Transcript Slide 1

Ultra-Thin Microelectronics
Inventing Team: Harry Charles,
Charles Banda (NSA), Shaun Francomacaro,
Allen Keeney, and John Lehtonen
Technology
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Standard microelectronic
assemblies are relatively thick and
rigid (exceeding 2500 m in
thickness with standard packaged
chips and printed wiring boards)
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Using bare chips and flex boards the
thickness can easily exceed 750 m
and, although the substrate may be
flexible, the chips are still rigid
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The focus of the ultra-thin
microelectronic invention is to
produce high density, highly flexible
microelectronic assemblies with
thicknesses in the 30-50 m range
(nominally about 1/3 the thickness of
a human hair)
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Technology
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The ultra-thin microelectronics
invention addresses four key
processes
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producing thin chips (integrated
circuits) down to 1 m in thickness
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fabricating multilayer thin film
freestanding substrates (four to six
conducting layers less than 25 m
overall thickness)
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connecting chips to the multilayer
thin film substrate (solder reflow,
nanowire interposer)
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verifying performance and reliability
(performance test vehicles, thermal
cycling studies, etc.)
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Technology
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Demonstrated Outcomes
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thinned die on flex (single layer)
reliability demonstrated units had
high assembly yields and survived
many thousands of stringent
temperature cycles
multilayer thin film free standing flex
has been fabricated and separated
from carriers (appears robust and
highly flexible)
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integrated circuit RF test vehicle chip
has been designed and fabricated –
awaiting thinning and flex testing
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nanowire interposers have been
fabricated
5-20 m
30-50 m
4 Layer substrate
Ultimate goal 30 m
(1/3 thickness of a human hair)
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Technology Applications
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What does it do?
– produces an integrated packaging system with an extremely low
profile and physical flexibility capable of supporting digital, RF, and
potentially microwave applications (inherently low weight, also)
– provides ultra-thin complex electronic circuitry that can be appliquéd
to any surface (flat or curved)
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Application Areas:
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3-D packaging
smart surfaces and skins
variable emissivity surfaces
active antennas
sensors
appliqués of all types
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Commercial Applications
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Cellular phones
RF ID tags
Portable electronics
Electronic clothing (“smart shirts”)
Biomedicine (“smart patch, prosthetics”)
Smart cards
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Commercial Opportunities
• Technology available for licensing
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Methods of Thinning
Thin-film multilayer substrates
Module assembly
Underfill selection and reliability testing
• Cooperative development of new
packaging applications
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Contact Information
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For technical information contact:
Harry Charles, Inventor
443-778-8050
[email protected]
Charles Banda, Inventor
443-778-1897
[email protected]
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For licensing information contact:
Teresa Colella, Technology Manager
Office of Technology Transfer
The Johns Hopkins University
Applied Physics Laboratory
11100 Johns Hopkins Road
Laurel, MD 20723
443-778-3782
[email protected]
www.jhuapl.edu/ott
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