field effect transistor and a second field effect transistor located in a first field effect transistor region (100 or 200). The first field effect transistor and the second field effect transistor comprise a first active region 51 and a second active region 52, respectively. The first active region and the second active region contact sidewalls of, and are laterally surrounded by, a trench isolation structure 8. A laterally-extending portion 8L of the trench isolation structure 8 is located between the first active region 51 and the second active region 52.
The third exemplary structure may comprise a third field effect transistor located in a second field effect transistor region (300 or 400). The third field effect transistor comprises: a third active region that is laterally surrounded by an additional portion of the trench isolation structure 8, a stack of a third gate dielectric 12 and a third gate electrode 14 having widthwise sidewalls contacting sidewalls of the additional portion of the trench isolation structure 8 and laterally extending along the first horizontal direction hd1, additional dielectric gate spacers 56 having a respective opening therethrough and contacting a respective subset of sidewalls of the additional portion of the trench isolation structure 8 and a respective lengthwise sidewall (which laterally extends along the second horizontal direction hd2) of the third gate electrode 14.
A portion of the top surface of third gate electrode 14 of the third field effect transistor can be contacted by the contact-level dielectric material layer 70. An additional conductive gate cap structure comprising a stack of a semiconductor gate cap structure 236 and a conductive gate cap structure 240 can contact another portion of the top surface of the third gate electrode 14. The additional conductive gate cap structure can comprise a same set of materials as the conductive gate connection structure in the first field effect transistor region (100 and/or 200). At least one gate contact structure (such as a first gate contact via structure 76G) can vertically extend through the contact-level dielectric layer 70 and can contact a top surface of a conductive gate connection structure (236, 240) in the first field effect transistor region (100 and/or 200), and at least one additional gate contact structure (such as a second gate contact via structure 86G) can vertically extend through the contact-level dielectric layer 70 and can contact a top surface of the additional conductive gate cap structure (236, 240).
The first gate electrode 14 and the second gate electrode 14 do not contact the contact-level dielectric layer 70, and are spaced from the contact-level dielectric layer 70 by a first dielectric gate spacer 56 and a conductive gate connection structure comprising the conductive gate cap structure 240). The third gate electrode 14 can have a same thickness as the first gate electrode 14 and the second gate electrode 14. A portion of a top surface of the third gate electrode 14 is in direct contact with the contact-level dielectric layer 70.
At least one gate contact structure (such as a first gate contact via structure 76G) extends through the contact-level dielectric layer 70 and contacts a top surface of the conductive gate connection structure comprising the conductive gate cap structure 240, and at least one additional gate contact structure (such as a second gate contact via structure 86G) extends through the contact-level dielectric layer 70 and contacts a portion of a top surface of the third gate electrode 14. An entirety of the top surface of the third gate electrode 14 is in contact with the at least one additional gate contact structure or the contact-level dielectric layer 70.
The third exemplary structure can comprise an additional field effect transistor such as a fourth field effect transistor formed in a third field effect transistor region (500 or 600). The additional field effect transistor comprises an additional active region having a pair of lengthwise sidewalls and a pair of widthwise sidewalls that contact sidewalls of, and are laterally surrounded by, an additional portion of the trench isolation structure 8. The additional field effect transistor comprises an additional gate structure (10, 14, 236, 240) overlies the additional active region. The additional gate structure (10, 14, 236, 240) can include an additional gate dielectric 10 having a greater thickness than the first gate dielectric 12, an additional gate electrode 14 (which may have a same thickness as the first gate electrode 14, an additional semiconductor gate cap structure 236 having a same thickness and a same material composition as the first semiconductor gate cap structures 236, and an additional conductive gate cap structure 240 having a same thickness and a same material composition as the first conductive gate cap structure 240. An entirety of a top surface of the additional gate electrode 14 is in contact with a bottom surface of the additional semiconductor gate cap structure 236.
In one embodiment, the third exemplary structure may comprise a passive device, which may be selected from a capacitor, a resistor, or any other passive device known in the art. The passive device comprises a layer stack including, from bottom to top, a first dielectric layer (such as another instance of a gate dielectric 12), a first semiconductor plate (such as a gate electrode 14), a second dielectric layer (such as a planar dielectric spacer plate 30), a second semiconductor plate (such as a planar semiconductor spacer plate 34), a third semiconductor plate (such as a semiconductor gate cap structure 236), and a metallic plate (such as a conductive gate cap structure 240). The first dielectric layer has a same material composition and a same thickness as the first gate dielectric 12. The first semiconductor plate may a same thickness as the first gate electrode 14. The second dielectric layer has a same material composition and a same thickness as the first planar dielectric spacer plate 30. The third semiconductor plate has the same material composition and the same thickness as the first semiconductor gate cap structure 236 in the first field effect transistor region (100 and/or 200). The metallic plate has a same material composition and a same thickness as the first conductive gate cap structure 240 in the first field effect transistor region (100 and/or 200).
The polysilicon gate electrode 14 and semiconductor gate cap structure 236 resistance is reduced by including respective silicide regions 25S and 240 on their upper surfaces. The semiconductor gate cap structure 236 extends along the second horizontal direction hd2 between two adjacent transistor structures and acts as the common gate contact via structure 76G tap area. Furthermore, since both the underlying gate electrodes 14 and the overlying semiconductor gate cap structures 236 comprise polysilicon with a silicide cap structure, it becomes easier to tune the characteristics of the fringeless transistors which include only the underlying gate electrode 14 and the fringed transistors which include both the underlying gate electrodes 14 and the overlying semiconductor gate cap structures 236.
The transistor structures may be formed closer to each other (e.g., be separated by relatively small distance d2 along the second horizontal direction) and take up relatively less chip space. Thus, the overall chip size may be reduced.
Although the foregoing refers to particular preferred embodiments, it will be understood that the disclosure is not so limited. It will occur to those of ordinary skill in the art that various modifications may be made to the disclosed embodiments and that such modifications are intended to be within the scope of the disclosure. Where an embodiment employing a particular structure and/or configuration is illustrated in the present disclosure, it is understood that the present disclosure may be practiced with any other compatible structures and/or configurations that are functionally equivalent provided that such substitutions are not explicitly forbidden or otherwise known to be impossible to one of ordinary skill in the art. All of the publications, patent applications and patents cited herein are incorporated herein by reference in their entirety.
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