Moisture Diffusion in Molding Compounds and Quality

Assurance of PEMs for Space Applications

Alexander Teverovsky

QSS Group, Inc./Goddard Operations

Alexander.A.Teverovsky.1@gsfc.nasa.gov

MRQW Dec '02 2

No humidity in space. Why moisture concerns?

We need to assure that no moisture related

failures occur during the ground phase

integration and testing period (2 to 5 years).

Quality assurance strategy for PEMs: Moisture prevention Adequate qualification testing

MRQW Dec '02 3

Quality assurance strategy for PEMs for military and space applications

Moisture prevention strategy: Military applications: Wafer Applied Seal for PEM Protection (WASPP);Space applications: Virtual monitoring/simulation of the moisture level variations and baking of components and assemblies.

Adequate testing: Military applications: To assure reliability for 15 to 20 years of storage and operation in harsh humid environments.Space applications: To assure reliability for 5 years maximum in controlled laboratory conditions.

MRQW Dec '02 4

Purpose and Outline

The purpose is to discuss:

Moisture characteristics of MCs and how they can be used for the moisture prevention strategy and for development of adequate testing.The relevance of HAST for PEMs intended for space applications.

Outline:

Part I:• Bake-out conditions for PEMs;• Diffusion characteristics of molding compounds .

Part II:• Acceleration factors of HAST. • What might be an adequate testing?

MRQW Dec '02 5

Part I. Moisture Diffusion Characteristics and Their Measurement

The first step in any MC or PEM degradation process is moisture

diffusion. The characteristic times of

diffusion are important for implementing the moisture prevention strategy.

MRQW Dec '02 6

Characteristic times of moisture diffusion in plastic encapsulated parts

0

0.2

0.4

0.6

0.8

1

0.001 0.01 0.1 1 10

time, t/

C/C

o, M

/Mo

C/Co

M/Mo

Moisture concentration at the die surface and mass losses of a flat package with rated

baking time.

At t = C/Co=0.1,

M/Mo=0.06

Bake-out time:

(T) = h2/D(T)

Bake-out time:

(T) = h2/D(T)

2h – package thickness

The master curve for moisture diffusion

MRQW Dec '02 7

Diffusion characteristics of epoxy encapsulating materials

180 140 120 100 80 60 40 20 T, oC

1.E-14

1.E-13

1.E-12

1.E-11

1.E-10

1.E-09

2 2.2 2.4 2.6 2.8 3 3.2 3.4 3.6 3.8

reciprocal temperature, 1000/K

D, m

2 /s

{1}{3}{4}{5}{6}{7}{7}{8}HCEMEpoliset

U = 0.43 eV )/exp( kTUDD o )/exp( kTUDD o

Averaged characteristics of MC:

Do = 7.3510-6 m2/sec

U = 0.43 eV

Averaged characteristics of MC:

Do = 7.3510-6 m2/sec

U = 0.43 eV

Data reported in literature.

D85 varies ~ 10 times

MRQW Dec '02 8

Calculated bake times at 125 oC and JEDEC recommendations

Three body thickness groups per IPC/JEDEC J-STD-033A, July 2002:

<1.4 mm; <2 mm;< 4.5 mm

•Ignoring real size of the parts causes significant errors.

•JEDEC is focused on SMT reflow soldering and might be not adequate for moisture control purposes.

•Ignoring real size of the parts causes significant errors.

•JEDEC is focused on SMT reflow soldering and might be not adequate for moisture control purposes.

Note: •2a and 5a are levels

of moisture sensitivity.•part saturated at

30 oC/85% RHIPC-SM-786A, ’95: < >2 mm

0

10

20

30

40

50

60

70

80

0 1 2 3 4 5

package thickness, mm

Ba

ke

tim

e, h

r

JEDEC_2a

JEDEC_5a

calculation

MRQW Dec '02 9

In-situ non-isothermal technique for D(T) measurements

Areas of application Moisture sorption simulation (virtual monitoring of

moisture level). Calculation of bake-out conditions. Lot characterization of molding compound.

(ROBOCOTS: need rapid assessment methods) Evaluation of moisture leaks along the leads of a

plastic package. Development of adequate moisture stress testing

(HAST alternative).

A. Teverovsky, “A Rapid Technique for Moisture Diffusion Characterization of Molding Compounds in PEMs“, http://nepp.nasa.gov

MRQW Dec '02 10

Part II. Highly Accelerated Stress Test (HAST)

Do we need to use same environmental stress testing as for PEMs intended for

harsh humid conditions?

MRQW Dec '02 11

Accelerated moisture resistance tests

JESD22-A102-C (unbiased autoclave):

121 oC, 100% RH, 24 to 336 hrs (96 hr typical).

JESD22-A118 (unbiased HAST): Cond. A: 130 oC, 85% RH, 96 hrs. Cond. B: 110 oC, 85% RH, 264 hrs.

JESD22-A110-B (biased HAST): Cond. A: 130 oC, 85% RH, 96 hrs. Cond. B: 110 oC, 85% RH, 264 hrs.

Typical HAST conditions: bias at 130 oC, 85% RH96 hrs per JESD22-A110-B.150 hrs per NAVSEA SD18 (Part Requirement & Application

Guide).500 hrs per PRF38535 spec. (for technology characterization).

NASA projects: 250 hrs?

Equivalent to 1000

hours at 85 oC and 85% RH

MRQW Dec '02 12

HAST failure mechanisms

Package levelCorrosion of the leads.

Dendrite formation (on the surface and inside packages).

Swelling/shrinkage:Delaminations;Solder ball failures in PBGA

and flip-chip technology;warpage of large packages;parametric shifts in linear

devices.

-400

-200

0

200

400

0 20 40 60 80 100

relative humidity, %d

V/V

, pp

m

MRQW Dec '02 13

HAST failure mechanisms

Die level:Corrosion of Al metallization.Dendrites between

metallization lines.Leakage currents.Charge instability (lateral, ion

drift, hot electron).

1.E-12

1.E-10

1.E-08

1.E-06

1.E-04

0 2 4 6 8 10 12 14 16 18

gate voltage, V

gat

e cu

rren

t, A

1.E-12

1.E-10

1.E-08

1.E-06

1.E-04

1.E-02

1.E+00

-2.5 -1.5 -0.5 0.5 1.5 2.5

Vg, V

IDS

, A

Curtsy of C.Greenwell

HEXFET failures

Mechanisms of moisture induced

parametric degradation require additional analysis

Mechanisms of moisture induced

parametric degradation require additional analysis

MRQW Dec '02 14

What is the HAST acceleration?

Life time at 25 oC/ 60% ambient conditions

equivalent to HAST: 130oC/85% 100 hrs)

0

100

200

300

400

500

600

700

10 20 30 40 50 60 70

device temperature, oC

life

time,

yea

rs

0

10

20

30

40

50

60

70

80

90

effe

ctiv

e R

H, %

Best-fit model:S. Peck [86];Hallberg and Peck [91];S. Tam [95]; SSB-1 [2000];J. Sweet [02]:

kTERHAt an

f exp)(

Life time increases with device temperature

Life time increases with device temperature

Ea = 0.8 eV; n = 2.7Ea = 0.8 eV; n = 2.7

)(

)(

devs

asaeff TP

TPRHRH

0.7 < Ea < 1.1 eV;

1 < n < 5

MRQW Dec '02 15

Test results on linear devices

Part DC Pack.type

QTYtested

QTYfaile

d

Failuremode

Vref 0112 SOIC8 31 3

1- increased Vout

2 - catastrophic

Opamp

0101 SOIC16 30 2 -

Instr. amp 0033 SOIC8 30 30 Excessive

input currents

FET1 0041 SOT223 29 28 IDS, VGTH

FET2 0040 D2Pak 30 29~ 60%

parametric shift

HAST: 130 oC, 85% RH, 250 hours

11 part types out of 25 failed HAST

11 part types out of 25 failed HAST

MRQW Dec '02 16

Is HAST adequate for normal conditions?

Testing temperature (130 oC) is above the operational range for many parts.

Degradation of molding compound: Decrease of Tg (up to 100 oC in resins and up to

30 oC in MCs). Enhanced creep. Decrease of the tensile stress and adhesion.

The model accelerates mostly corrosion failures, but corrosion is no longer a prime concern.

Moisture assisted hot-carrier degradation mighthave U < 0.

MRQW Dec '02 17

Irreversible changes in MCs: An example

00.20.40.60.8

11.21.41.61.8

bake 85 deg.C 110 deg.C 130 deg.C 150 deg.C bake

mas

s/vo

lum

e de

viat

ion,

%

MC1_m

MC1_v

MC2_m

MC2_v

bake: 125 deg.C for 96 hr

dM

dV

Test: moisture uptake and swelling after HAST were measured on two epoxy molding compounds.

Conditions: saturation with moisture at 85% RH and different temperatures.

Additional mechanical stresses due to swelling: AE[(MC - LF)T + m], At MC LF mechanical stresses are due only to moisture sorption.

An increase in volume might cause delaminations and mechanical failures.

MRQW Dec '02 18

Do we need moisture testing?

Ionic dissociation in polymer: Charge carriers are impurity ions generated by dissociation of a salt MAThe equilibrium constant: no is the concentration of salt molecules; f is the fractional degree of dissociation

AMAM

f

nf

AM

AMK

1

][][ 02

kT

UKK

0

0 expIn a medium with low : Uo is the energy of ions separation in vacuum

kT

UAn

2exp 0 2. Another reason:

Moisture activates ionic impurities similar to temperature. Moisture

testing might accelerate degradation mechanisms related to charge

instability.

2. Another reason:Moisture activates ionic impurities

similar to temperature. Moisture testing might accelerate degradation

mechanisms related to charge instability.

w

mcwmcmcmc m

~

~0

1. Moisture concentration

at the die surface at RT is approximately the same as at

high T/RH conditions.

1. Moisture concentration

at the die surface at RT is approximately the same as at

high T/RH conditions.

MRQW Dec '02 19

A possible alternative to HAST: MS + HTB

Soaking in humidity

chamber for 48 hrs at

110 oC and 85% RH

Note: C/Co = 1 corresponds to the equilibrium moisture saturation at 100% RH.

Testing at 85 oC.

0

0.1

0.2

0.3

0.4

0.5

0.6

0.7

0.8

0.9

0.01 0.1 1 10 100

time, hr

C/C

o,

M/M

o C/Co soaking

M/Mo soaking

C/Co testing

M/Mo testing

Moisture evolution in a 2 mm thick package

MRQW Dec '02 20

Calculated test time and equivalent time of operation

0

5

10

15

20

25

30

60 70 80 90 100 110

test temperature, oC

test

tim

e, h

r

0

1

2

3

4

5

6

7

equ

ival

ent

time,

yea

r

Soaking conditions:RH = 95%,T = 110 oC,

t = 30 hr

Test conditions:RHeff 90%

70 oC < T < 105 oCOperating conditions

(environment):RH =50%T = 20 oCPackage thickness 2 mm

MRQW Dec '02 21

HAST alternative: MS + HTB testing

Input: Package size; D(T) data; ground phase conditions; maximum storage and operation temperatures.

Set RH and T for MS conditions

MS + HTB Test conditionsMS + HTB Test conditions

C(t) simulation

Estimate MS time

Set T for HTB conditions

Calculate A and

C(t) simulation

Estimate HTB time

Is A & suitable?

Algorithm for calculation of MS+HTB testing conditions

+-

MRQW Dec '02 22

ConclusionSuggested quality assurance strategy: moisture content control (virtual monitoring and baking) + adequate testing.The moisture prevention strategy can be implemented by assessment of moisture content and calculations of the bake-out conditions based on D(T) data. The existing HAST conditions are too harsh for PEMs intended for space applications. A possible alternative to HAST might be MS + HTB testing. Additional analysis of moisture induced parametric degradation and acceleration factors is necessary.