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2002 SSDM Conference, September, Nagoya Submicron InP Bipolar Transistors: Scaling Laws, Technology Roadmaps, Advanced Fabrication Processes Mark Rodwell University of California, Santa Barbara [email protected] 805-893-3244, 805-893-3262 fax Applications of InP HBTs Optical Fiber Transceivers 40 Gb: InP and SiGe HBT both feasible ICs now available; market has vanished 80 & 160 Gb may come in time within feasibility for scaled InP HBT world may not need capacity for some time WDM might be better use of fiber bandwidth 1 mmWave Transmission 1 km Sea level 60-80 GHz, 120-160 GHz, 220-300 GHz Low atmospheric attenuation (weather permitting). High antenna gains (short wavelengths). 10 Gb/s transmission over 500 meters with 20 cm antennas needs 4 mW transmitter power Mixed-Signal ICs for Military Radar/Comms Log Transmission 0.1 0.01 1E-3 1E-4 1E-5 1E-6 0.0 0.2 0.4 0.6 Frequency, THz direct digital frequency synthesis, ADCs, DACs high resolution at very high bandwidths sought 0.8 1.0 How Do We Improve the Bandwidth of Bipolar Transistors ? kT 1 kT base collector C je Cbc Rex Rcoll 2f qI E qI E Thinner base, thinner collector higher f , but higher RbbCcb , RexCcb … what parameters are really important in HBTs ? how do we improve HBT performance ? How do we improve gate delay ? Gate Delay Determined by : Depletion capacitanc e charging through the logic swing VLOGIC Ccb Cbe,depletion IC Depletion capacitanc e charging through the base resistance Rbb Ccb Cbe,depletion Supplying base collector stored charge through the base resistance IC Rbb b c VLOGIC The logic swing must be at least VLOGIC kT 6 Rex I c q out out in in clock clock clock clock Delay not well correlated with f . VLOGIC I C Ccb Cbe,depl is 60% - 80% of total. High I C / Ccb is a key HBT design objective. Acollector TC Aemitter 2veffective Rex must be very low for low Vlogic at high J e Ccb VLOGIC VLOGIC IC 2VCE ,min InP logic barely faster tha n SiGe : need to design for clock speed, not f & f max Scaling Laws for fast HBTs Required proportion al change in HBT parameters in order to obtain a : 1 increase in bandwidth in an arbitrary circuit For mesa HBTs, but not trans ferred - substrate or undercut - mesa HBTs, the base contact resistivit y v ( - cm 2 ) must also scale as 2 Challenges with Scaling: Collector-base scaling Mesa HBT: collector under base Ohmics. Base Ohmics must be one transfer length → sets minimum size for collector Solution: reduce base contact resistivity → narrower base contacts allowed Solution: decouple base & collector dimensions transferred-substrate, undercut-mesa, or buried SiO2 in junction (SiGe) Emitter Ohmic Resistivity: must improve in proportion to square of speed improvements Current Density: self-heating, current-induced dopant migration, dark-line defect formation Loss of breakdown avalanche Vbr never less than collector bandgap (1.12 V for Si, 1.4 V for InP) ….sufficient for logic, insufficient for power Yield ! submicron HBT processes have progressively decreasing yield Technology Roadmaps for 40 / 80 / 160 Gb/s Low Ccb InP HBT structures transferred-substrate Allows deep submicron collector scaling Problems with heating at high J Low yield at deep submicron scaling undercut-collector emitter base contact undercut collector junction InGaAs collector InGaAs base InP collector collector contact Popular approach Uncertain yield at submicron geometries InGaAs subcollector InP subcollector SI substrate Narrow-mesa with ~1E20 carbon-doped base Conservative approach Still not viable for > 3000 transistors per IC Need improved device structures for high yield at 0.1 mm scaling Miguel Urteaga Unbounded Power Gain in Submicron InAlAs/InGaAs HBTs Transistor Gains, dB 40 Emitter 30 unbounded U U 0.3 x 18 mm2 U 20 MSG/MAG Power gain is high, but fmax can’t be determined Collector 10 H Ic = 5 mA, Vce = 1.1 V 0 10 1 10 -14 8 10 21 0.7 x 18.6 mm2 100 Frequency, GHz B12 / Ccb cancellati on terms 5 10 -3 -15 4 10 -3 -15 3 10 -3 6 10 2 10 -3 4 10 -15 1 10 -3 2 10 Ic = 1 Ic = 2 Ic = 3 Ic = 4 Ic = 5 -15 V =1.1 V ce 0 10 mA mA mA mA mA 100 Frequency (GHz) 150 Ic = 1 mA Ic = 2 mA Ic = 3 mA Ic = 4 mA Ic = 5 mA reduced ce 0 60 mS=1/17k negative conductance at 110 GHz -1 10 50 2 G12 2 C cbi Rbb negative G terms V =1.2 V 0 10 0 0 Int. Symp. Compound Semiconductors, Tokyo, Oct. 2001 Int. Journal High Speed Electronics and Systems, to be published 1000 Gc (S) Cc (Farads) Unbounded 45-170 GHz Unilateral power gain 200 -3 0 50 100 Frequency (GHz) 150 200 Capacitance modulation & negative resistance observed: Gunn-like or IMPATT effects ? Miguel Urteaga Collector velocity modulation: Ccb cancellation and negative resistance c Tcoll / 2velectron 0.3 μm /( 2 3 105 cm/s ) 0.5 ps Ccbx Ccbi Ycb Rbb B d j c sin( c ) I C , DC e Ycb dVcb c C Cbe,depl Ix gmb Rex re=1/gm d d cos( c ) sin( c ) Gcb I C , DC c c dVcb d c sin( c ) I x e j c c 1 d c d sin 2 ( c ) Ceq I C , DC dVcb d c c -3 2 10 -3 -3 cb 1 10 Real Part: Collector-Base Conductance 0 10 -1 10 0 -3 -2 10 -3 -3 10 -3 negative Ycb: 0-700 GHz (340 mS=1/3000 at 120 GHz) 0 100 200 300 400 500 600 700 -Ic*d(tau_c)/dVcb= -Ccb,cancellation=-1 fF 3 10 equivalent capacitance, B / omega, Farads collector-base conductance, Siemens -Ic*d(tau_c)/dVcb= -Ccb,cancellation=-1 fF E 1 10 -15 Equivalent Negative Capacitance, B / cb 5 10 -16 0 -5 10 -16 -1 10 -15 equivalent negative Ccb: starts decreasing at ~150 GHz reaches zero at 370 GHz 0 100 200 300 400 500 Frequency, GHz 600 700 Frequency, GHz If Ccb cancellation is observed, there must also be an associated negative resistance 2nd Hypothesis: weak IMPATT effects in the collector H Tcoll / 2vhole 0.3 μm /( 2 5 10 4 cm/s ) 3 ps Ccbx Ycb Rbb C gmb re=1/gm Rex IMPATT conductance, Siemens -Ic*d(tau_c)/dVcb= -Ccb,cancellation=-1 fF E Again : Ccb A Tc I c total Vcb at low frequencie s -4 Real Part: Collector-Base Conductance 3 10 -4 2 10 -4 1 10 -4 0 10 -1 10 negative conductance: 83-166 GHz (70 mS=1/14,000 at 120 GHz) 0 -4 0 50 100 150 Frequency, GHz 200 250 cb Ix sin( c ) sin( H ) 1 Me j H I x e j c c H -Ic*d(tau_c)/dVcb= -Ccb,cancellation=-1 fF Cbe,depl 4 10 dM j h sin( H ) e Ycb I C , DC H dVcb MPATT capacitance, B / omega, Farads Ccbi B Miguel Urteaga 4 10 -16 2 10 -16 Equivalent Negative Capacitance, B / 12 0 -2 10 -16 -4 10 -16 -6 10 -16 -8 10 -16 -1 10 -15 equivalent negative Ccb: starts decreasing at ~50 GHz reaches zero at 166 GHz 0 50 100 150 Frequency, GHz 200 IMPATT effect also produces both capacitance cancellation and negative resistance 250 Deep Submicron Bipolar Transistors for 140-220 GHz Amplification Transistor Gains, dB 30 unbounded U U U 20 MSG/MAG 10 H 21 0 10 100 1000 Frequency, GHz 8 6 4 S21, dB Miguel Urteaga raw 0.3 mm transistor: 6-11 dB power gain @ 200 GHz 40 2 -2 1-transistor amplifier: 6.3dB @ 175 GHz -4 140 150 0 160 170 180 190 200 210 220 Frequency, GHz 10 gain, dB UCSB 0 -10 -20 -30 140 3-transistor amplifier: 8 dB @ 195 GHz 150 160 170 180 190 Frequency (GHz) 200 210 220 Mattias Dahlstrom (UCSB) Amy Liu (IQE) Wideband Mesa InP/InGaAs/InP DHBTs 30 500 Ohm/square base sheet resistance Pd/Ti/Pd/Au base Ohmic contacts < 10-7 Ohm-cm2 base contact resistance 1 mm base contacts, 0.5 mm emitter junction 0.7 mm emitter contact 25 21 Gain (dB) H , U 2000 Å InP collector 300 Å InGaAs base 8E19 to 5E19 graded C base doping InAlAs/InGaAs base-collector grade. UCSB / IQE 20 282 GHz f >450 GHz fmax, 15 480 GHz 10 5 Vce=1.7 V J=3.7E5 A/cm2 0 7.5 V Breakdown 282 GHz f , > 450 GHz fmax , operation to 500 kA/cm2 at 1.7 volts Rbb is low, Ccb needs further reduction 10 10 11 10 Frequency (Hz) 10 12 87 GHz HBT master-slave latch UCSB PK Sundararajan, Zach Griffith InAlAs /InGaAs/InP MESA DHBT 400 Å base, 2000 Å collector, 9 V BVCEO 200 GHz ft, 180 GHz fmax 2.5 x 105 A/cm2 operation 87 GHz input, 43.5 GHz output -0.06 -0.08 V out (Volts) -0.1 -0.12 -0.14 -0.16 -0.18 -0.2 22 22.02 22.04 22.06 22.08 time (nsec) 22.1 22.12 22.14 8 GHz S ADC Technology 0.7 um InP MESA DHBT 400 Å base, 2000 Å collector, 9 V BVCEO, 200 GHz ft, 180 GHz fmax 2.5 x 105 A/cm2 operation Design simple 2nd-order gm-C topology comparator is 87 GHz MSS latch integration by capacitive loads 3-stage comparator, RTZ gated DAC PK Sundararajan Results 133 dB (1 Hz) SNR at 74 MHz equivalent to ~8.8 bits at 200 MS/s 975 kHz FFT bin size 8 GHz clock rate 65.5 MHz signal 64:1 oversampling ratio Very strong features of SiGe-bipolar transistors High current density 10 mA/mm2 T-shaped polysilicon emitter 0.25 mm junction wide contact low resistance, high yield Thin intrinsic base: low b Thick extrinsic base: low Rbb Low Ccb collector junction collector pedestal CVD/CMP SiO2 planarization regrown poly extrinsic base High-yield, planar processing high levels of integration LSI and VLSI capabilities SiGe clock rates up to 65 GHz Much more complex ICs than feasible in InP HBT InP HBT must reach higher integration scales or will cease to compete InP vs Si/SiGe HBTs: materials vs scaling advantages Advantages of InP ~20:1 lower base sheet resistance, ~5:1 higher base electron diffusivity ~3:1 higher collector electron velocity, ~4:1 higher breakdown-at same f. Disadvantage of InP: archaic mesa fabrication process Presently only scaled to ~ 1 um (production) large emitters, poor emitter contact: low current density: 2 mA/um2 high collector capacitance nonplanar device - low yield low integration scales InP HBT limits to yield: non-planar process Emitter contact Failure modes liftoff failure: emitter-base short-circuit emitter base contact base base sub collector S.I. substrate sub collector S.I. substrate Etch to base base excessive emitter undercut sub collector base contact S.I. substrate base Liftoff base metal base contact emitter contact sub collector base contact S.I. substrate base sub collector S.I. substrate planarization failure: interconnect breaks Emitter planarization, interconnects base base sub collector S.I. substrate sub collector S.I. substrate Yield degrades as emitters are scaled to submicron dimensions MBE growth of Polycrystalline n+ InAs Dennis Scott SiGe HBT process: extensive use of non-selective-area poly-Si regrowth Can a similar technology be developed for InP ? Polycrystalline InAs grown on SiN: • Doping = 1.3 1019 cm-3, Mobility = 620 cm2/V•s Poly InAs:Si Doping vs. Temp 19 2.2 10 2 10 • doping-mobility product 81021 (V •s •cm)-1 19 1.8 10 19 Doping InGaAs lattice matched to InP: • Doping = 1.0 1019 cm-3, Mobility = 2200 cm2/V•s • doping-mobility product 221021 (V •s •cm)-1 19 1.6 10 19 1.4 10 19 1.2 10 1 10 19 8 10 18 6 10 18 945 950 955 960 965 Temp 970 975 980 Polycrystalline InAs has potential as an extrinsic emitter contact 985 1) Epitaxial Growth, Fe implant isolation Process Flow: Single-polyregrowth InP HBT 2) Deposit Pd/W base Ohmics. Encapsulate with Si3N4 Etch base-collector junction base N- collector N- collector N+ subcollector N+ subcollector S.I. substrate S.I. substrate top view extrinsic emitter and contact subcollector isolation implant mask 4) Regrow polycrystalline emitter. Deposit emitter metal. Etch through emitter emitter contact regrown InAlAs/InAs emitter* Si N 3 4 base contact Si N 3 4 base contact N- collector N+ subcollector S.I. substrate collector contact base contact base contact Si N 3 4 base 3) Passivate with Si3N4 Etch emitter window through base Form emitter SiN sidewalls emitter junction Dennis Scott N- collector N+ subcollector S.I. substrate 5) Recess etch and deposit collector contacts N- collector N+ subcollector S.I. substrate emitter contact regrown InAlAs/InAs emitter* Si N 3 4 base contact collector contact *monocrystalline where grown on semiconductor, polycrystalline where grown on silicon nitride Regrown-Poly-InAs-Emitter HBT 1 1.0 10 A = 0.8 x 15 um 2 E I = 100uA/step b 0 0 6.0 10 c I (mA) 8.0 10 0 4.0 10 0 2.0 10 0 0.0 10 0 1 2 3 4 V (V) ce Ib, Ic (mA) 2 10 2 10 1 10 0 10 -1 10 -2 10 -3 10 -4 Gummel for 0.8x15 um Emitter Ic Ib 0 0.2 0.4 0.6 0.8 Vbe (volts) 1 1.2 Dennis Scott Emitter Regrowth with Buried Base Contact Metal Buried W/Au base metal under emitter → further reduced Rbb Similar to buried WSi base contact process (SiGe, Washio) Dennis Scott Submicron Scaling of InP HBTs InP HBTs are a mixed-signal, not a MIMIC technology for MIMICs, sub-0.1-mm InP HEMTs are hard to beat mixed-signal is fiber ICs, ADCs, DACs, digital frequency synthesis these are 1000 -- 40,000 transistor ICs InP HBTs are struggling to compete with SiGe HBT application demands transistor counts near/beyond yield limits large emitter junctions→ high current → power near acceptable limits no decisive speed advantage in relevant circuits: digital logic materials advantages being squandered by inadequate scaling Critically needed for InP HBTs highly scaled process: 0.2 mm emitters, 0.4 mm collectors highly planar and high-yield fabrication processes small emitter junctions (0.2 mm x 0.5 mm) for acceptable power