The present invention relates to FinFET structures and, more particularly, relates to the formation of fins having conformal doping in a CMOS process flow.
FinFET devices and FinFET structures are nonplanar devices and structures typically built on a semiconductor on insulator (SOI) substrate. The FinFET devices are field effect transistors which may comprise a vertical semiconductor fin, rather than a planar semiconductor surface, having a single or double gate wrapped around the fin. In an effort to provide for continued scaling of semiconductor structures to continuously smaller dimensions while maintaining or enhancing semiconductor device performance, the design and fabrication of semiconductor fin devices and semiconductor fin structures has evolved within the semiconductor fabrication art.
The various advantages and purposes of the exemplary embodiments as described above and hereafter are achieved by providing, according to a first aspect of the exemplary embodiments, a. conformal doping process for FinFET devices including: forming a first plurality of fins on a semiconductor substrate; forming a first plurality of gates with each gate of the first plurality of gates wrapping around a central portion of at least one of the fins of the first plurality of fins so as to leave end portions of the first plurality of fins exposed, the first plurality of fins and first plurality of gates being for N-type FinFET devices (NFETs); forming a second plurality of fins on the semiconductor substrate; forming a second plurality of gates with each gate of the second plurality of gates wrapping around a central portion of at least one of the fins of the second plurality of fins so as to leave end portions of the second plurality of fins exposed, the second plurality of fins and second plurality of gates being for P-type FinFET devices (PFETs); conformally depositing an N-type dopant composition over the NFET first plurality of fins and the PFET second plurality of fins such that the N-type dopant composition is in direct contact with the NFET first plurality of fins and indirectly in contact with the PFET second plurality of fins; annealing the semiconductor substrate to drive in an N-type dopant from the N-type dopant composition into the NFET first plurality fins; stripping the N-type dopant composition from the NFET first plurality of fins and the PFET second plurality of fins; conformally depositing a P-type dopant composition over the NFET first plurality of fins and the PFET second plurality of fins such that the P-type dopant composition is in direct contact with the PFET second plurality of fins and indirectly in contact with the NFET first plurality of fins; annealing the semiconductor substrate to drive in a P-type dopant from the P-type dopant composition into the PFET second plurality fins; and stripping the P-type dopant composition from the NFET first plurality fins and the PFET second plurality of fins.
According to a second aspect of the exemplary embodiments, there is provided a conformal doping process for FinFET devices including: forming a first plurality of fins on a semiconductor substrate; forming a first plurality of gates with each gate of the first plurality of gates wrapping around a central portion of at least one of the fins of the first plurality of fins so as to leave end portions of the first plurality of fins exposed, the first plurality of fins and first plurality of gates being for N-type FinFET devices (NFETs); forming a second plurality of fins on the semiconductor substrate; forming a second plurality of gates with each gate of the second plurality of gates wrapping around a central portion of at least one of the fins of the second plurality of fins so as to leave end portions of the second plurality of fins exposed, the second plurality of fins and second plurality of gates being for P-type FinFET devices (PFETs); conformally depositing AsH3 over the NFET first plurality of fins and the PFET second plurality of fins such that the AsH3 is in direct contact with the NFET first plurality of fins and indirectly in contact with the PFET second plurality of fins; annealing the semiconductor substrate to drive in an As dopant from the AsH3 into the NFET first plurality fins; stripping the AsH3 from the NFET first plurality of fins and the PFET second plurality of fins; conformally depositing B2H6 over the NFET first plurality of fins and the PFET second plurality of fins such that the B2H6 is in direct contact with the PFET second plurality of fins and indirectly in contact with the NFET first plurality of fins; annealing the semiconductor substrate to drive in a B dopant from the B2H6 into the PFET second plurality fins; and stripping the B2H6 from the NFET first plurality fins and the PFET second plurality of fins.
According to a third aspect of the exemplary embodiments, there is provided a conformal doping process for FinFET devices including: forming a first plurality of fins on a semiconductor substrate; forming a first plurality of gates with each gate of the first plurality of gates wrapping around a central portion of at least one of the fins of the first plurality of fins so as to leave end portions of the first plurality of fins exposed, the first plurality of fins and first plurality of gates being for N-type FinFET devices (NFETs); forming a second plurality of fins on the semiconductor substrate; forming a second plurality of gates with each gate of the second plurality of gates wrapping around a central portion of at least one of the fins of the second plurality of fins so as to leave end portions of the second plurality of fins exposed, the second plurality of fins and second plurality of gates being for P-type FinFET devices (PFETs); conformally depositing a first dopant composition over one of the NFET first plurality of fins and the PFET second plurality of fins; stripping the first dopant composition from the other of the NFET first plurality of fins and the PFET second plurality of fins; conformally depositing a second dopant composition over the NFET first plurality of fins and the PFET second plurality of fins such that the second dopant composition is in direct contact with the other of the NFET first plurality of fins and the PFET second plurality of fins and indirectly in contact with the first dopant composition on the one of the NFET first plurality of fins and the PFET second plurality of fins; annealing the semiconductor substrate to drive in a first dopant from the first dopant composition into the one of the NFET first plurality fins and the PFET second plurality of fins and a second dopant from the second dopant composition into the other of the NFET first plurality of fins and the PFET second plurality of fins; stripping the second dopant composition from the NFET first plurality fins and the PFET second plurality of fins; and stripping the first dopant composition from the one of the NFET first plurality of fins and the PFET second plurality of fins.
The features of the exemplary embodiments believed to be novel and the elements characteristic of the exemplary embodiments are set forth with particularity in the appended claims. The Figures are for illustration purposes only and are not drawn to scale. The exemplary embodiments, both as to organization and method of operation, may best be understood by reference to the detailed description which follows taken in conjunction with the accompanying drawings in which:
Referring now to
In
Referring now to
Referring now to
Thereafter, a conformal layer of nitride 116 is deposited over the stripes of amorphous silicon 112, as shown in
The conformal layer of nitride 116 is conventionally etched to form sidewall spacers 118, as shown in
Using the spacers 118 as a mask, the substrate is etched to form fins 120 and stripes of oxide 122 on the fins 120 as shown in
Referring now to
Referring now to
Referring first to
Referring now to
The oxide layer 412 may be stripped from the NFET fins 408 by dilute hydrofluoric acid (HF) as now shown in
The photoresist 414 then may be removed, for example, by conventional oxygen (O2) ashing.
An N-type dopant composition 416 is then deposited on the NFET fins 408, the PFET fins 410 and the semiconductor substrate 402 as shown in
It is preferred that the N-type dopant composition 416 comprises AsH3 (also known as arsine). Plasma doping is a technique characterized by the implantation of energetic impurity ions that are generated by immersing the substrate into a plasma and applying a negative bias voltage—pulsed bias in general—to the substrate. The system consists of a chamber, an RF power and a high vacuum pumping system, a high voltage pulse supply and gas supply system. The plasma doping source is a gas mixture of AsH3, in the case of the preferred dopant composition, and helium gas. When the substrate is exposed to the plasma, the doping will be either impinging into or deposit onto the surface to achieve very shallow junction formation either in planar or vertical structure. The plasma doping will deposit layers of arsenic dopant on the fins.
The FinFET structure 400 then undergoes an anneal to drive in the N-type dopant, preferably the arsenic from the arsine deposition, into the NFET fins 408. The oxide layer 412 on the PFET fins 410 prevents the doping of the PFET fins 410 by the N-type dopant. The anneal is preferably a rapid thermal anneal at a temperature of about 1000 to 1050° C. for 1 to 2 seconds. After the anneal, the N-type dopant composition 416 may be stripped off the fins 408, 410, gate (not shown) and semiconductor substrate 402 using ammonium peroxide followed by dilute HF to remove the oxide layer 412 from the PFET fins 410.
The resulting structure is shown in
Now that the NFET fins 408 have been conformally doped, the PFET fins 410 may now be conformally doped.
Referring to
Referring now to
The oxide layer 420 may be stripped from the PFET fins 410 by dilute HF as now shown in
The photoresist 422 then may be removed, for example, by conventional oxygen (O2) ashing.
A P-type dopant composition 424 is then deposited on the NFET fins 408, the PFET fins 410 and the semiconductor substrate 402 as shown in
It is preferred that the P-type dopant composition 424 comprises B2H6 (also known as diborane). In this plasma doping process, the plasma doping source is a gas mixture of B2H6, in the case of the preferred dopant composition, and helium gas. When the substrate is exposed to the plasma, the doping will be either impinging into or deposit onto the surface to achieve very shallow junction formation either in planar or vertical structure. The plasma doping will deposit layers of boron dopant.
The FinFET structure 400 then undergoes an anneal to drive in the P-type dopant, preferably the boron from the diborane deposition, into the PFET fins 410. The presence of oxide layer 420 prevents the NFET fins 408 from being doped by the P-type dopant. The anneal is preferably a rapid thermal anneal at a temperature of 1000 to 1050° C. for 1 to 2 seconds. After the anneal, the P-type dopant composition 424 is stripped off the fins 408, 410, gate (not shown) and semiconductor substrate 402 using ammonium peroxide followed by dilute HF to remove the oxide layer 420 from the NFET fins 408.
The resulting structure is shown in
As a result of this first exemplary process, the NFET fins 408 and PFET fins 410 have both been conformally doped.
It should be understood that while the NFET fins 408 were conformally doped before the PFET fins 410 were doped, the process may be reversed so that the PFET fins 410 are doped first.
Referring first to
An N-type dopant composition 512 may be deposited on the NFET fins 508, the PFET fins 510 and the semiconductor substrate 402 as shown in
It is preferred that the N-type dopant composition 512 comprises AsH3 (arsine). The plasma doping may be performed as described previously with respect to the first exemplary embodiment.
Referring now to
The N-type dopant composition 512 may be removed from the exposed areas not covered by the photoresist 514. That is, the N-type dopant composition 512 may be removed from the PFET fins 510 and a portion of the semiconductor substrate 402. The N-type dopant composition 512 may also be removed from the gate (not shown). The resulting structure is shown in
The photoresist 514 then may be removed, for example, by conventional O2 ashing.
An oxide layer 516, for example, silicon oxide may be conformally deposited over the NFET fins 508, the PFET fins 510 and the semiconductor substrate 402 as shown in
Referring now to
The oxide layer 516 may be stripped from the PFET fins 510 by dilute HF as now shown in
The photoresist 518 then may be removed, for example, by conventional oxygen (O2) ashing.
A P-type dopant composition 520 is then deposited on the NFET fins 508, the PFET fins 510 and the semiconductor substrate 402 as shown in
It is preferred that the P-type dopant composition 520 comprises B2H6 (diborane). The plasma doping process for the P-type dopant composition 520 is preferably as described earlier with respect to the first exemplary embodiment.
The FinFET structure 500 then undergoes an anneal to drive in the N-type dopant, preferably the arsenic from the arsine deposition, into the NFET fins 508 and the P-type dopant, preferably the boron from the diborane deposition, into the PFET fins 510. The anneal is preferably a rapid thermal anneal at a temperature of about 1000 to 1050° C. for 1 to 2 seconds. After the anneal, the P-type dopant composition 520 is stripped off the fins 508, 510, gate (not shown) and semiconductor substrate 402 using ammonium peroxide followed by dilute HF to remove the oxide layer 516 from the NFET fins 508 and the gate (not shown). Lastly, the N-type dopant composition 512 is stripped off the NFET fins 508 using ammonium peroxide.
The resulting structure is shown in
As a result of this second exemplary process, the NFET fins 508 and PFET fins 510 have both been conformally doped.
It should be understood that while the N-type dopant composition was deposited first followed by the deposition of the P-type dopant composition, the process may be reversed so that the P-type dopant composition is deposited first followed by a protective oxide layer and then the N-type dopant composition. In this way, the FinFET structure may be annealed once to drive in the dopants in the NFET fins 508 and PFET fins 510 at the same time and conformally dope the NFET fins 508 and PFET fins 510.
After the NFET fins 408, 508 and the PFET fins 410, 510 have been conformally doped as described in the exemplary embodiments, the FinFET structures 400, 500 may undergo further processing to complete the FinFET structures 400, 500 including forming the sources/drains.
It will be apparent to those skilled in the art having regard to this disclosure that other modifications of the exemplary embodiments beyond those embodiments specifically described here may be made without departing from the spirit of the invention. Accordingly, such modifications are considered within the scope of the invention as limited solely by the appended claims.
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