Top Banner
PONDICHERRY UNIVERSITY CENTRE FOR NANOSCIENCE AND TECHNOLOGY MEMS/NEMS DEVICES AND APPLICATIONS TOPIC :FLIP CHIPS SUBMITTED TO SUBMITED BY Dr.K.Suresh babu VENKATA KISHORE .PERLA M.TECH II YEAR
21

Flipchip bonding.

Jul 03, 2015

Download

Engineering

venkata016

it explains about filp bonding in chips.
Welcome message from author
This document is posted to help you gain knowledge. Please leave a comment to let me know what you think about it! Share it to your friends and learn new things together.
Transcript
Page 1: Flipchip bonding.

PONDICHERRY UNIVERSITY

CENTRE FOR NANOSCIENCE AND TECHNOLOGY

MEMS/NEMS DEVICES AND APPLICATIONS TOPIC :FLIP CHIPS

SUBMITTED TO SUBMITED BYDr.K.Suresh babu VENKATA KISHORE .PERLA

M.TECH II YEAR

Page 2: Flipchip bonding.

FLIP CHIP

• Developments to improve cost, reliability and productivity in the electronic packaging industry – flip chip technology.

• Introduced as the Solid Logic Technology by IBM in 1962.

• In 1970, converted into Controlled Collapse Chip Connection (C4)

• Flip chip = Advanced form of SMT,

in which bare semiconductor chips

are turned upside down and bonded

directly to PCB.

• Initially applied to peripheral contacts

but quickly progressed to area arrays

which allow for high I/O counts at

larger pitches.

Page 3: Flipchip bonding.

Concept• Flip chip is the connection of an integrated circuit chip to a carrier

or substrate with the active face of the chip facing toward the substrate.

• The basic structure of flip chip consists of an IC or chip, an interconnection system, and a substrate.

• The IC can be made of silicon, gallium-arsenide, indium-phosphide.

• Substrate material could be ceramic, epoxy-glass laminate, ceramic thick-film and many more

Page 4: Flipchip bonding.
Page 5: Flipchip bonding.

IC Bond Pad Interface• The interconnection system is subdivided into four functional areas:

– Under bump metallization (UBM)

– Chip bumps

– Encapsulation

– Substrate metallization

Page 6: Flipchip bonding.

Flip Chip Processing

• Solder Interconnection Processing

– (a) Wetted controlled Collapse solder interconnection (High Temp.)

– (b) Solid state bond (Similar to wirebonds)

– (c) Cap reflow configuration (Two metals)

• Isotropic and compressed anisotropic Adhesives

Page 7: Flipchip bonding.

Flip Chip on Organic Substrate

• Benefits

– Cheaper

• Fall backs

– High CTE

– Fatigue

– Bad joints

• IBM and Hitachi discovered that using polymer underfills reduce strain on solder

Page 8: Flipchip bonding.

Underfill Encapsulants and Processing

• Advantages to underfills

– Compensate for thermal expansion differences between chip and substrate

– Avoid solder corrosion

– Protect from environmental effects such as moisture

– Absorb α particle emissions from lead in solder

Page 9: Flipchip bonding.

Underfill Encapsulants and Processing

• Capillary Flow Processing

• Injection Flow Processing

Page 10: Flipchip bonding.

Underfill Encapsulants and Processing

• Compression Flow Processing

– Placement velocity feedback

Page 11: Flipchip bonding.

Flip Chip Assembly Processes

Page 12: Flipchip bonding.

Electrical Performance

• Flip chip provide shortest chip-to-package connections

• Minimal resistance

• Minimal capacitance

• Minimal inductance

• Layout and materials effect the performance

Page 13: Flipchip bonding.

N = A F 1/3 exp(E/kT)DNP ( s - c ) T

H

N = cycles to failureF = cycling frequencyDNP = distance from neutral points = CTE of the substratec = CTE of the chip T = temperature cycleH = height of solder ball E = activation energy

1.9

Coffin-Manson Equation for Reliability

Page 14: Flipchip bonding.

Reliability

• Range from highly reliable to adequate

• Flip chips on ceramic have high reliability

• Underfilled flip chips have better reliability

• Alpha particle emissions (cause soft errors)

• Increased sensitivity to electrostatic discharge

Page 15: Flipchip bonding.

Failure Modes

• Delamination

– Increases solder joint stress

– Allows solder to move into voids

*C-mode scanning acoustic microscope (C-SAM) images

Page 16: Flipchip bonding.

Failure Modes

• Solder migration

– Can cause shorts by bridging

Page 17: Flipchip bonding.

Failure Modes

• Die cracking

– Catastrophic failure

– Edge cracks

– Center die cracks

Page 18: Flipchip bonding.

Failure Modes

• Fillet Cracking

– Chip side cracks

– Board side cracks

– Complete cracks

– Can lead to delamination

Page 19: Flipchip bonding.

Failure Modes

• Solder fatigue cracking

– Can create opens

• Bulk underfill cracking

– Typically between joints

– Potential to cause shorts

Page 20: Flipchip bonding.

Advantages

• Size and weight reduction.

• Applicability for existing chip designs.

• Performance enhancement and increased production.

• Feasibility for chip replacement.

• Increased I/O capability, extendable for RF and optical interfaces.

Page 21: Flipchip bonding.

Conclusion

• Unlike wire bonding which requires the bond pads to be positioned on the periphery of the die to avoid crossing wires, flip chip allows the placement of bond pads over the entire die (area arrays), resulting in a significant increase in density of input/output (I/O) connections (700 I/O’s). Additionally, the effective inductance of each interconnect is miniscule because of the short height of the solder bump. It becomes clear why the integrated circuit industry has adopted flip chip for high-density, fast electronic circuits.

• What makes flip-chip bonding attractive to the MEMS industry is its ability to closely package a number of distinct dice on one single package substrate with multiple levels of embedded electrical traces.