UMC 0.18µm radiation hardness studies Sven Löchner CBM

UMC 0.18µm radiation hardness studies
Sven Löchner
CBM-XYTER Family Planning Workshop
GSI Darmstadt
December 5th, 2008
Experiment Electronics
Agenda
• GRISU chip project
– Overview
• Single Event Effects test
–
–
–
–
Mechanism
Testability
Results
Summary
• Total Ionising Dose test
–
–
–
–
Pre-radiation test
Measurements after radiation
Annealing
Summary
December 5th, 2008
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GRISU project
Project objectives:
• Characterisation of UMC 0.18µm CMOS process concerning
the vulnerability against Single Event Effects (SEE), especially
Single Event Upsets (SEU) and Single Event Transients (SET)
– SEU cross section for different Flip-Flop designs and layouts
– Characterisation of the critical charge Qcrit respectively the
Linear Energy Transfer (LETcrit )
– SET sensitivity of the UMC 0.18µm process
• Single Transistor measurements
– Comparison of transistor models by simulation
– Total Ionising Dose (TID)
Characterisation of the UMC 0.18µm process under irradiation,
especially leakage currents, threshold shifts, annealing, ...
December 5th, 2008
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GRISU test ASIC
GRISU 1 chip
• UMC 0.18µm process
• 1.5 x 1.5 mm²
• 64 pads
– 28 core pads
– 36 pads
•
Test structures
for SEU
measurements
First tape out:
02/2007
Ring oscillator
for TID / SEU
measurements
Test structures
for TID
measurements
Test structures
for SET
measurements,
Qcrit
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GRISU 2 test ASIC
GRISU 2 chip
like previous version, but
• Modified LVDS receiver
• Test structures
– now with ESD
protection at gate
– one new transistor layout
• Second ring oscillator with
different W and L of inverters
Tape out 02/2008
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Single Event Effects (SEE)
SEE: two types of categories
• Cause of permanent damages (hard errors)
• Induce of temporary malfunctions (soft errors)
Only soft errors are analysed, especially:
• Single Event Upsets (SEU)
Bit flips, e.g. change of states in the digital logic
• Single Event Transient (SET)
Temporary change of the signal level in the circuit, e.g. a glitch
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Linear Energy Transfer (LET)
• Minimum amount of particle energy induced to a semiconductor device at which a SEE appears is called LETcrit
• The unit of LET is typical MeV·cm²/mg (related to Si for MOS)
LETcrit
3.6eV ⋅ Qcrit
=
e ⋅ ρ Si ⋅ d
d - sensitive depth of penetration
ρ - material density (Si: 2.33g/cm3)
Typical values for 0.18µm process technology:
• d = 0.5 ... 2µm
• Qcrit = 30 ... 60fC
=> LETcrit between 1.5 and 12 MeV·cm²/mg
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SEE Building Blocks
3 different building blocks for SEE characterisation:
• Test structures for SEU measurements
– 8 different types of flip-flops implemented, e.g. oversized flipflops, flop-flops with Dual Interlock Cell (DICE) architecture, ...
• Test structures for SET and Qcrit measurements
– Different inverter chains
=> Qcrit,sim from 20 ... 1000fC
• 2 ring oscillator test structure
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SEE Testability at GSI
SEE test with heavy ions => two possibilities at GSI:
• Low Energy
– 11.4 MeV / AMU
– 103 ... 1010 p/(cm·s)
– bunches of up to 5ms “length”, frequency up to 50Hz
– different ions (C, Ni, Xe, U, ...)
– low penetration depth
=> only usable for unpackaged chips
• High Energy
– 50 ... 2000 MeV / AMU
– 100 ... 1012 p/(cm2)
– different ions (C, Ni, Xe, U, ...)
– high penetration depth
=> usable for all un-/packaged chips
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Low Energy testing site
• Installation of a test facility for ASIC irradiation with heavy ions
at X6 cave at GSI (in cooperation with bio physics group)
• Beam monitoring via
ionisation chamber
• Dosimetry setup available
• Irradiation of DUT in air
• Easy access
Disadvantages of setup:
• Only one ion source
during beam time
• “Fixed” LET range for ion source
December 5th, 2008
•X6 cave at GSI
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Simulation of C-12
But:
• Setup is movable along
beam axis
• Air is used as energy
degrader
• Simulation of LET for C-12
– including complete setup
– ionisation chamber
– chip material
• Max range is 41cm from
exit window
• LET from 1.5 ... 5 MeV·cm²/mg possible
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Simulation of Ni-58
• Maximum range is only
11cm
• LET from 15 ... 30
MeV·cm²/mg possible
For characterisation of the
LET cross-section several
irradiation test with different
ion sources are necessary.
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SEE Test setup
• Hardware: Xilinx Spartan-3E Starter Kit board
–
–
–
–
control unit is in the cave
programming of GRISU memory
readout of memory after irradiation
frequency measurement of
ring oscillators
– counting of ionisation chamber
pulses
– pre-analysing of test data
– sending data to control room
• Controlling the test setup via
LabVIEW
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Cross-section results (Weibull-Fit)
SET cross-section measurement for a minimum size inverter
data from C-12
(2..5 MeV cm²/mg)
and Ni-58
(10..30 MeV cm²/mg)
=> LETcrit =
1.94 MeV cm²/mg
=> σsat =
1.62 10-8 cm²/bit
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SEE Summary
• Setup a heavy ion test environment for ASIC irradiation
at low energies
• Successful operation of 5 heavy ions beam times
with different ion sources
Still to do:
• Analysing data from last beam time
(=> more cross-section points, specially for higher LETs)
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GRISU 2 – test structures
• Access to single transistors via core pads
– small pad geometry
– close to neighbour test pads
=> Bonding challenge
• Automatic measurement of all 16 transistors
– Output characteristic (Uds – Ids)
– Transfer characteristic (Ugs – Ids)
• Controlled via LabVIEW
• Around 15 minutes for a complete characterisation
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GRISU 2 – test structures
Transfer function for a minimum size NMOS (0.24 / 0.18) at
Uds = 0.1V
=> problem to simulate this behaviour with the existing models
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Total Irradiation Dose (TID) tests
• TID testing with X-rays
• Irradiation facility at Institute for Experimental Nuclear Physics,
University of Karlsruhe
• 60keV X-ray
• 100 ... 600krad/h
• Thanks to Mr. Dierlamm
and Mr. Simonis
for support
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TID tests
•
•
•
•
9 GRISU chips irradiated
Total dose between 800krad and 2500krad(SiO2)
Operating dose rate between 200krad/h and 580krad/h
Two modes of operation
– single transistor test structure measurements
leakage current, threshold shift, characteristics (offline)
– complete chip measurements
frequency of ring oscillator, total power consumption (online)
December 5th, 2008
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TID tests – complete chip
Measurement of two ring oscillators on GRISU 2 test chip
• Total dose: 1.5Mrad
– at 490krad/h
• Decrease of the transit time
– ~ 4% for minimum size inv.
– ~ 10% for up-sized inv.
• Good annealing at room
temperature
– for min. size: even faster
• Up to 250krad:
– min. size inverter gets faster
– up-sized inverter keeps stable
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TID tests – complete chip
Measurement of power consumption on GRISU 2 test chip (core)
• Total dose: 1.5Mrad
– at 490krad/h
• Increase of the core power
consumption
– from 10mA (pre-rad) to
22mA (1.5Mrad)
• Annealing at room temp.
– power consumption back to
pre-radiated value after
6 weeks
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TID tests – complete chip
Measurement of power consumption on GRISU 2 test chip (pad)
• Total dose: 1.5Mrad
– at 490krad/h
• Increase of the pad power
consumption
– from 1mA (pre-rad) to
105mA (1.5Mrad)
• Annealing at room temp.
– power consumption also
back to pre-radiated value
after 6 weeks
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TID tests – single transistors
Measurements of the transistor characteristics and calculation of
the threshold voltages for different dose levels
(e.g. NMOS 0.24/1.80)
• In total 6 chips are irradiated
• Total dose up to 2.5Mrad
• Decrease of threshold voltage
– ~ 20% after 1Mrd
– no further change
after 1Mrad
December 5th, 2008
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TID tests – single transistors
Measurements of the transistor characteristics and extraction of
the leakage current for different dose levels
(e.g. NMOS 0.24/1.80)
• In total 6 chips are irradiated
• Total dose up to 2.5Mrad
• Increase of leakage current
– no significant increase up to
200krad
– by 3 orders of magnitude
after 2.5Mrad
December 5th, 2008
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TID tests – single transistors
Measurements of the annealing and calculation of the threshold
voltage for different dose levels (e.g. NMOS 0.24/1.80)
• Detailed annealing scans
only with one 1 chip
• 2.5Mrad total dose
• Annealing at room temp.
• Increase of threshold voltage
after 6 weeks
– still 10% under pre-radiation
value
– but no saturation reached
(maybe further increase possible)
December 5th, 2008
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TID tests – single transistors
Measurements of the annealing and extraction of the leakage
current for different dose levels (e.g. NMOS 0.24/1.80)
• Detailed annealing scans
only with one 1 chip
• 2.5Mrad total dose
• Annealing at room temp.
• Decrease of leakage current
after 6 weeks
– almost back to pre-rad value
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TID summary
• Final analyse of measured data
• UMC process shows good annealing at room temperature
(at least at high dose rates)
– maybe a second irradiation campaign with low dose rates
– long term test with a gamma source
• Simulation models slightly differs from measured
characteristics (especially between small and large Ugs)
• Not shown:
– Offset current for zero-Vth transistors are much higher than
predicted from simulation
– measured transition time for minimum size inverters differs ~40%
from simulation
• ...
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Thank you
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Additional Transparencies
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Charge collection
cross-section through an ASIC
December 5th, 2008
charge collection under the gate
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GRISU 2 – test structures
4 groups with each 4 single transistor test structures
NMOS transistors
Zero-Vt transistors
Low-Vt transistors
Enclosed transistors
Enclosed Zero-Vt
Finger transistor (10x)
PMOS transistors
Enclosed PMOS transistor
Finger transistor (10x)
December 5th, 2008
W = 0,24 µm
L = 1,80 µm
W = 2,40 µm
L = 0,18 µm
W = 0,24 µm
L = 0,18 µm
W = 2,40 µm
L = 1,80 µm
W = 2,40 µm
L = 3,00 µm
W = 0,24 µm
L = 0,30 µm
W = 0,24 µm
L = 0,24 µm
W = 2,40 µm
L = 2,40 µm
W = 2,28 µm
L = 0,18 µm
W = 6,70 µm
L = 1,80 µm
W = 4,48 µm
L = 0,30 µm
W = 10*0,24 µm L = 0,18 µm
W = 2,40 µm
L = 1,80 µm
W = 0,24 µm
L = 0,18 µm
W = 6,70 µm
L = 1,80 µm
W = 10*0,24 µm L = 0,18 µm
W/L = 0,13
W/L = 13,33
W/L = 1,33
W/L = 1,33
W/L = 0,80
W/L = 0,80
W/L = 1,00
W/L = 1,00
W/L = 12,67
W/L = 3,72
W/L = 14,93
W/L = 13,33
W/L = 1,33
W/L = 1,33
W/L = 3,72
W/L = 13,33
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Dual Interlock Cell (DICE)
DICE (Dual Interlock Cell)
memory technologies are
(more or less) immune
against SEU flips.
Reference:
T. Calin, M. Nicolaidis, R. Velazco
Upset Hardened Memory Design for
Submicron CMOS Technology
IEEE Transactions on Nuclear Science,
Vol. 43, No. 6, December 1996
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GRISU 2 – test structures
Output characterisation of a minimum size NMOS transistor
(0.24 / 0.18) at Ugs = 0.6V (left) and Ugs = 1.5V (right)
Discrepancies between measurements and simulations.
December 5th, 2008
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Vth – simulation vs. measurement
Threshold measurement for all test structures.
Tendency to higher threshold values for all test
structures is visible.
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