Transcript SiGe - NTU

SiGe
A complementary BiCMOS
technology with High Speed npn
and pnp SiGe:C HBTs
Abstract
• Demonstrate SiGe:C pnp HBTs in a complementary
bipolar CMOS flow with ft/fmax values of
80GHz/120GHz at BVceo=2.6v,ring oscillator delay
8.9ps
• Npn-noly BiCMOS ft/fmax has the value of
180GHz/185GHz , a ring oscillator delay 4.6ps
• Pnp-only BiCMOS produces peak ft/fmax values for pnp
devices of 115GHz/115GHz
Introduction
• The availability of both npn-and pnp-type bipolar transistors with
matched performance can significantly reduce the power
consumption of high speed bipolar circuits
• Optimization of heterojunction pnp transistors for operation at high
speed has to consider not only the effect of poorer transport
parameters of holes compared to electrons
• Careful profile design is required for pnp SiGe HBTs to minimize the
deleterious impact of valence band barriers before the onset of the
Kirk effect
• Si/Si(1-y)C(y) layers offer a band lineup that is more suited for pnp
HBTs than the Si/Si(1-x)Ge(x) system
• Carbon fraction needed for a sufficient gain enhancement would
lead to strain relaxation and precipitation during a typical final RTA
step in a BiCMOS process and constraints of the process flexibility
Si/SiGe pnp heterojunction bipolar
transistors
• (a) what is the problem to make a pnp
transitors using Si/SiGe heterojunction?
• (b) how to solve it using the Si/SiGe
heterojunction
• (c)is Si/SiC heterjunction better for pnp
HBT?why?
• (a) Si/SiGe pnp.
P
N
Eg  Ev
P
Ec
Ef
Is fixed.
C
E
B
If some SiGe diffuse to Emitter.
Si
SiGe
Current small !!
Plastic barrier
• We do not want
• Not only the effect of poorer transport
parameters of hole compared to
electrons.due to the band lineup in the
Si/SiGe system,careful profile design is
required for pnp SiGe HBT.to minimize the
deleterious impact of valence band
barriers before the onset of the kirk effect.
• (b)
• If control SiGe in base region
Is better !!
• (c)Si/SiC heterjunction is better for pnp HBT
EG  EC
Si/SiC layers offer a band lineup that is more suited for pnp
HBTs than the Si/SiGe System. However, a carbon fraction
needed for a sufficient gain enhancement would Lead to
strain relaxation and precipitation during a typical final RTA
step.
Introduction(2)
• A complementary bipolar (CBi)CMOS process with an isolated
SiGe:C pnp-HBT whose high speed performance significantly
exceeds all previously reported data.
• The performance gain of the pnp-HBTs is mainly due to a highly
tuned vertical doping profile taking full advantage of the reduced P
diffusion in the C-doped base combined with the special collector
construction of previously reported 200GHz npn transistors
• The construction allows one to integrate an isolated pnp into a
CMOS process easily ,while simultaneously minimizing collector
resistance and capacitance.
A key feature of both the npn and the pnp HBT process is the formation of the whole HBT
Structure in one active area without shallow trench isolation between the active emitter and
The collector contact region.This allows one to achieve low-capacitance isolation from
The substrate ,and low
collector resistance for both types of transistors.
Device fabrication and design
Schematic flow of the complementary BiCMOS process
Device parameter
The formation of the whole HBT structure in one active area without shallow
trench Isolation between the active emitter and the collector contact region.
This allows one to achieve low-capacitance isolation from the substrate and low
Collector resistance for both types of transistors.
Device results
Ico
Ibo
Ic
Ib
These devices have a current gain of 160 and 180 at V(be)=0.7v,and BV(CEO) values
of 2.0v and 2.6v for npn and pnp HBTs respectively
Peak values of 110-120 ghZ for
CBiCMOS both Pnp preparations exceed by a
factor Of 2 all previously reported
BiCMOS values for Pnp bipolar devices.
CBiCMOS
The lower peak ft of the CBiCMOS
pnp Compared to the pnp-only flow
is due To reduced collector
doping.(3c-32)
A lower base resistance and a
higher F(max) are obtained in the
CBiMOS Process,because the
base link region Is enhanced by the
npn emitter poly.
CBiCMOS
A minimum gate delay of 8.9ps was measured for npn CML ring oscillator of the CBiCMOS
Process,representing the best reported values for pnp based ROs so far.
The npn HBTs of the CBiCMOS flow reach ft/fmax values of 180GHz/185GHz and a gate
Delay of 4.6ps.
This performance is almost as high as that of the reference BiCMOS ,despite the changed
Emitter construction and the additional thermal budget within the CBiCMOS process.
Current gain
=Ic/Ib
Figs.7 and8 show the current gain and ft as a function of collector current at different
collector biases for the pnp HBTs.
The weak sensitivity of current gain and peak ft to the collector bias and the high Early
Voltage at low V(ce) indicate that valence band barrier effects are largely suppressed
before onset of the Kirk effect.
This was achieved by a careful profile design at the base-collector junction.
Conclusions
• This paper have demonstrated SiGe:C pnp
HBTs with ft/f(max) values exceeding
100GHz.High-speed pnp and npn devices
have been integrated into a complementary
bipolar CMOS process. This process is a
promising route to applications
simultaneously requiring low voltage,low
power, and high speed .
Reference
• 2003 IEDM
•
SiGe
• SiGe:C BiCMOS Technology with 3.6ps
Gate Delay
Abstract
• A high-speed SiGe:C HBT technology is presented that
combines a new extrinsic base construction with a
low resistance collector design to simultaneously
minimize base and collector resistances and base
collector capacitance
• A ring oscillator delay of 3.6ps per stage was achieved
• The HBTs demonstrate an f(t) of 190GHz,an f(max) of
243 GHz and a BV(CEO) OF 1.9V at an drawn emitter
size of 0.175*0.84 um^(2)
Introduction
•
•
•
•
SiGe BiCMOS technology is a strong contender for enabling communication
speeds inexcess of 100 Gb/s and wireless systems in the 100GHz range.
This has led to new device structures that reduce base and collector
resistance and to a vertical and lateral device scaling resulting in f(t) and
f(max) values above 200GHz
Here,we report on a high-speed SiGe:C HBT technology that combines a
new extrinsic base construction with a low resistance collector design to
simultaneously minimize base resistance, collector resistance and
base-collector capacitance.
(i)Gate delays of 3.6ps per stage are achieved for CML ring oscillators at a
differential voltage swing of 300mV (ii)The HBTs demonstrate of f(t) of 190
GHz an f(max) of 243 GHz and a BV(CEO) of 1.9v at an emitter size of
0.175*0.84um^(2).(iii)The high speed HBT module has been integrated in
a 0.25um CMOS platform, without altering any CMOS device characteristics.
Device fabrication
Process sequence for fabrication of the HBT module.
The key new device feature is the formation of an elevated extrinsic base region by
Selective epitaxial growth of B-doped Si after structuring the poly Si emitter.
The elevated extrinsic base is self-aligned to the active emitter to minimize
base resistance
A SEM cross section of the final emitter structure
The HBT stack and the collector contact are formed in one active area and no deep
Trenches are needed for device isolation to minimize R(C) AND C(BC)
The HBT without the elevated extrinsic base ,in this process the extrinsic base is
formed by ion implantation after emitter structuring.
Device results:
A. DC characteristics
Current gain=300 at V(BE)=0.7V
Gummel characteristics of HBTs with
elevated extrinsic base
The open-base E-C breakdown voltage BV(CEO)=1.9V
Common emitter output characteristics at constant base current
Device results:
B. RF characteristics
225
For reference HBTs with implanted extrinsic base(lines)
Due to reduced R(B) and
C(BC) for the devices with
elevated extrinsic base.
186
With elevated extrinsic base(lines with circles)
Both transistors have similar f(T) curves due to almost
Identical doping profiles in the active transistor region.
Ft(Ic)Fmax(Ic) curves of transistors with the elevated extrinsic base are compared with
Reference transistors with implanted extrinsic base
A further reduction of the base resistance was achieved by shrinking the drawn
emitter Width to 0.175um.As a result, f(max) increased to 243 GHz for the device with
Shrunk Emitter width.
Mason’s unilateral gain
With elevated extrinsic base
Deembedded small signal current gain h(21) and unilateral gain U vs frequency.f(t) and
f(max) were extrapolated at 30 GHz with -20dB decay per frequency decade. Two
Transistors in parallel were measured.
with elevated extrinsic base and different
Emitter dimensions
Implanted extrinsic base
This delay is shorter than all previously reported
Values for SiGe technologies
CML ring oscillator gate delay vs current per gate for oscillators with 53 stages and a
Differential voltage swing of 300mv.devices with elevated extrinsic base and different
Emitter dimensions( lines with circles) are compared with reference devices with
Implanted extrinsic base (solid line)
• The comparison of the gate delays for the two
different base contact technologies illustrates
the impact of individual device parameters.
Although both processes gave almost identical
transit frequencies f(t) for HBTs with 0.21um
emitter width, the gate delay decreased from
4.3ps for the devices with implanted extrinsic
base to 3.9ps for devices with elevated
extrinsic base. This gain in circuit speed is
mainly due to the reduction of R(B) and
C(BC),the further reduction of R(B) and C(BC)
due to shrinking the drawn emitter width to
0.175um led to the reduction of the gate delay to
3.6ps
Conclusions
• Ring oscillator gate delays of 3.6ps per stage
have been demonstrated in a SiGe:C BiCMOS
technology featuring HBTs with ft/f(max) of
190GHz/243GHz.The achieved reduction of the
stage delay was due to a new device
construction with reduced base resistance
and base-collector capacitance .This
performance further establishes the potential of
SiGe:C technology for communication speeds
exceeding 100Gb/s and 100GHz.
Reference
• IEDM 2003