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Simplified Thermal Stress Analysis

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Simplified Thermal Stress Analysis Reference: Sergent, J., and Krum, A., Thermal Management Handbook for Electronic Assemblies, McGraw-Hill, New York, 1998. – PowerPoint PPT presentation

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Title: Simplified Thermal Stress Analysis


1
Simplified Thermal Stress Analysis
  • Reference Sergent, J., and Krum, A., Thermal
    Management Handbook for Electronic Assemblies,
    McGraw-Hill, New York, 1998. Chapter 7
  • Another helpful source Vaynman, S., Mavoori, H.,
    Chin, J., Fine, M.E., Moran, B, and Keer, L.M.,
    Stress management and reliability assessment in
    electronic packaging, National Electronic
    Packaging and Production Conference--Proceedings
    of the Technical Program (West and East), v 3,
    1996, p 1711-1726.

2
TCE
  • Problem when one material is bonded to another
    with a much smaller temperature coefficient of
    expansion (TCE)
  • ETCExDT
  • Estrain (length/length)
  • DTtemperature differential across sample
  • SEY
  • Sstress (psi/in or Pa/m)
  • Ymodulus of elasticity (lb/in2 or Pa)
  • When total stress (Smax dimension of sample)
    exceeds tensile strength, cracks will form
  • Note that this analysis is simplified (Dr. Yee
    might not approve.)

3
Types of cracks from thermal stress
4
Other thermal stress properties
  • The stress can cause displacement in the
    tangential direction.
  • Poissons ratio nstrain in tangential direction
    /strain in normal direction eT/ eN
  • Shear modulus GE/2/(1n)

5
Die-Die Attach-Substrate
  • Two types of problems caused by TCE dieltTCE
    substrate
  • When the temperature is at equilibrium (component
    and die at same temp), stress greater than
    tensile stress of the die can occur. This happens
    when there is temperature cycling.
  • Temperature differential exists, causing stress
    may be caused by large thermal resistance of die
    attach

6
Total strain when both cases occur
  • E(TCED-TCES)(TD-TA)TCES(TD-TS)
  • where Ddie, Ssubstrate, Aambient with power
    off
  • Experimental results will usually be somewhat
    less than this. However, note that there are
    other causes of stress, too, such as vibrations
    or material faults.
  • Note again that this is simplified, so other
    sources may have a somewhat different version of
    this equation.

7
Stress due to processing
  • Processing temps are usually higher than
    operating temps, so they may cause the maximum
    stress. The stress maximum in this case is at
    the corners.

8
Stress concentrations
  • During manufacturing, small stress concentrations
    often occur small cracks when a semiconductor
    die is sawed, small voids formed. When external
    stress is applied, these concentrations amplify
    the stress and may cause a fracture.
  • For an elliptical microcrack with major axis
    perpendicular to applied stress, max stress at
    crack tip

9
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10
Force required to cause breakage
KICplain strain fracture toughness in psi-in1/2
or MPa-m1/2 Zdimensionless constant, usually
1.2 amicrocrack length/2
11
To Minimize Stress
  1. Match TCE of component and substrate as much as
    possible
  2. Use an intermediate layer with a TCE in between
    that of the die and substrate molybdenum often
    used (TCE between that of silicon and alumina)
  3. Choose materials that need the lowest processing
    temperatures a large amount of stress is
    induced on the components as they cool from the
    processing temp
  4. Small voids in the bond distributed uniformly
    over the bond can help reduce stress. However,
    these voids will increase thermal resistance,
    increasing the junction temp, so this may not be
    a good thing. Also, watch out for stress
    concentrations, such as those caused by large
    voids.
  5. Use compliant bonding materials, such as soft
    solders and soft epoxies. Pb-Sn solder balls in
    BGA, or J-, gull-wing, and other types of leads
    in surface mounted devices are good. Again, note
    that a bonding material with a high thermal
    resistance will increase Tj.
  6. Reduce temperature fluctuations due to better
    thermal management.

12
To Minimize Stress, cont.
  • Increase bond thickness greater ability to flex
    when force applied often used with solder joints

13
Helpful properties to use with examples
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