Review: implified CMO Inverter Process CPE/EE 7, CPE 7 VLI esign I L: MO Transistor cut line epartment of Electrical and Computer Engineering University of Alabama in Huntsville Aleksandar Milenkovic ( www. ece.uah.edu/~milenka ) www. ece.uah.edu/~milenka/cpe7-f p well [Adapted from Rabaey s igital Integrated Circuits,, J. Rabaey et al.] 9/8/ VLI esign I; A. Milenkovic Course Administration Review: Intra-Layer esign Rules Instructor: TA: Labs: URL: Text: Aleksandar Milenkovic milenka@ece.uah.edu www.ece.uah.edu/~milenka E 7-L Office Hrs: MW 7:-8: Fathima Tareen tareenf @eng.uah.edu Office Hrs: Accounts on 6 machines http://www.ece.uah.edu/~milenka/cpe7-f igital Integrated Circuits, nd Edition Rabaey et. al., (October) Well Active elect ame Potential or 6 ifferent Potential 9 Contact or Via Hole Polysilicon Metal Metal 9/8/ VLI esign I; A. Milenkovic 9/8/ VLI esign I; A. Milenkovic Review: CMO Process at a lance Review: Inter-Layer esign Rule Origins efine active areas Etch and fill trenches Implant well regions eposit and pattern polysilicon layer Implant source and drain regions and substrate contacts Create contact and via windows eposit and pattern metal layers One full photolithography sequence per layer (mask) uilt (roughly) from the bottom up metal metal polysilicon exception! source and drain diffusions tubs (akawells, active areas). Transistor rules transistor formed by overlap of active and poly layers Transistors Unrelated Poly & iffusion Catastrophic error Thinner diffusion, but still working 9/8/ VLI esign I; A. Milenkovic 9/8/ VLI esign I; A. Milenkovic 6 VLI esign I; A. Milenkovic
Review: Vias and Contacts oal of this lecture (Chapter ) Via Metal to Active Contact Metal to Poly Contact Present intuitive understanding of device operation Introduction of basic device equations Introduction of models for manual analysis Introduction of models for PICE simulation Analysis of secondary and deep-sub-micron effects Future trends 9/8/ VLI esign I; A. Milenkovic 7 9/8/ VLI esign I; A. Milenkovic Learn more about fabrication The iode http://www. leb.e-technik.unierlangen.de/ lehre/mm/html/start.htm Al p n A io Cross-section of pn-junction in an IC process A p n One-dimensional representation Al A diode symbol Mostly occurring as parasitic element in igital ICs 9/8/ VLI esign I; A. Milenkovic 8 9/8/ VLI esign I; A. Milenkovic esign Abstraction Levels epletion Region YTEM hole diffusion electron diffusion p n (a) Current flow. MOULE hole drift electron drift + ATE Charge ensity - ρ + x istance (b) Charge density. CIRCUIT Electrical Field ξ x (c) Electric field. V in V out EVICE Potential V ψ -W W x (d) Electrostatic potential. 9/8/ VLI esign I; A. Milenkovic 9 9/8/ VLI esign I; A. Milenkovic VLI esign I; A. Milenkovic
I (ma) iode Current The NMO Transistor Cross ection n areas have been doped with donor ions (arsenic) of concentration N - electrons are the majority carriers W ource Polysilicon ate L p substrate ulk (ody) ate oxide rain Field-Oxide (io ) p+ stopper p areas have been doped with acceptor ions (boron) of concentration N A - holes are the majority carriers 9/8/ VLI esign I; A. Milenkovic 9/8/ VLI esign I; A. Milenkovic 6 Ideal iode Equation witch Model of NMO Transistor The ideal diode equation (for both forward and reverse-bias conditions) is I = I (e V / φ T ) where V is the voltage applied to the junction a forward-bias lowers the potential barrier allowing carriers to flow across the diode junction a reverse-bias raises the potential barrier and the diode becomes nonconducting φ T = kt/q = 6mV at K I is the saturation current of the diode -. + V -... - -.7 -. -....7 V (V) V ource (of carriers) ate rain (of carriers) Open (off) (ate = ) Closed (on) (ate = ) R on V < V T V > V T Connected to N for NMO 9/8/ VLI esign I; A. Milenkovic 9/8/ VLI esign I; A. Milenkovic 7 The MO Transistor witch Model of PMO Transistor Polysilicon Aluminum V ource (of carriers) ate rain (of carriers) Open (off) (ate = ) Closed (on) (ate = ) R on Connected to V for PMO V > V V T V < V V T 9/8/ VLI esign I; A. Milenkovic 9/8/ VLI esign I; A. Milenkovic 8 VLI esign I; A. Milenkovic
V T (V) Threshold Voltage Concept Transistor in Linear Mode V + - n channel p substrate depletion region Assuming V > V T V - V(x) + x V I The value of V where strong inversion occurs is called the threshold voltage, V T 9/8/ VLI esign I; A. Milenkovic 9 The current is a linear function of both V and V 9/8/ VLI esign I; A. Milenkovic The Threshold Voltage V T = V T + γ( -φ F + V - -φ F ) where V T is the threshold voltage at V = and is mostly a function of the manufacturing process ifference in work-function between gate and substrate material, oxide thickness, Fermi voltage, charge of impurities trapped at the surface, dosage of implanted ions, etc. V is the source-bulk voltage φ F = -φ T ln(n A /n i ) is the Fermi potential (φ T = kt/q = 6mV at K is the thermal voltage; N A is the acceptor ion concentration; n i.x cm - at K is the intrinsic carrier concentration in pure silicon) γ = (qε si N A )/C ox is the body-effect coefficient (impact of changes in V ) (ε si =.x - F/m is the permittivity of silicon; C ox = ε ox /t ox is the gate oxide capacitance with ε ox =.x - F/m) 9/8/ VLI esign I; A. Milenkovic Current flowing in the transistor Current flowing in the transistor: I dsn = Q/t f Q charge, t f time for flight t f = L/v x Velocity of electrons: v = - µ n * E µ n electron mobility (-cm /Vs); µ p hole mobility (-cm /Vs); E electric field (vector) E x horizontal component of E, E x = - V ds /L v x horizontal component of v, v x = - µ n * E x t f = L/v x = L /µ n *V ds 9/8/ VLI esign I; A. Milenkovic The ody Effect Current flowing in the transistor (cont d).9.8.8.7.7.6.6.... -. - -. - -. V (V) V is the substrate bias voltage (normally positive for n-channel devices with the body tied to ground) A negative bias causes V T to increase from.v to.8v Q = C(V gc V tn ) V gc voltage between the gate and the channel charge only appears on the lower plate when V gc exceeds V tn V gc is not constant; V gc = V gs at the source, V gc = V gs V ds at the drain => sum (integrate) the charge all the way across the channel from x = (at the source) to x = L (at the drain) Assume: V gc (x) is linear function of distance => V gc = [V gs + (V gs V ds )]/ = V gs V ds / C the gate capacitance (parallel-plate capacitor with length L, width W, a plate separation equal to the gate-oxide thickness T ox, ε ox the gate oxide permittivity; ε ox =.x - F/m, T ox = Å) C = ε ox *W*L/T ox = C ox *W*L; C ox gate capacitance per unit area Q = C ox *W*L*[(V gs V tn ) V ds /] 9/8/ VLI esign I; A. Milenkovic 9/8/ VLI esign I; A. Milenkovic VLI esign I; A. Milenkovic
Current flowing in the transistor (cont d) t f = L/v x = L /µ n *Vds Q = C ox *W*L*[(V V TN ) V /] I N = (W/L)*µ n *C ox *[(V V TN ) V /]*V k n = µ n *C ox process transconductance parameter β n = (W/L)*k n transistor gain factor Linear (triode) region: V ds < = V gs V tn I dsn = β n *[(V gs V tn ) V ds /]*V ds Voltage -Current Relation: aturation Mode For long channel devices When V V V T I = k n / W/L [(V V T ) ] since the voltage difference over the induced channel (from the pinch-off point to the source) remains fixed at V V T However, the effective length of the conductive channel is modulated by the applied V, so I = I ( + λv ) where λ is the channel-length modulation (varies with the inverse of the channel length) 9/8/ VLI esign I; A. Milenkovic 9/8/ VLI esign I; A. Milenkovic 8 Voltage -Current Relation: Linear Mode For long-channel devices (L >. micron) When V V V T I = k n W/L [(V V T )V V /] where k n = µ n C ox = µ n ε ox /t ox = is the process transconductance parameter (µ n is the carrier mobility (m /Vsec)) k n = k n W/L is the gain factor of the device For small V, there is a linear dependence between V and I, hence the name resistiveor linear region Current eterminates For a fixed V and V (> V T ), I is a function of the distance between the source and drain L the channel width W the threshold voltage V T the thickness of the io t ox the dielectric of the gate insulator (io ) ε ox the carrier mobility for nfets: µ n = cm /V-sec for pfets: µ p = 8 cm /V-sec 9/8/ VLI esign I; A. Milenkovic 6 9/8/ VLI esign I; A. Milenkovic 9 Transistor in aturation Mode Assuming V > V T V V - V - V + T I Pinch-off V > V - V T The current remains constant (saturates). I Long Channel I-V Plot (NMO) X - 6 V V =.V = V - V T V =.V Linear aturation V =.V V =.V cut-off... V (V) NMO transistor,.um, L d = um, W/L =., V =.V, V T =.V Quadratic dependence 9/8/ VLI esign I; A. Milenkovic 7 9/8/ VLI esign I; A. Milenkovic VLI esign I; A. Milenkovic
υ n (m/s) hort Channel Effects ehavior of short channel device mainly due to Constant mobility (slope = µ) υ sat = Constant velocity Velocity saturation the velocity of the carriers saturates due to scattering (collisions suffered by the carriers) ξ c =. ξ(v/µm) For an NMO device with L of.µm, only a couple of volts difference between and are needed to reach velocity saturation 9/8/ VLI esign I; A. Milenkovic I hort Channel I-V Plot (NMO) X. -.. Linear Early Velocity aturation aturation V =.V V =.V V =.V V =.V... V (V) NMO transistor,.um, L d =.um, W/L =., V =.V, V T =.V 9/8/ VLI esign I; A. Milenkovic Linear dependence Voltage -Current Relation: Velocity aturation For short channel devices Linear: When V V V T I = κ(v ) k n W/L [(V V T )V V /] where κ(v) = /( + (V/ξ c L)) is a measure of the degree of velocity saturation aturation: When V = V AT V V T I at = κ(v AT ) k n W/L [(V V T )V AT V AT /] I 6 X - MO I -V Characteristics... V (V) (for V =.V, W/L =.) long-channel quadratic short-channel linear Linear (short-channel) versus quadratic (longchannel) dependence of I on V in saturation Velocity -saturation causes the shortchannel device to saturate at substantially smaller values of V resulting in a substantial drop in current drive 9/8/ VLI esign I; A. Milenkovic 9/8/ VLI esign I; A. Milenkovic V = V Velocity aturation Effects Long V AT V -V T channel devices hort channel devices For short channel devices and large enough V V T V AT < V V T so the device enters saturation before V reaches V V T and operates more often in saturation I AT has a linear dependence wrt V so a reduced amount of current is delivered for a given control voltage hort Channel I-V Plot (PMO) All polarities of all voltages and currents are reversed - V (V) - V = -.V V = -.V V = -.V V = -.V - X - PMO transistor,.um, L d =.um, W/L =., V =.V, V T = -.V -. -. -.6 -.8 I 9/8/ VLI esign I; A. Milenkovic 9/8/ VLI esign I; A. Milenkovic 6 VLI esign I; A. Milenkovic 6
The MO Current-ource Model ubthreshold Conductance I I = for V V T I = k W/L [(V V T )V min V min /](+λv ) for V V T with V min = min(v V T, V, V AT ) and V T = V - V T etermined by the voltages at the four terminals and a set of five device parameters V T (V) γ(v. ) V AT (V) k (A/V ) λ(v - ) NMO...6 x -6.6 PMO -. -. - - x -6 -. I - - ubthreshold exponential region V T Linear region Quadratic region... V (V) I ~ I e (qv /nkt) where n Transition from ON to OFF is gradual (decays exponentially) Current roll-off (slope factor) is also affected by increase in temperature = n (kt/q) ln () (typical values 6 to mv/decade) Has repercussions in dynamic circuits and for power consumption 9/8/ VLI esign I; A. Milenkovic 7 9/8/ VLI esign I; A. Milenkovic R eq (Ohm) x 7 6 The Transistor Modeled as a witch V V T R on Modeled as a switch with infinite off resistance and a finite on resistance, R on Resistance inversely proportional to W/L (doubling W halves R on ) ubthreshold I vs V I = I e (qv /nkt) ( - e (qv /kt) )( + λv )... V (V) (for V = V, V = V V /) For V >>V T +V AT /, R on independent of V Once V approaches V T, R on increases dramatically V from to.v V (V) NMO(kΩ) PMO (kω). 9 9/8/ VLI esign I; A. Milenkovic 8 8. R on (for W/L = ) For larger devices divide R eq by W/L 9/8/ VLI esign I; A. Milenkovic Other (ubmicon) MO Transistor Concerns Velocity saturation ubthreshold conduction Transistor is already partially conducting for voltages below VT Threshold variations In long-channel devices, the threshold is a function of the length (for low V) In short-channel devices, there is a drain-induced threshold barrier lowering at the upper end of the V range (for low L) Parasitic resistances resistances associated with the source and drain contacts Latch-up R R ubthreshold I vs V I = I e (qv /nkt) ( - e (qv /kt) )( + λv ) V from to.v 9/8/ VLI esign I; A. Milenkovic 9 9/8/ VLI esign I; A. Milenkovic VLI esign I; A. Milenkovic 7
Threshold Variations V T VT Long-channel threshold Low V threshold Threshold as a function of the length (for low V ) L V rain-induced barrier lowering (for low L) 9/8/ VLI esign I; A. Milenkovic Next Time: The CMO Inverter V V in V out C L 9/8/ VLI esign I; A. Milenkovic VLI esign I; A. Milenkovic 8