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Applicazioni industriali delle radiazioni ionizzanti (Effetti della radiazione ionizzante nella Tecnologia CMOS) Andrea Candelori Istituto Nazionale di Fisica Nucleare and Dipartimento di Fisica, Padova 1 5A. MOS and MOSFET: a brief review 2 The MOS capacitor MOS is the acronym of metal oxide semiconductor Gate tox bulk contact 3 The MOS capacitor band diagram Ef is the fermi level Eg is the energy gap Ec is the conduction band energy level Ev is the valence band energy level is the electron affinity is the work function q is the potential barrier q·m,e=3.15 eV Eo q·Si,e=3.15 eV q·ox=0.95 eV q·m=4.1 eV q·Si=4.05 eV Ec,ox q·Si,e Ef,m q·Si Ec,Si Ei,Si Eg,ox=9 eV Ef,Si Eg,Si=1.1 eV q·m,h=5.9 eV Ev,ox q·Si,h=4.8 eV Ev,Si 4 The MOS capacitor band diagram (accumulation and depletion) electron accumulation close to the SiO2/Si interface ns>Nd Vg>0 n-type silicon Vg<0 electron are pushed back from the SiO2/Si interface leaving the donor ionized ns<Nd 5 The MOS capacitor band diagram (accumulation and depletion) Vg=VT<0 donor are ionized holes are attracted at the SiO2/Si interface hs=Nd Vg<VT<0 n-type silicon 6 The MOS capacitor band diagram Flatband Accumulation Depletion Inversion 7 MOSFET MOSFET is the acronym of Metal Oxide Semiconductor Field Effect Transistor Applets: http://jas.eng.buffalo.edu/education/mos/mosfet/mosfet.html 8 N-channel MOSFET (conduction is due to electrons) G S D n+ n+ The n-MOSFET threshold voltage (VT>0) is the voltage which has to be applied to the gate in order to form a conductive channel (electrons) between source and drain. VG=VT>0 p G S D B n+ n+ p B The silicon at the SiO2/Si interface is in strong inversion (n=Na), and a conductive channel of electrons is formed between source and drain. 9 P-channel MOSFET: conduction is due to holes G S D p+ p+ The p-MOSFET threshold voltage (VT<0) is the voltage which has to be applied to the gate in order to form a conductive channel (holes) between source and drain. VG=VT<0 n G S D B p+ p+ n B The silicon at the SiO2/Si interface is in strong inversion (p=Nd), and a conductive channel of holes is formed between source and drain. 10 Measurement of the MOSFET threshold voltage ID A G S D p+ VG=VD<0 is variable p+ 0.15 n Oxide thickness 5.5 nm W=2000 m L=0.36 m 0.12 |ID|1/2 (A1/2) B 0.09 0.06 0.03 |VT|=0.416 V 0.00 0.0 0.4 |VG|=|VD| (V) 0.8 Threshold voltage (VT) for the p-MOSFET at the input at the APV-25 read-out electronics. 1.2 11 MOSFET operation in sub-threshold VG is variable VT<VG<0 ID G VD=-50 mV A S Above-threshold D p+ Sub-threshold p+ 1E-1 n 1E-3 1E-5 |ID| (A) B VD=-50 mV 1E-7 Threshold 1E-9 1E-11 1E-13 1E-15 0.4 0.2 0.0 -0.2 -0.4 VG (V) -0.6 -0.8 Sub-threshold curve for the p-MOSFET at the input at the APV-25 read-out electronics. -1.0 12 -1.2 MOSFET operation above threshold VG>VT and VG is fixed Linear region VG>VT and VD<VG B Pinch-off condition VG>VT and VD=VG B Saturation region VG>VT and VD>VG B 13 MOSFET operation above threshold VG is fixed VG<VT<0 ID G VD is variable A S D p+ p+ 30 VG=-0.40 V VG=-0.50 V VG=-0.60 V VG=-0.85 V VG=-1.00 V VG=-1.20 V n B |ID| (mA) 20 10 0 0.0 0.2 0.4 0.6 |VD| (V) 0.8 Output curve for the p-MOSFET at the input at the APV-25 read-out electronics. 1.2 1.0 14 The MOSFET as an amplifier VOUT=VINgmRD VDD R VOUT gm=IDS/VG Trans-conductance VIN D p+ 50 G 40 VG B |gm| (mS) VD=-450 mV, AsRec S 30 VD=-650 mV, AsRec VD=-850 mV, AsRec 20 p+ VD=-50 mV, AsRec VD=-250 mV, AsRec VD=-1050 mV, AsRec n 10 0 0.0 -0.2 -0.4 VG (V) -0.6 -0.8 15 -1.0 5B. Radiation Effects in thick oxide (>10 nm) 16 Materials for study 1) T.R. Oldham and F. B. McLean, "Total Ion ionizing Dose Effects in MOS Oxides", IEEE Trans. Nucl. Sci., vol 50, n.3, June 2003, pp. 483-499, and references therein. 2) J. R. Schwank et al., "Radiation Effects in MOS Oxides", IEEE Trans. Nucl. Sci., vol 55, n.4, August 2008, pp. 1833-1853, and references therein. 3) J. R. Schwank et al., "Radiation Effects in MOS Oxides", IEEE Trans. Nucl. Sci., vol. 50, n. 3, June 2003, pp.522-538. 4) R. C. Lacoe., "Improving Integrated Circuits Performance Through the Application of Hardnessby-design Methodology", IEEE Trans. Nucl. Sci., vol. 55, n. 4, August 2008, pp.1903-1925. 5) G. Anelli et al., "Radiation Tolerant VLSI Circuits in Styandard Deep Submicron CMOS Technologies for the LHC Experiment: Practical Design Aspects", IEEE Trans. Nucl. Sci., vol. 46, n. 6, December 1999, pp.1690-1696. 17 MOSFET: the gate oxide n-MOSFET before irradiation: electron channel: VT>0 n-MOSFET after irradiation: positive oxide charge trapped in the oxide, VT decreases and becomes negative. Also at VGS=0 V the electron channel is formed. 18 The MOSFET sensitive parts to radiation SiO2/Si interface to ionizing radiation G S SiO2 to ionizing radiation D p+ p+ The substrate can be sensitive to bulk damage, but this effect is less relevant because the conduction is close to the SiO2/Si surface n B 19 The MOSFET sensitive parts to radiation SiO2/Si interface to ionizing radiation G S SiO2 to ionizing radiation D n+ n+ The substrate can be sensitive to bulk damage, but this effect is less relevant because the conduction is close to the SiO2/Si surface p B 20 Ionizing radiation in SiO2: p-MOSFET threshold voltage VT<0: channel of holes 21 Ionizing radiation in SiO2: n-MOSFET threshold voltage VT>0: channel of electrons 22 MOSFET: the gate oxide Which are the physical mechanisms governing radiation damage in Silicon Oxide (SiO2)? Which is the dependence of these mechanisms considering the following experimental parameters? -Oxide thickness. -Time. -Electric field in the oxide. -Temperature. We will consider first the results of investigations for thick oxide (>10 nm), whose thicknesses are typical for old technologies (2000) and nowadays field oxides. 23 Ionizing radiation in SiO2 and defect generation mechanisms (1) VG>0 -When radiation passes through the oxide electron/hole pairs are created by the deposited energy. -In SiO2 electrons are much more mobile than holes, and they are swept out of the oxide typically in picoseconds or less. However in the first picosecond some fraction of the electrons and holes will recombine, depending on the energy and type of the impinging radiation. -Holes escaping recombination are relatively immobile and remain near the point of the generation causing the initial negative threshold voltage shift. 24 Ionizing radiation in SiO2 and defect generation mechanisms (1) (1) The initial negative threshold voltage shift described in the previous slide. 25 Ionizing radiation in SiO2 and defect generation mechanisms (2) VG>0 -The transport of the holes to the SiO2/Si interface causes a short term recovery of the threshold voltage: this process takes place over may decades of times and is very sensitive to the electric field, temperature, oxide thickness and process history (<1 s at RT, orders of magnitudes slower at low temperature). 26 Ionizing radiation in SiO2 and defect generation mechanisms (2) (2) The short recovery of the initial negative threshold voltage shift, due to the transport 27 of holes to the SiO2/Si interface, described in the previous slide. Ionizing radiation in SiO2 and defect generation mechanisms (3) VG>0 -When holes are close to the SiO2/Si interface a fraction is trapped in relatively deep long-lived trap sites. The trapped holes cause a remnant negative voltage shift which can persist for hours or even for years. But even these stable trapped holes undergo a gradual annealing. 28 Ionizing radiation in SiO2 and defect generation mechanisms (3) (3) The remnant negative threshold voltage shift due to hole trapping in deep long-lived 29 sites close to the SiO2/Si interface. Ionizing radiation in SiO2 and defect generation mechanisms (4) VG>0 -Generation of interface states at the SiO2/Si interface. These defects introduce energy levels in the Si band-gap, whose occupancy depends on the Fermi level at the SiO2/Si interface, which in turn depends on the applied gate voltage: consequently they cause a threshold voltage shift which varies depending on the applied gate voltage. -Interface states in the upper part of the band-up are acceptor (can trap electrons and are relevant for n-MOSFET: VT increases). -Interface states in the lower part of the band-up are donors (can emit electrons and are relevant 30 for p-MOSFET: VT decreases). Ionizing radiation in SiO2 and defect generation mechanisms (4) (4) The positive threshold voltage shift due to interface states at the SiO2/Si interface in n-MOSFET (VT decreases due to the contributions from the oxide charge, VT increases 31 due to the contributions from the interface states in the upper part of the band-gap which are negative charged) Ionizing radiation in SiO2 and defect generation mechanisms (4) In n-MOSFET, the long-term threshold voltage shift is positive (rebound effect) due to negative trapped charge in interface states. 14 orders of magnitude for time: 1 day: 8.6·104 s 1 month: 2.6 ·106 s 1 year: 3.15·107 s 32 Electron-hole pairs generation in SiO2 The mean energy to create and electron hole pair in SiO2 is: (17 ± 1) eV [1986]. The electron-holes pairs created in the volume of 1 cm3 by the dose of 1 rad is 8.1·1012. We define g0= 8.1·1012 e-h/(cm3·rad) SiO2 N e h g 0 V D 8.11012 eh V D 3 cm rad Dose (rad) Volume (V) eh eh 12 N eh g t D 8 . 1 10 tox D 0 ox 2 3 cm rad cm 33 Initial hole yield -Ionizing radiation generates electron-hole pairs in SiO2. -Electrons are swept out of the oxide very rapidly (1 ps or less), but in that time some fraction of electrons recombine with holes. -The fraction of holes surviving recombination depends on: a) the magnitude of electric field in the oxide (operative condition of the device); b) the initial electron-hole pairs density in the oxide (the LET of the impinging radiation or primary electrons). N h g 0 V D f ( Eox, Radiation ) 8.1 1012 eh V D f ( Eox, Radiation ) cm 3 rad eh N eh g 0 tox D f ( Eox , Radiation ) 2 cm eh 12 8.1 10 tox D f ( Eox , Radiation ) 3 cm rad 34 Initial hole yield: geminate and columnar recombination models Geminate recombination model (can be applied for electron and Co60 irradiation): a) The average separation distance between electron-hole pairs is higher than the thermalization distance. b) The interaction between electron and hole of an isolated pairs is due to Coulomb attraction. c) Electrons and holes drifts in opposite direction due to the electric field. d) Electrons and holes moves randomly due to thermal fluctuations of the system. c) The interactions with other electron-hole pairs can be neglected. Columnar recombination model (can be applied for heavy ions (Z>1)): a) The average separation distance between electron-hole pairs is lower than the thermalization distance: there are several electrons closer to any given hole than the electron, which was its original partner. b) The recombination probability is higher for the columnar model than for geminate model. 35 Initial hole yield: geminate recombination model Geminate recombination model (can be applied for electron and Co60 irradiation): a) The average separation distance between electron-hole pairs is higher than the termalization distance. b) The interaction between electron and hole of an isolated pairs is due to Coulomb attraction. c) Electrons and holes drifts in opposite direction due to the electric field. d) Electrons and holes moves randomly due to thermal fluctuations of the system. c) The interactions with other electron-hole pairs can be neglected. V E d 1 MV 100 nm cm 106V 1 105 cm 10V cm -The fraction yield for holes . . . . . . by increasing the oxide electric field. -The maximum value of the fraction yield for holes at 2.5 MV/cm is . . . -At 1 MV/cm the fraction yield for holes is . . . 36 Initial hole yield: columnar recombination model Columnar recombination model (can be applied for heavy ions (Z>1)): a) The average separation distance between electron-hole pairs is lower than the termalization distance: there are several electrons closer to any given hole than the electron, which was its original partner. b) The recombination probability is higher for the columnar model than for geminate model. 2 MeV particle B is the radius at half-maximum for the Gaussian charge distribution of the 2 MeV particle: i.e. 1.178·. V E d 1 MV 100 nm cm 106V 1 105 cm 10V cm -The fraction yield for holes . . . . . . by increasing the oxide electric field. -The maximum value of the fraction yield for holes at 2.5 MV/cm is . . . -At 1 MV/cm the fraction yield for holes is . . . 37 Initial hole yield for different radiations [1983] Geminate model Intermediate condition Co60 -rays and 10 keV X-ray sources: which is the better solution for radiation damage due to electrons in Van Allen Belts? Columnar model Experimental values of the fractional yield for holes as a function of the oxide electric field for 38 different radiations Initial hole yield for different radiations The fractional yield for holes as a function of the proton energy: -at low proton energy: columnar model -at high proton energy: geminate model Linear Energy Transfer for different radiations (values for 10 keV X-rays and Co60 -rays are for primary electrons) [2002]: - geminate model applied at low dE/dx; - columnar model applied at high dE/dx; -10 keV X-rays simulates 20-60 MeV protons; - Co60 -rays simulates 1 MeV electrons; 39 Hole transport in SiO2 (1) Hole transport occurs over many decade of times after the radiation pulse. 1) Changes in temperature does not charge the "S" shape of the recovery curve (VFB vs time). At temperature higher than -130 ºC the hole transport is strongly temperature activated. 1978 Flat band voltage variation after irradiation as a function of time. VFB (t ) VFB (0 ) Flat band voltage variation just after the LINAC electron pulse. -Oxide thickness: tox=96.5 nm -Radiation: LINAC 12 MeV electron pulse (30 krad) (geminate model) -Oxide electric field: 1 MV/cm 40 16.6 min Hole transport in SiO2 (2) Hole transport occurs over many decade of times after the radiation pulse. 2) Changes in the oxide electric field does not charge the shape of the recovery curve (VT vs time). The hole transport is activated by the oxide electric field. 1978 Flat band voltage variation after irradiation as a function of time. VFB (t ) VFB (0 ) Flat band voltage variation just after the LINAC electron pulse. -Oxide thickness: tox=96.5 nm -Radiation: LINAC 12 MeV electron pulse (30 krad) (geminate model) -Temperature: 80 K 41 16.6 min Hole transport in SiO2 (3) Hole transport occurs over many decade of times after the radiation pulse. 3) Changes in the oxide thickness does not charge the shape of the recovery curve (VT vs time) but the hole transport time has a super linear power law dependence on the oxide thickness. 1978 tTR c (tox ) The "hole transit time" tTR is the time at which: VFB (t1/ 2 ) 1 VFB (0 ) 2 -Oxide thickness: tox=96.5 nm -Radiation: LINAC 12 MeV electron pulse (30 krad) (geminate model) 42 Hole transport in SiO2 (3) Proposed mechanisms for hole transport in SiO2: -Continuous-time-random-walk (CTRW) hopping (hopping of holes between localized shallow trap states having a random spatial distribution, but having an average separation of about 1 nm); -Multiple-trapping model. 1978 Flat band voltage variation after irradiation as a function of time. Eox=1 MV/cm VFB (t ) VFB (0 ) Flat band voltage variation just after the LINAC electron pulse. -Oxide thickness: tox=96.5 nm -Radiation: LINAC 12 MeV electron pulse (30 krad) (geminate model) The "S" shape of the recovery curve is . . . The data can be fitted by . . . The "hole recovery time" t1/2 is the time at which: VFB (t1/ 2 ) 1 VFB (0 ) 2 43 5C. Radiation effects in SiO2: microscopic considerations 44 Silicon oxide (SiO2) -The silicon oxide used in microelectronic applications is composed by tetrahedral SiO4 blocks, but they are irregular: the SiO2 structure is not crystalline but amorphous (a-SiO2). -The SiO4 blocks are connected by Si-O-Si bridging bonds, as shown in the following figure, the corresponding formula is O3Si-O-SiO3. In a-SiO2, the Si-OSi bonds are strained: the angle between the oxygen and the two Si neighbours can assume values between 120° and 180°. Two tetrahedral SiO4 blocks and the oxygen bonding the two silicon atoms. 45 Microscopic defects in SiO2: the oxygen vacancy -The oxygen vacancy (Vo) is a structure of fundamental importance for defect studies in SiO2. The Vo defect is obtained by removing the oxygen bonding two Si atoms, as shown in the following Figure. -It is schematically represented by the formula: O3Si-SiO3. When the oxygen is removed, the c-SiO2 structure relaxes: the two silicon atoms move to the oxygen vacancy by near equal amount along the Si-O direction. The oxygen vacancy density can be high up to 6·1019 cm-3, in oxides thermally grown in oxygen reach atmosphere (dry oxide). The SiO2 structure (left). The oxygen vacancy defect (right). 46 Hole trapping and annealing in SiO2 Holes are trapped close to the SiO2/Si interface because there is a transition region where oxidation is not complete, this region contains excess Si atoms, i.e. "Oxygen vacancy defects". (a) "Oxygen vacancy": a Silicon atom is back bonded to three Oxygen atoms and with a weak bond to a Silicon atom. (e) (d) 47 Hole trapping and annealing in SiO2 (b) When a hole is trapped by a "Oxygen vacancy" the Si-Si bond is broken and the lattice relaxes to the E’ center: the first Silicon atom is positive charged and back bonded to three Oxygen atoms, the second Silicon atoms is neutral and back bonded to three Oxygen atoms. The E’ center is a positively charge defects which is detectable by ESR (Electron Spin Resonance). (e) (d) 48 The positive charge oxygen vacancy -The bonding between the two Si atoms of the Vo defect can be broken by exciting a bonding electron to the SiO2 conduction band or by hole trapping. -The new defect, is called positive charged oxygen vacancy (Vo+). It is represented by the chemical formula: O3Si°SiO3, where the symbols "" and "°" are the unpaired electron and the trapped hole, respectively. -The Vo+ center is positive charged (°SiO3) and paramagnetic (O3Si). It can be characterized by the electron-spin-resonance (ESR) technique. The paramagnetic part of the Vo+ defect is called E' center. The positive charged oxygen vacancy defect. The arrow indicates the unpaired electron of the neutral Si atom. The Vo+ defect is strongly correlated to the positive charge induced by ionising radiation. 49 Hole trapping and annealing in SiO2 (c) Trapped holes are relatively stable but they can undergo a long-term annealing which can extend from hours to years. The microscopic mechanism for the annealing of the trapped hole: at room temperature is electron tunneling from the Si substrate and at higher temperature is electron thermal excitation from the Si substrate valence band: an electron can be trapped by the neutral Silicon atom back bonded to the three Oxygen atoms, becoming negative and compensating the positive charge of the other Si atom back bonded to three Oxygen atoms. This effects is enhanced for positive gate bias: VG>0 V. (e) VG>0 (d) 50 Hole trapping and annealing in SiO2 (d) Depending on the local microscopic strain of the two Si atoms, the weak Si-Si bond can be reformed coming from (c) to (a): true annealing of the trapped holes. (e) Depending on the local microscopic strain of the two Si atoms, the weak Si-Si bond can not be reformed coming from (c) to (b) when a negative gate bias VG<0 is applied: neutral electron trap, which can emit the trapped electron for VG<0 (from (c) to (b)) and which can trap an electron for VG>0 (from (b) to (c)). (e) (d) VG<0 51 -Oxide thickness: tox= 45 nm -Radiation source: Co60 -rays -Bias during irradiation VGS=10 V Vot Hole trapping and annealing in SiO2 1984 (e) VG>0 (d) VG<0 52 Hole trapping and annealing in SiO2 Annealing of the midgap voltage variation (Vmg ) for MOS capacitors. Vmg depends on the oxide trapped charge: -Vmg negative => positive oxide trapped charge (Vmg decreases: positive trapped charge increases; Vmg increases: positive trapped charge decreases). VG>0: Trapped hole annealing: electron tunneling from the Si substrate, from (b) to (c). (e) VG>0 (d) VG<0 VG<0: Si-Si weak bond reformation (true annealing of the trapped holes) from (c) to (a); Reverse annealing (electron tunneling back from neutral electron traps to the Si substrate) from (c) to (b). 53 Hole trapping and annealing in SiO2 The neutral electron trap, which can be positive charged or neutral and are close to the SiO2/Si interface are also called border traps. MOS capacitor with p-substrate and VG>0. In the Figure are shown the interface states and the neutral 54 electron traps close to the SiO2/Si interface which can be positive charged or neutral. Positive and negative charge trapping in SiO2 Oxigen vacancy (D) +h hole trapping o oo Si o Si o o electron redistribution bond reformation o oo Si o Si o o Oxigen vacancy (A) +h hole trapping o oo Si o Si o +e electron trapping o oo Si o o Positive charged oxygen vacancy Si o Unstable state not observed (C) o electron redistribution no bond reformation (B) +h hole trapping o oo Si o oo Si +e electron trapping o Si o o Neutral compensated defect (E) o Si o o Fixed negative charge (F) Oxygen vacancy (A). Positive charged oxygen vacancy (B). Unstable state (C). Oxygen vacancy after bond reformation (D). Neutral compensated defect (E). Fixed negative charge (F). 55 Interface states Interface states are identified with the Pb0 center, i.e. a Si atom which is back-bonded to three Si atoms and with a dangling bond. This defect is amphoteric: 1) donor type in the lower part of the Si bandgap: -if the Fermi level is higher than midgap the defect is neutral -if the Fermi level is lower than midgap the defect emits an electron and becomes positive charge (positive charge trapping relevant for p-MOSFET) 2) acceptor type in the upper part of the Si bandgap: -if the Fermi level is higher than midgap the defect traps an electron and becomes negative charged (negative charge trapping relevant for n-MOSFET) -if the Fermi level is lower than midgap the defect is neutral. 56 Interface states -The Pb center is a trivalent Si defect at the SiO2/Si interface: i.e., a silicon atom bonded to three other Si atoms with an unpaired electron in an orbital pointing out to a vacancy. It is represented by the chemical formula Si3Si. -The Pb defect is amphoteric, that is its charge condition can be positive, negative or neutral. Pb: Si3Si Pb- : Si3Si (acceptor) qB Pb: Si3Si Pb+ : Si3Si° (donor) The donor (close circles) and acceptor (open circles) Pb centers in the Si band-gap at midgap condition for a MOS on n-Si substrate. 57 Interface traps -The Pb centers whose energy level is in the lower part of the Si band-gap are donor interface states: at midgap they are neutral and paramagnetic (Pb: Si3Si), if the Fermi level in the Si substrate moves to the Si valence band edge (Vg<0), they emit the trapped electron and become positive charged and diamagnetic (Pb+: Si3Si). -The Pb centers whose energy level is in the upper part of the Si band-gap are acceptor interface states: at midgap they are neutral and paramagnetic (Pb: Si3Si), if the Fermi level in the Si substrate moves to the Si conduction band edge, (Vg>0) they trap an electron from the Si substrate and become negative charged and diamagnetic (Pb-:Si3Si ). Pb: Si3Si Pb- : Si3Si (acceptor) qB Pb: Si3Si Pb+ : Si3Si° (donor) The donor (close circles) and acceptor (open circles) Pb centers in the Si band-gap at midgap condition for a MOS on n-Si substrate. 58 Interface states -When the SiO2 layer is grown at the SiO2/Si interface there are 1013 cm-3 Si atoms, each back-bonded to three Si atoms, with a dangling bond: Si3Si, which are neutral interface states. -In the subsequent processing, almost all these centers are passivated by reacting with Hydrogen, which saturates the Si dangling bond: Si3Si H. -However they can be depassivated by radiation and/or electrical stress giving rise to neutral interface states: Si3Si. -Two stage model for radiation induced interface states: 1) In SiO2, due to H2 atmosphere processing steps, neutral Hydrogen is present. In the fist stage radiation induces holes cause positive hydrogen ions (protons) in the oxide; 2) In the second stage, protons undergo hopping transport under positive gate bias, and when they reach the SiO2/Si interface, they interact with the passivated trivalent Si centers (Si3Si H) (H) giving rise to an interface states and an Hydrogen molecules (by capturing an electron): Si3Si H2. 59 Defect classification in SiO2 -Location: oxide traps, border traps and interface traps -Electrical behavior: fixed states (positive and negative charge or neutral) switching states (can exchange charge by tunneling) Gate tox bulk contact The MOS capacitor. The classification of the defects in the SiO2/Si system, depending on their location (a) and electrical behaviour (b). 60 Ionizing radiation in SiO2: summary (a) Before irradiation. (b) During irradiation: electrons and holes are generated by ionizing radiation. (c) Electrons are sweep out in picoseconds, under Vg>0 holes slowly moves to the SiO2/Si interface. (d) Holes are trapped in SiO2 close to the SiO2/Si interface. Interface states are created at the SiO2/Si interface. Effects of the positive oxide trapped charge and of the charge trapped in the interface states on the threshold characteristics of p-MOSFET and n-MOSFET. 61 5D. The rebound effect in n-MOSFETs and ELDRS in BJT 62 The rebound effect Positive charge trapping: VT<0 (VT decreases) Negative charge trapping: VT>0 (VT increases) p-MOSFET 1) Oxide trapped charge is positive: Vot contribution to VT=> VT<0 2) Positive trapped charge in interface states for p-MOSFET: Vit contribution to VT=> VT<0 The two contributions have the same sign. n-MOSFET 1) Oxide trapped charge is positive: Vot contribution to VT=> VT<0 3) Negative trapped charge in interface states for n-MOSFET: Vit contribution to VT=> VT>0 The two contributions have opposite sign. 63 The rebound effect -Oxide thickness: tox= 45 nm -Radiation source: Co60 -rays -Bias during irradiation VGS=10 V 1984 n-MOSFET VT 1) Which is the trend for VT during irradiation and annealing? 2) Which is the trend for Vit during irradiation and annealing? 3) Which is the trend for Vot during irradiation and annealing? 4) Which is the effect of the annealing temperature increase on the oxide charge? 5) Which is the effect of the annealing temperature increase on the interface states? 64 The rebound effect Interface state buildup occurs on time frames much slower than oxide charge build up. Example in the figure: the time for reaching 50% build up is 35 s for the 5 pulse curve, but the interface state buildup does not begin to saturate up to 105 s (27.8 hours). Si bandgap 1.12 eV -Oxide thickness: tox= 47 nm -Oxide electric field 1 MV/cm -Pulse repetition rate: 4 Hz Orders of magnitude for time: 1 day: 8.6·104 s 1 week: 6.05 · 105 s 1 month: 2.6 ·106 s 1 year: 3.15·107 s Time after the end of the irradiation (s) 65 The rebound effect 1 VT Vox Vit Cox Qit 0(Gate/ SiO2 Interface) ox ( x) xdx Cox tox( SiO2 / Si Interface) At high dose rates, taking into account that: the interface state buildup occurs on time frames much slower than oxide charge buildup, Vox predominates on Vit: in n-MOSFET Vox<0 predominates on Vit>0: VT<0 (Laboratory testing) At low dose rates, taking into account that: the interface state buildup occurs on time frames much slower than oxide charge buildup, and the annealing of the positive oxide trapped charge, Vit predominates on Vox : in n-MOSFET Vit>0 predominates on Vox<0: VT>0 (Space environment) At intermediate dose rates, taking into account that: the interface state buildup occurs on time frames much slower than oxide charge buildup, and the annealing of the positive oxide trapped charge, Vit and Vox are comparable: in n-MOSFET Vox>0 compensates Vit<0: VT0 Gate 0 tox bulk contact 66 Apparent dose rate effects 1984 Intermediate dose rates: In n-MOSFET compensation for the contribution from -Oxide positive trapped charge Vot -Negative charge trapped in interface states Vit>0 VT=Vot+Vit Low dose rates: n-MOSFET, failure due to interface states and negative charge trapping therein VTVit>0 (at low dose rates, the oxide positive charge anneals) High dose rates: n-MOSFET, failure due to oxide positive charge trapping VTVot<0 (long times and proton transport is required67 for interface state activation by SiSi H depassivation) The rebound effect In the space environments, electronic components are typically exposed to relative low dose rates for very long mission times: -the positive oxide trapped charge anneals; -the interface states buildup. In order to compare the radiation induced degradation by Laboratory testing (at high dose rates) for prediction in the Space environments (low dose rates) after irradiation devices are annealed at 100ºC for 1 week to anneal the positive oxide trapped charge and to complete the interface state build-up. 68 ESA ESCC Basic Specification 22900 The rebound effect: 100º for 168 h (1 week): 100ºC is a compromise because this temperature is not high enough to accelerate trapped hole annealing, but if one goes much higher temperature, 69 the interface states may anneal too. Enhanced Low Dose Rate Sensitivity (ELDRS) -La carica positiva intrappolata nell’ossido tra base ed emettitore causa un aumento dell’ampiezza della regione di svuotamento nelle zone p/p- della base all’interfaccia SiO2/Si. -Gli stati interfacciali all’interfaccia SiO2/Si dell’ossido tra base ed emettitore provocano un aumento nella generazione di portatori della regione di svuotamento nelle zone p/p- della base all’interfaccia SiO2/Si. -La conseguenza è un aumento della corrente di base IB e quindi una diminuzione del parametro =IC/IB del transistor. -Tale effetto, che si manifesta a bassi ratei di dose (rad(SiO2)/s), viene chiamato "Enhanced Low Dose Rate Sensitivity " (ELDRS) ed è particolarmente rilevante per i BJT in applicazioni spaziali. Sezione di un BJT p-n-p 70 Enhanced Low Dose Rate Sensitivity (ELDRS) In BJT technology the degradation induced by ionizing radiation, estimated by Laboratory testing (high dose rates) even after the 100ºC annealing for 1 week, underestimates the degradation induced by the Space environments (low dose rates): Enhanced Low Dose Rate Sensitivity (ELDRS). ELDRS is due positive charge trapping in the oxide which modify the oxide electric field and the subsequent spatial distribution of the trapped holes (Space Charge effects in the oxide) and lowering the annealing rates at low dose rates. 71 Apparent dose rate effects [opzionale] 1988 n-MOSFET or p-MOSFET? -Oxide thickness: tox= 60 nm -Bias during irradiation and annealing: VGS=6 V Vit is positive and iincreases with time: -the interface states are positively or negatively charged? -the interface states density increases or decreases? -Identical samples were exposed to the same dose (100 krad), with the dose rate varied over 11 orders of magnitude. -The threshold voltage variation, due to the oxide positive trapped charge, as a function of the total time (the sum of the irradiation time and of the annealing time) is the same. 72 Apparent dose rate effects [opzionale] 1988 n-MOSFET or p-MOSFET? -Oxide thickness: tox= 60 nm -Radiation source: Co60 -rays -Bias during irradiation and annealing: VGS=6 V Vot is negative and decreases with time: -the oxide charge is positive/negative? -the oxide charge decreases/increases? -Identical samples were exposed to the same dose (100 krad), with the dose rate varied over 11 orders of magnitude. -The threshold voltage variation, due to the oxide positive trapped charge, as a function of the total time (the sum of the irradiation time and of the annealing time) is the same. 73 Apparent dose rate effects [opzionale] 1988 n-MOSFET or p-MOSFET? -Oxide thickness: tox= 60 nm -Radiation source: Co60 -rays -Bias during irradiation and annealing: VGS=6 V -At high dose rates, the main contribution to Vot is due to… -At low dose rates, the main contribution to Vot is due to… A-t intermediate dose rates, the main contribution to Vot is due to… -Identical samples were exposed to the same dose (100 krad), with the dose rate varied over 11 orders of magnitude. -The threshold voltage variation as a function of the total time (the sum of the irradiation time and of the annealing time) is the same. 74 Oxide hardening Thermal oxidation of silicon is usually performed at high temperature (800°C-1200°C): High Temperature Oxide layer (HTO): Oxidant: a) water vapor (H2O: wet oxide); b) molecular oxygen (O2 dry oxide). Si 2HO2 SiO2 H 2 Vox tox n Si O2 SiO2 Vit tox n Wet oxides are more radiation hard for what concerns the positive oxide trapped charge. No significant improvement appears for interface states. 75 Oxide hardening High temperature annealing (>800ºC) can cause a decrease in oxide hardening for what concern the positive oxide trapped charge. Processing in H2 atmosphere after the deposition of the polysilicon gate material can cause a decrease in oxide hardening for what concern the interface states. 76 5E. Radiation Effects in thin oxide (<10 nm) 77 Device scaling In the figures the VT for n-MOSFET produced by different commercial technologies (AMI 1.6 m, Orbit 1.2 m, HP 0.8 m, HP 0.5 m, HP 0.35 m, TSMC 0.25 m, TSMC 0.18 m) is reported. What can be observed? Why it happens? 78 Device scaling 79 Device scaling In 1985: gate oxide thickness: 100 nm In 2005: gate oxide thickness: 10 nm Vox 1986 Qox d 2 Vox ox d ox 1 Cox d ox -The electron tunneling distance in SiO2 is 3 nm. -In thin oxides (dox<20 nm), electron tunneling from both gate/SiO2 and SiO2/Si interfaces eliminates or at least neutralize trapped charge near the interfaces. -For very thin oxides (dox<6 nm), the two tunneling fronts meets in the center of the oxide layer, leaving no positive oxide trapped charge. -The problem of hardening gate oxides is basically solved for what concerns positive charge trapping. 2 4 6 20 80 Device scaling 1) Electrons from Al and Si recombine with the trapped SiO2 positive charge within 3 nm from the SiO2 interfaces. 2) SiO2 positive charge trapping is negligible for oxide thickness lower than 6 nm. EC Ef,m + + + + + + Ef,Si - Ei 3 nm 3 nm EV Al SiO2 Si 81 The conduction through SiO2 layers Thick oxides Oxide thickness > 6 nm Conduction mechanism Fowler-Nordheim tunneling Ultra-thin oxides Oxide thickness < 3 nm Conduction mechanism Direct tunneling Thin oxides Oxide thickness < 6 nm and > 3 nm Conduction mechanism Trapped assisted tunneling 82 The conduction through thick (>3 nm) SiO2 layers 1) Electrons tunnel from gate to the SiO2 conduction band through the triangular potential barrier and move in the SiO2 conduction band to the Si substrate. 2) The conduction mechanism through a triangular potential barrier is called FowlerNordheim (FN) tunnelling. C V<0 Ef,m - 3 nm Al VAl<0 SiO2 Al VSi=0 SiO2 Si EC Ef,Si Ei Si + EV MOS capacitor with a negative gate voltage applied, and the corresponding band diagram showing the Fowler-Nordheim conduction mechanism (right). 83 The conduction through thick (>3 nm) SiO2 layers B | F | C q2m A= 8 h C mox J A| FC | e 2 4 82 mox (qC )3/ 2 B= 3 q h2 10-3 Oxide breakdown |Ig| (Ampere) Eox=120 V/200 nm=6 MV/cm 10-6 FN region 10-9 10-12 0 20 40 60 80 100 |Vg| (Volt) 120 140 160 Fowler-Nordheim conduction through a 200 nm thick SiO2 layer. 84 The conduction through ultra-thin (<3 nm) SiO2 layers -The direct tunnel effect is relevant for ultra-thin (<3 nm) SiO2 layers: electrons tunnel from gate to the SiO2 conduction band through the trapezoidal potential barrier directly to the Si substrate. Is there any implication for technology and radiation hardness? V<0 VAl<0 VSi=0 <3 nm Al Ef,m EC Ef,Si Ei - SiO2 Si EV + Al SiO2 Si MOS capacitor with a negative gate voltage applied, and the corresponding band diagram showing the direct tunneling conduction mechanism (right). 85 The conduction through ultra-thin (<3 nm) SiO2 layers The decrease in gate oxide thickness (<3 nm) for CMOS technology nodes under 100 nm has resulted in negligible radiation-induced charge trapping, but it also result in increased gate-substrate tunneling current: -increase in MOSFET off-state current and power dissipation; -new materials with dielectric constant (K) higher than SiO2, so that, for a given gate capacitance value, the thickness of the dielectric film can be increased, limiting the direct tunneling current: Hf-O/SiO2/Si, Al2O3/SiOXNY/Si: which is the radiation hardness of these highK dielectric materials? Nowadays research issues Cox 0 SiO2 A tox Cdielectric 0 dielectric A tdielectric 86 The conduction through thin (3 nm<TSiO2<6 nm) SiO2 layers 1) The trap assisted tunneling (TAT) is the tunnel effect by a defect in the SiO2 layers. 2) TAT is active at lower voltages than the Fowler-Nordheim (FN) conduction because TAT is through a trapezoidal potential barrier, while FN is through a triangular potential barrier. 3) The electron tunneling distance is 3 nm: TAT cannot be observed for oxide thickness than 6 nm. V<0 VAl<0 VSi=0 Oxide trap 6 nm Al Ef,m EC Ef,Si Ei - SiO2 Si EV + Al SiO2 Si MOS capacitor with a negative gate voltage applied, and the corresponding band diagram showing the trapped assisted tunneling (TAT) conduction mechanism (right). 87 Radiation effects: gate oxides in deep submicron CMOS technologies -The scaling down of contemporary CMOS technologies decreases the gate oxide thickness and the threshold voltage variation after irradiation .... .... but also new reliability issues for radiation hardness appears due to defect generation in the SiO2 layer: Radiation Induced Leakage Current (RILC); Radiation Soft Breakdown (RSB); Radiation Hard Breakdown (RHB). 2004 Gate current versus voltage (Ig-Vg) measured before and after irradiation of 3 nm oxide. The curves referring to RILC have been measured after 51010 Si ions/cm2 (E=158 MeV, LET=8.5 MeVcm2/mg). The curve referring to RSB has been measured after 107 I ions/cm2 (E=277 MeV, 88 LET=61.8 MeVcm2/mg). Radiation Induce Leakage Current (RILC) The radiation induced leakage current (RILC) is an increase of the current through the SiO2 layer due to an inelastic trap assisted tunneling by neutral defects generated by ionizing radiation (rays, electrons, protons, ions). The traps are distributed all over the oxide area. 1999 89 Radiation soft breakdown (RSB) 1) The radiation soft breakdown (RSB) is a huge increase of the current through the SiO2 layer due to multi-trap assisted tunneling through a localized path of neutral defects generated by ionizing radiation (mainly ions). 2) A single high LET ion strike is able to generate RSB along its high ionizing track. RILC RSB RHB RILC and RSB in 4 nm oxides 90 RILC and RSB Oxide conduction Oxide conduction and RSB Oxide conduction and RILC 2001 91 Mobility degradation Defects in SiO2 close to the SiO2/Si interface can also reduce the carrier mobility in the channel by acting as scattering centers. 92 5F. Radiation effects due to positive charge trapping in field oxides 93 Radiation induced field oxide leakage current in n-MOSFET -Technology scaling down: decrease of the gate oxide thickness, but the field oxide of advanced commercial technologies for are still relative thick and are soft to ionizing radiation. A relatively small dose in field oxides (10 krad) can induce sufficient positive charge trapping to cause field oxide induced IC failure. -Field oxide thickness: 100 nm – 1000 nm. -Field oxide are not produced only by thermal oxidation, but also by deposition techniques: the trapping properties of field oxide may be poorly controlled. -Field oxide isolation is performed by a) Local oxidation of Silicon (LOCOS) b) Shallow Trench Isolation (STI) in advance sub-micron technologies 94 CMP=Chemical Mechanical Polishing Radiation induced field oxide leakage current in n-MOSFET 1) In n-MOSFETs with LOCOS isolation, the positive charge build-up in the birds’ beak regions can invert the underlying p-type surface forming an n-type region underneath the filed oxide, i.e. a conductive path can be generated from source to drain, which will greatly increase the leakage current even at VGS=0V. -Similar conductive path are generated for n-MOSFETs with STI isolation: a) a leakage path occurs at the edge of the gate oxide transistor between the source and the drain; b) a leakage path occurs between the n-type source and drain regions of a n-MOSFET and the n-well of adjacent p-MOSFET. 1) b) a) 1998 95 Radiation induced field oxide leakage current in n-MOSFET [op] Ionizing radiation in the field oxide isolation structures, i.e. in the Local Oxidation of Silicon (LOCOS), causes positive charge build-up in the bird’s beak region and in nMOSFET it turns on a parasitic lateral leakage paths from source to drain, even if there is no channel formed under the gate. Top view LOCOS 1987 Lateral view 96 Radiation induced field oxide leakage current in n-MOSFET The field oxide form a parasitic field oxide transistor in parallel with the gate oxide transistor: the parasitic field oxide transistor consists of the gate polysilicon, a portion of the filed oxide and the source and drain of the gate transistor LOCOS Parasitic field oxide transistor: large thickness of the field oxide => high VT>0 before irradiation and high VT<0 due to positive charge trapping after irradiation. Contributions to the source-drain current in n-MOSFET with LOCOS isolation before and after irradiation from: -the channel under the gate oxide for the gate oxide transistor; -the parasitic lateral channel under the LOCOS bird’s beak region for the parasitic field oxide 97 transistor. Radiation induced field oxide leakage current in n-MOSFET PA= Annealing: 1 week a 100ºC VT is not a problem but … 300 k 100 k ID(VG=0) 70 k 400 k ID(VG=0) 300 k After annealing . . ., consequently is it a problem for Space? 98 PA= Annealing: 1 week a 100ºC 500 k Radiation induced field oxide leakage current in n-MOSFET Technology node: 130 nm (year: 2005) New technology node: evaluation of its radiation hardness . . . A continuous running to evaluate radiation hardness of new commercial technologies 99 Enhanced Low Dose Rate Sensitivity (ELDRS) in n-MOSFETs In MOSFET technology, the degradation induced by ionizing radiation in field oxides (LOCOS), inducing parasitic leakage current paths from source to drain, estimated by Laboratory testing (high dose rates) even after the 100ºC annealing for 1 week, underestimates the degradation induced by the Space environments (low dose rates): Enhanced Low Dose Rate Sensitivity (ELDRS). ELDRS is due positive charge trapping in the oxide which modify the oxide electric field and the subsequent spatial distribution of the trapped holes (Space Charge effects in the oxide) and lowering the annealing rates at low dose rates. LOCOS 100 Radiation induced field oxide leakage current in n-MOSFET The variation of the shallow insulator thickness at the top corner of the trench can results in very high oxide electric fields: -reduction of the gate oxide integrity; -anomalous humps in the sub-threshold Ids-Vgs characteristic; -limiting the radiation hardness: as the electric field increases, the VT<0 amplitude for the parasitic field oxide transistor increases; -worst case condition "ON": VGS>0, VDS=VBS=0 STI Vfb (red) and contributions from the positive trapped oxide charge (Vox) and from the interface states (Vit) in n-MOSFET, whose gate oxide has been deposited, as for the field oxide in STI, as a function of the electric field inside the oxide. The electric field in the field oxide must be kept lower than 1 MV/cm. 101 Radiation induced field oxide leakage current in n-MOSFET LOCOS How to solve this problem? How to eliminate the parasitic leakage paths from source to drain? Parasitic leakage current path in a n-channel MOSFET transistor with LOCOS design for the gate-field oxide structure due to charge trapping in the oxide (left) and effect on the sub-threshold characteristics (right). 102 n-MOSFET leakage current path mitigation by enclosed layout Solution: change the transistor topology from “Standard" to “Enclosed". Standard layout: leakage current path between source and drain Enclosed layout: no leakage current path between source and drain 103 Radiation induced field oxide leakage current in n-MOSFET Enclosed layout transistor Is it working? 104 Radiation induced field oxide leakage current in n-MOSFET Enclosed layout transistor Disadvantages: 1) area increases by a factor 3.2 for the minimum geometry transistor; 2) avoid sharp corners where the electric field can become large, resulting in undesiderable reliability consequences; 3) which is the effective channel length? The electric field for carriers traversing the device near the corners is variable. 4) Difficulties in modelling: requires the development of a custom cell library. 3) Increased gate and source/drain capacitance. 4) Are not symmetric devices: asymmetry in the output characteristics: dIds/Vds for a fixed Vgs is higher for the drain inside configuration. Chosing the inner ring as drain minimize the drain area and the drain to substrate capacitance. 105 Radiation induced field oxide leakage current in n-MOSFET Effective channel lenght Enclosed layout transistor Real layout (0.25 m node) =0.05 K=3.5 se L 0.5 m K=4 se L>0.5 m ·L c Leff: gate length shortening due to under-diffusion, lithography and etching d d’ 106 Loss of interdevice isolation n-well n-MOSFET Radiation induced hole trapping in thick isolation oxides can drive the channel of parasitic n-type field oxide transistor into inversion (ON) resulting in leakage between adjacent devices and a lack of isolation (n-well and n-MOSFET source) Signal corruption Additional supply current Increase in rail voltage drop How to solve this problem? 107 Loss of interdevice isolation n-well n-MOSFET Radiation induced hole trapping in thick isolation oxides can drive the channel of parasitic n-type field oxide transistor into inversion (ON) resulting in leakage between adjacent devices and a lack of isolation (n-well and n-MOSFET source) Cross-section of a CMOS process with a p+-channel stop implant designed into the isolation field oxide to mitigate the loss of interdevice isolation due to ionizing radiation. The p+-channel stop implant must surround each transistor: area penalty. It can be implemented in CMOS108 technology but the layout rules of the technology must be respected. Loss of interdevice isolation Development of ad-hoc test structures (transistor with a polysilicon gate over the field oxide for isolation between the n-well and the source of the n-MOSFET) Polysilicon gate PA= Annealing: 1 week a 100ºC After annealing . . ., consequently is it a problem for Space? 109 5G. Radiation effects in Silicon on Insulator (SOI) Technology 110 SOI Technology CMOS Standard bulk technology -SOI transistor are built on top of an oxide instead of a silicon substrate. -SOI process technology is similar to standard bulk technology. CMOS Silicon on Insulator Technology (SOI) 20-250 nm 350-400 nm 111 SOI Technology Standard top gate transistor How to measure the Vds-Ids characteristic of the back gate transistor 112 Parasitic back-gate transistor SOI Technology "Partially depleted" SOI technology: the depletion region under the top gate transistor does not extend completely through the p+ body region, there is a non-depleted region between the top gate and the back gate, the top gate transistor and the back gate transistor are not directly coupled, the p+ body region is floating, the top gate transistor characteristics are not directly affected by charge buildup in the buried oxide. Silicon thickness: 100-250 nm "Fully depleted" SOI technology: the depletion region under the top gate transistor extend completely through the p+ body region, there is a fully depleted region between the top gate and the back gate, the top gate transistor and the back gate transistor are directly coupled, the top gate transistor characteristics are directly affected by charge buildup in the buried oxide. Silicon thickness: 20-50 nm Floating body region 113 SOI Technology "Partially depleted" SOI technology: the depletion region under the top gate transistor does not extend completely through the p+ body region, there is a non-depleted region between the top gate and the back gate, the top gate transistor and the back gate transistor are not directly coupled, the p+ body region is floating, the top gate transistor characteristics are not directly affected by charge buildup in the buried oxide. Silicon thickness: 100-250 nm "Fully depleted" SOI technology: the depletion region under the top gate transistor extend completely through the p+ body region, there is a fully depleted region between the top gate and the back gate, the top gate transistor and the back gate transistor are directly coupled, the top gate transistor characteristics are directly affected by charge buildup in the buried oxide. Silicon thickness: 20-50 nm 114 SOI Technology In SOI technologies the parts sensitive to the dose deposited by ionizing radiation are: 1) the gate oxide of the front-transistor (analogous to the bulk CMOS technology, and already considered); 2) the field oxide of the Shallow Trench Isolation (analogous to the bulk CMOS technology, and already considered); 3) the buried oxide of the parasitic back-transistor. The positive charge trapped in the buried oxide of the parasitic back-transistor in n-MOSFET can: -invert the surface of the body region from p-type to n-type causing a parasitic leakage path from the source to the drain of the top gate transistor; -high VT<0 of the parasitic back-transistor (VT becomes negative) which is in the on condition also for VBack Gate=0. 1999 115 SOI Technology The positive charge trapped in the buried oxide of the parasitic back-transistor in n-MOSFET can: -invert the surface of the body region from p-type to n-type causing a parasitic leakage path from the source to the drain of the top gate transistor; -high VT<0 of the parasitic back-transistor (VT becomes negative) which is in the on condition also for VBack Gate=0. Parasitic back gate transistor Top gate transistor (n-MOSFET) 2000 n-MOSFET, Unibond wafer, Co60 -ray irradiation, all terminals grounded during irradiation. 116 SOI Technology SIMOX (Separation by Implanted Oxygen) (Unibond) Smart cut splitting (a) Protons are implanted at 5·1016 cm-2 in Wafer A with has a SiO2 surface layer. (b) Wafer A is bonded on Wafer B by using Van der Waals Force. (a) Deep O ion implantation (b) High temperature annealing (1350 ºC) to form theSiO2 deep layer (c) The top Wafer is removed by thermal activation at 500ºC by forming a cleavage plane. Then High thermal annealing and polishing. High temperature processes cause O diffusion from the buried oxide, leaving oxide defects, which 117 can cause positive charge trapping due to ionizing radiation exposure. SOI Technology Technology node: 0.5 m Oxide thickness for the front gate transistor: tox=12.5 nm Shallow Trench Isolation Unibond wafer Buried oxide thickness: 400 nm Partially depleted Top silicon thickness: 185 nm SIMOX wafer Buried oxide thickness: 370 nm Partially depleted Top silicon thickness: 170 nm 2000 118 SOI Technology Which is the best SOI substrate for radiation hardening? (Minimum threshold voltage variation of the parasitic back gate transistor) 2000 n-MOSFET 0V "0 V": All terminal grounded VS=VD=VG=VBody= 0V "OFF" (Front gate n-MOSFET) VD=VDD All other terminals grounded VS=VG=VBody= 0V Answer . . . . . . . . . . . . . .................... .................... Unibond=Smart cut technology by SOITEC 119 SOI Technology Which is the worst case irradiation condition? (Maximum threshold voltage variation of the parasitic back gate transistor) Gate Source Drain Body Substrate Which is the picture For the "ON" condition? The electric field lines are perpendicular to the equi-potential line: the electric field is from points at high potential (red) to points at low potentials (blue) 120 SOI Technology Which is the worst case irradiation condition? (Maximum threshold voltage variation of the parasitic back gate transistor) "TG" (Transmission bias condition): VS=VD=VDD VG=VBoby=0V "OFF" (Front gate n-MOSFET) VD=VDD All other terminals grounded VS=VG=VBody= 0V "ON" (Front gate n-MOSFET) VG=VDD All other terminals grounded VS=VD=VBody= 0V Answer . . . . . . . . . . . . . .................... .................... n-MOSFET, Unibond wafer, Co60 -ray irradiation, all terminals grounded during irradiation. 121 SOI Technology "Fully depleted" SOI technology: the depletion region under the top gate transistor extend completely through the p+ body region, there is a fully depleted region between the top gate and the back gate, the top gate transistor and the back gate transistor are directly coupled, the top gate transistor characteristics are directly affected by charge buildup in the buried oxide. The positive charge trapped in the buried oxide of the parasitic back-transistor in fully depleted n-type MOSFET can cause a decrease in the threshold voltage of the top gate transistor: more sensitive to radiation than “Partially depleted" SOI devices. In advanced "Fully depleted" SOI devices with gate length in the range of several tens of nanometers a radiation-induced high current regime from source to drain can exist in floating body devices, both at low and high drain voltages. This high current regime is attributed to a floating body effects and is sometimes refereed to as "Total dose latch" or "Total dose snap back effect". An external body contact in the device prevents the onset of this high leakage current regime from source to drain. 122 SOI Technology source N+ source N+ drain N+ p+ body p+ body drain N+ p+ body 123 SOI Technology Improving the radiation hardness of the buried oxide by technology by Silicon ion implantation. -The Silicon ion implantation creates in the buried oxide electron traps, which can be filled during irradiation by ionizing radiation, so compensating the positive trapped charge. Improving the radiation hardness by new device layout. -In the BUSFET (Body-Under-Source-Field-Effect-Transistor), the source penetrates only partially through the top silicon layer, and is isolated from the buried oxide by the body silicon region which is also contacted by the p+ body contact. The inverted n-type layer at the buried oxide surface can not create a parasitic leakage path from source to drain. SOI n-MOSFET without body contact SOI n-BUSFET with body contact 124 Radiation-hard vs Commercial Technologies Commercial vs Radiation-Hard technologies (MIPS=Million of Instructions Per Second) 125 Test 126 Test: domande 1-5 1) Descrivi gli effetti della radiazione ionizzante (carica positiva intrappolata nell’ossido e generazione di stati interfacciali) sulla caratteristica Ids-Vgs di un transistor MOSFET a canale p e di un transistor MOSFET a canale n. 2) Dopo aver descritto l’effetto dell’annealing sulla carica positiva intrappolata nell’ossido e sulla generazione di stati interfacciali per un MOSFET a canale n e per un MOSFET a canale p, descrivi cosa si intende per effetto "Rebound" in un MOSFET a canale n. 3) Descrivi dal punto di vista microscopico il modello per l’intrappolamento e l’annealing della carica positiva nel SiO2 tenendo presente l’importanza della vacanza dell’ossigeno e del centro E'. Descrivi dal punto di vista microscopico il modello per la generazione degli stati interfacciali a partire dal centro Pb0 passivato dall’idrogeno. 4) Descrivi sinteticamente l’effetto ELDRS (Enhanced Low Dose Rate Sensitivity) nei BJT 5) Perchè con lo scaling down delle tecnologie, l’ossido di gate dei MOSFET diventa intrinsecamente meno sensibile agli effetti da dose totale della radiazione ionizzante? 127 Test: domande 6-10 6) Quali sono le differenze tra la conduzione di Fowler-Nordheim, per tunneling assistito da trappole e per tunneling diretto attraverso l’isolante SiO2, e per quali spessori di ossido tali tipi di conduzione sono rilevanti? 7) Che cosa si intende per RILC, RSB, RHB? 8) Descrivi gli effetti del danno da dose totale indotti dalla radiazione ionizzante negli ossidi di isolamento LOCOS dei MOSFET a canale n e le conseguenze sulle caratteristiche Igs-Vds. Quali sono le tecniche di layout per prevenire tali effetti? 9) Descrivi gli effetti del danno da dose totale indotti dalla radiazione ionizzante negli ossidi di isolamento tra dispositivi MOSFET. Quali sono le tecniche di layout per prevenire tali effetti? 10) Dopo aver descritto le principali caratteristiche della tecnologia CMOS SOI, evidenziando le differenze rispetto alla tecnologia CMOS Bulk, indica gli effetti da dose totale indotti dalla radiazione ionizzante con particolare riguardo all’attivazione del transistor parassita sul backside e alle tecniche di layout per prevenire l’attivazione di tale transistor parassita. 128 Note -Il materiale, la cui raccolta e organizzazione ha richiesto un notevole impegno, può essere utilizzato liberamente per fini di studio e ricerca, se possibile citandone la fonte e le referenze. -Ringrazio tutti coloro che mi segnaleranno parti da correggere/migliorare. 129 Riassunto 130 Ionizing radiation in SiO2: p-MOSFET threshold voltage VT<0: channel of holes 131 Ionizing radiation in SiO2: n-MOSFET threshold voltage VT>0: channel of electrons 132 Ionizing radiation in SiO2 and defect generation mechanisms 14 orders of magnitude for time: 1 day: 8.6·104 s 1 week: 6.05 · 105 s 1 month: 2.6 ·106 s 1 year: 3.15·107 s Initial hole yield: geminate and columnar recombination models Geminate recombination model (can be applied for electron and Co60 irradiation): a) The average separation distance between electron-hole pairs is higher than the thermalization distance. b) The interaction between electron and hole of an isolated pairs is due to Coulomb attraction. c) Electrons and holes drifts in opposite direction due to the electric field. d) Electrons and holes moves randomly due to thermal fluctuations of the system. c) The interactions with other electron-hole pairs can be neglected. Columnar recombination model (can be applied for heavy ions (Z>1)): a) The average separation distance between electron-hole pairs is lower than the thermalization distance: there are several electrons closer to any given hole than the electron, which was its original partner. b) The recombination probability is higher for the columnar model than for geminate model. 134 Initial hole yield: geminate recombination model Geminate recombination model (can be applied for electron and Co60 irradiation): a) The average separation distance between electron-hole pairs is higher than the termalization distance. b) The interaction between electron and hole of an isolated pairs is due to Coulomb attraction. c) Electrons and holes drifts in opposite direction due to the electric field. d) Electrons and holes moves randomly due to thermal fluctuations of the system. c) The interactions with other electron-hole pairs can be neglected. V E d 1 MV 100 nm cm 106V 1 105 cm 10V cm -The fraction yield for holes . . . . . . by increasing the oxide electric field. -The maximum value of the fraction yield for holes at 2.5 MV/cm is . . . -At 1 MV/cm the fraction yield for holes is . . . 135 Initial hole yield: columnar recombination model Columnar recombination model (can be applied for heavy ions (Z>1)): a) The average separation distance between electron-hole pairs is lower than the termalization distance: there are several electrons closer to any given hole than the electron, which was its original partner. b) The recombination probability is higher for the columnar model than for geminate model. 2 MeV particle B is the radius at half-maximum for the Gaussian charge distribution of the 2 MeV particle: i.e. 1.178·. V E d 1 MV 100 nm cm 106V 1 105 cm 10V cm -The fraction yield for holes . . . . . . by increasing the oxide electric field. -The maximum value of the fraction yield for holes at 2.5 MV/cm is . . . -At 1 MV/cm the fraction yield for holes is . . . 136 Initial hole yield for different radiations The fractional yield for holes as a function of the proton energy: -at low proton energy: columnar model -at high proton energy: geminate model Linear Energy Transfer for different radiations (values for 10 keV X-rays and Co60 -rays are for primary electrons) [2002]: - geminate model applied at low dE/dx; - columnar model applied at high dE/dx; -10 keV X-rays simulates 20-60 MeV protons; - Co60 -rays simulates 1 MeV electrons; 137 The positive charge oxygen vacancy -The bonding between the two Si atoms of the Vo defect can be broken by exciting a bonding electron to the SiO2 conduction band or by hole trapping. -The new defect, is called positive charged oxygen vacancy (Vo+). It is represented by the chemical formula: O3Si°SiO3, where the symbols "" and "°" are the unpaired electron and the trapped hole, respectively. -The Vo+ center is positive charged (°SiO3) and paramagnetic (O3Si). It can be characterized by the electron-spin-resonance (ESR) technique. The paramagnetic part of the Vo+ defect is called E' center. The positive charged oxygen vacancy defect. The arrow indicates the unpaired electron of the neutral Si atom. The Vo+ defect is strongly correlated to the positive charge induced by ionising radiation. 138 Defect classification in SiO2 -Location: oxide traps, border traps and interface traps -Electrical behavior: fixed states (positive and negative charge or neutral) switching states (can exchange charge by tunneling) Gate tox bulk contact The MOS capacitor. The classification of the defects in the SiO2/Si system, depending on their location (a) and electrical behaviour (b). 139 Interface states -The Pb center is a trivalent Si defect at the SiO2/Si interface: i.e., a silicon atom bonded to three other Si atoms with an unpaired electron in an orbital pointing out to a vacancy. It is represented by the chemical formula Si3Si. -The Pb defect is amphoteric, that is its charge condition can be positive, negative or neutral. Pb: Si3Si Pb- : Si3Si (acceptor) qB Pb: Si3Si Pb+ : Si3Si° (donor) The donor (close circles) and acceptor (open circles) Pb centers in the Si band-gap at midgap condition for a MOS on n-Si substrate. 140 Ionizing radiation in SiO2: summary (a) Before irradiation. (b) During irradiation: electrons and holes are generated by ionizing radiation. (c) Electrons are sweep out in picoseconds, under Vg>0 holes slowly moves to the SiO2/Si interface. (d) Holes are trapped in SiO2 close to the SiO2/Si interface. Interface states are created at the SiO2/Si interface. Effects of the positive oxide trapped charge and of the charge trapped in the interface states on the threshold characteristics of p-MOSFET and n-MOSFET. 141 Device scaling 142 The conduction through ultra-thin (<3 nm) SiO2 layers -The direct tunnel effect is relevant for ultra-thin (<3 nm) SiO2 layers: electrons tunnel from gate to the SiO2 conduction band through the trapezoidal potential barrier directly to the Si substrate. Is there any implication for technology and radiation hardness? V<0 VAl<0 VSi=0 <3 nm Al Ef,m EC Ef,Si Ei - SiO2 Si EV + Al SiO2 Si MOS capacitor with a negative gate voltage applied, and the corresponding band diagram 143 showing the direct tunneling conduction mechanism (right). The conduction through thin (3 nm<TSiO2<6 nm) SiO2 layers 1) The trap assisted tunneling (TAT) is the tunnel effect by a defect in the SiO2 layers. 2) TAT is active at lower voltages than the Fowler-Nordheim (FN) conduction because TAT is through a trapezoidal potential barrier, while FN is through a triangular potential barrier. 3) The electron tunneling distance is 3 nm: TAT cannot be observed for oxide thickness than 6 nm. V<0 VAl<0 VSi=0 Oxide trap 6 nm Al Ef,m EC Ef,Si Ei - SiO2 Si EV + Al SiO2 Si MOS capacitor with a negative gate voltage applied, and the corresponding band diagram 144 showing the trapped assisted tunneling (TAT) conduction mechanism (right). Radiation induced field oxide leakage current in n-MOSFET The field oxide form a parasitic field oxide transistor in parallel with the gate oxide transistor: the parasitic field oxide transistor consists of the gate polysilicon, a portion of the filed oxide and the source and drain of the gate transistor LOCOS Parasitic field oxide transistor: large thickness of the field oxide => high VT>0 before irradiation and high VT<0 due to positive charge trapping after irradiation. Contributions to the source-drain current in n-MOSFET with LOCOS isolation before and after irradiation from: -the channel under the gate oxide for the gate oxide transistor; -the parasitic lateral channel under the LOCOS bird’s beak region for the parasitic field oxide 145 transistor. Radiation induced field oxide leakage current in n-MOSFET Enclosed layout transistor Is it working? 146 SOI Technology CMOS Standard bulk technology -SOI transistor are built on top of an oxide instead of a silicon substrate. -SOI process technology is similar to standard bulk technology. CMOS Silicon on Insulator Technology (SOI) 20-250 nm 350-400 nm 147 SOI Technology Standard top gate transistor How to measure the Vds-Ids characteristic of the back gate transistor 148 Parasitic back-gate transistor SOI Technology In SOI technologies the parts sensitive to the dose deposited by ionizing radiation are: 1) the gate oxide of the front-transistor (analogous to the bulk CMOS technology, and already considered); 2) the field oxide of the Shallow Trench Isolation (analogous to the bulk CMOS technology, and already considered); 3) the buried oxide of the parasitic back-transistor. The positive charge trapped in the buried oxide of the parasitic back-transistor in n-MOSFET can: -invert the surface of the body region from p-type to n-type causing a parasitic leakage path from the source to the drain of the top gate transistor; -high VT<0 of the parasitic back-transistor (VT becomes negative) which is in the on condition also for VBack Gate=0. 1999 149 SOI Technology Improving the radiation hardness of the buried oxide by technology by Silicon ion implantation. -The Silicon ion implantation creates in the buried oxide electron traps, which can be filled during irradiation by ionizing radiation, so compensating the positive trapped charge. Improving the radiation hardness by new device layout. -In the BUSFET (Body-Under-Source-Field-Effect-Transistor), the source penetrates only partially through the top silicon layer, and is isolated from the buried oxide by the body silicon region which is also contacted by the p+ body contact. The inverted n-type layer at the buried oxide surface can not create a parasitic leakage path from source to drain. SOI n-MOSFET without body contact SOI n-BUSFET with body contact 150