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There has been and is a growing trend in the semiconductor industry for
increased circuit density. This trend has resulted in an increased circuit
density. This trend has resulted in an increase in volumetric heat
generation and concurrent decrease in available heat transfer surface when
devices are tested in a chip form. These highly dense devices may
dissipate in the order of five watts or more of energy during the
electrical testing operation.
A primary and critical problem with testing chips in chip form is the wide
temperature fluctuations which can affect test results because of the
thermal-electrical relationships of the devices. This wide temperature
variation is caused by the high thermal resistance of the chip (in
.degree.C/watt) and the power input variations during test.
Testing chips in wafer form has the advantage of low thermal resistance due
to effective conductance of heat to adjacent chips on the wafer. This low
thermal resistance minimizes the affect of power input variations and
yields acceptable temperature variations when chips are tested in wafer
form. The disadvantage of wafer test is that additional process steps have
to take place after the testing operation. These additional process steps,
such as the dicing operation, have some yield associated with them. This
yield loss will have a dramatic affect on the final yield of the module
which consists of multiple chips.
The test fixture of the invention enables the testing of devices in chip
form by injecting liquid at the vacuum pencil chip interface thereby
reducing the thermal resistance of the chip. This reduction in the thermal
resistance of the chip is due to the reduction in thermal contact
resistance at the chip/pencil interface surface. The mechanism of contact
resistance consists of conduction through the solid to solid spots at the
interface, and the conduction through the entrapped gasses in the
asperities created by the contact. It is the second factor that represents
the major resistance to heat flow since the thermal conductivity of the
gas is quite small in comparison with that of the solids (224 for copper
compared to 0.013 for air). By introducing water at the pencil/chip
interface the water flows by capillary action to fill the air asperities.
The conductivity of water (0.3 BTU/Hr-ft-.degree.F) is 23 times that of
air. Thus a more effective method of removing the heat at the interface
surface and a reduction in the overall thermal resistance of the chip is
achieved.
In a test system for testing micro-miniature devices, a test fixture is
used to support and maintain in alignment a micro-miniature device under
test with a probe structure. More particularly, where said micro-miniature
device is a chip of monolithic material containing a plurality of circuits
and having first and second substantially planar surfaces. Said first
planar surface of said chip containing a densely spaced array of
conductive pads for making electrical connection to the circuits within
said chip. Said test fixture including a substantially planar surface on
which said chip is supported and maintained in alignment with the probe
structure of said test system, whereby a physical interface is formed
between said second planar surface of said device under test and said
substantially planar surface of said test fixture. The improvement
comprising means and method for controllably and selectively introducing a
liquid, preferably water, into the physical interface between said test
fixture and said device under test, whereby the thermal resistance of the
chip under test is reduced due to the reduction in thermal contact
resistance at the chip/test fixture interface.
The above ABSTRACT is not to be taken either as a complete exposition or as
a limitation of the present invention, the full nature and extent of the
invention being discernible only by reference to and from the entire
disclosure.
Reference to Pending U.S. Patent
Applications, Patents and Publications
The test fixture of the present invention may be employed in a test system
generally of the type disclosed in Ser. No. 394,712, filed Sept. 6, 1973,
granted as U.S. Pat. No. 3,916,306 on Oct. 28, 1975, entitled, "Method and
Apparatus for Testing High Circuit Density Devices", by M. J. Patti and of
common assignee herewith.
The test fixture of the present invention may be employed in a test system
generally of the type disclosed in Ser. No. 410,592, filed Oct. 29, 1973,
granted as U.S. Pat. No. 3,873,818 on Mar. 25, 1975, entitled, "Electronic
Tester for Testing Devices Having a High Circuit Density", by J. D.
Barnard and of common assignee herewith.
The test fixture of the present invention may be employed in a test system
with a probe structure generally of the type disclosed in U.S. Pat. No.
3,806,801 granted Apr. 23, 1974, to R. Bove, on "Probe Contactor Having
Buckling Beam Probes" and of common assignee herewith.
The test fixture of the present invention may be employed in a test system
with a Coaxial Array Space Transformer generally of the type disclosed in
Ser. No. 484,052, filed June 28, 1974, granted as U.S. Pat. No. 3,911,361
on Oct. 7, 1975, entitled "Coaxial Array Space Transformer" by R. Bove et
al and of common assignee herewith.
As will be more fully apparent from the detailed description of the
invention set-forth hereinafter, applicants' invention may be practiced by
employing a suitably modified precision vacuum chuck generally of the type
disclosed in the following publications: (1) "Chuck Elevator" by R. M.
Gustafson, IBM Technical Disclosure Bulletin, Vol. 17, No. 1, June 1974,
pages 109 and 110; (2) "Precision Mechanism for Use in a System Requiring
Precise Alignment" by R. E. Hogan et al., IBM Technical Disclosure
Bulletin, Vol. 17, No. 3, August 1974, pages 880 and 881; and (3)
"High-Resolution X, Y, Z, .theta. Mechanism" by Z. Segal et al., IBM
Technical Disclosure Bulletin, Vol. 17 No. 7, December 1974, pages 1961
and 1962.
BACKGROUND OF THE INVENTION AND PRIOR ART
Applicants' invention is directed to a test fixture for maintaining the
temperature of a device under test within predetermined limits when said
device is subjected to a relatively sizeable amount of electrical energy
for test purposes.
Numerous structures and techniques have been employed in the art for the
cooling of electronic devices including semiconductor devices. The
structures of the prior art are extensive and varied. Many of the
structures of the prior art employ a liquid coolant. Particularly,
well-known to the art and commonly employed is a heat sink fabricated from
a metal, such as copper, having the ability to efficiently conduct energy
in the form of heat. Many of these heat sinks have provision for passing a
coolant liquid through the heat sink for maintaining the heat sink within
a predetermined temperature range.
It is also well-known in the art to submerge an electronic component or
device in a suitable coolant liquid. It is also well-known in the art to
provide control apparatus for controlling the flow of coolant in a heat
sink or bath.
In U.S. Pat. No. 3,007,088, granted to E. J. Diebold on Oct. 31, 1961, a
rectifier such as a crystal junction rectifier utilizing a germanium or
silicon wafer as a rectifying medium, is clamped to a fluid-cooled bus
bar. A heat-conductive and electrically conductive grease, for example
silicone grease, is provided between the lower base block (lower cathode
contact) and the liquid cooled bus bar. The silicone grease under pressure
fills voids which may exist between opposing surfaces which are not
perfectly smooth. Heat transfer from the base block to the bus bar is
thereby improved by virtue of the direct contact of the grease with
portions of opposing surfaces which may not otherwise make direct contact.
The tightening down of flanges by means of bolts puts the grease under
high pressure.
In U.S. Pat. No. 3,648,167, granted to D. R. Purdy et al. on Mar. 7, 1972
fluid cooled apparatus for testing power semiconductor devices is
disclosed. The apparatus includes a base member having a major surface and
a cavity within the base member. The surface of the base member has an
aperture which communicates with the cavity. The apparatus further
includes means for holding the power semiconductor device in the aperture,
so that an outer heat transfer surface of the device is exposed in the
cavity. Additionally, the apparatus includes means for circulating a fluid
through the cavity and across the heat transfer surface; and means in the
cavity for controlling the circulating fluid so as to minimize the thermal
resistance between the fluid and the heat transfer surface.
In U.S. Pat. No. 3,492,535, granted to D. L. Behrendt on Jan. 27, 1970
entitled "Ceramic Circuit Card", a thermally conductive compound is
employed between the surfaces of the ceramic circuit card and the modules
mounted thereon. The circuit card is comprised of an alumina ceramic
substrate card with a multilayer pattern of conductors on one surface and
a conductive plane on the opposing surface. Pads formed on circuit sites
by increasing the lateral dimension of a conductor, are connected by the
conductive pattern and a conductive layer about the edge of the substrate
card to the plane on the opposing surface. The heat from the thermal
emitting circuit modules mounted on the pads with a conductive thermal
compound therebetween, is circulated away from the modules by the
connecting path.
In U.S. Pat. No. 3,842,346, granted to C. R. Bobbitt on Oct. 15, 1974,
entitled "Continuity Testing of Solid State Circuitry During Temperature
Cycling", water is used to cool the heat sink for the thermoelectric
devices. The thermoelectric devices are formed as flat plates which are
assembled to be individually replaceable and are capable of cycling in two
minutes or less from approximately 25.degree. to 100.degree.C and back to
25.degree.C.
In U.S. Pat. No. 3,761,808, granted to R. B. Ryan on Sept. 25, 1973
entitled "Testing Arrangement", the temperature of a device under test
(packaged integrated circuit) is controlled by controlling the temperature
of the fluid bath in which the device under test is submerged.
In U.S. Pat. No. 3,150,021, granted to A. Sato on Sept. 22, 1964, entitled
"Method of Manufacturing Semiconductor Devices", the desired
characteristics of a tunnel diode are achieved by manufacturing the tunnel
diodes with a slightly oversized junction area. The tunnel diodes are then
placed in a chemical etching bath which etches away edges of the junction
area while simultaneously measuring the capacitance across the junction.
In U.S. Pat. No. 3,794,912, granted to P. J. W. Severin et al. on Feb. 26,
1974, entitled "Contact Device Using Conductive Fluid Measuring Resistance
and Capacitance of Semiconductor", a liquid electrical contact is made
with a semiconductor disk by forcing the liquid through an opening
contained in the structure on which the disc is supported.
In U.S. Pat. No. 3,803,489, granted to G. L. Miller on Apr. 9, 1974,
entitled "Liquid Contacts for Use in Semiconductor Profile Analysis",
semiconductor doping profile apparatus of the type using current feedback
for maintaining a constant modulation parameter is disclosed.
Non-destructive analysis is achieved by using a liquid electrode
rectifying contact for forming each required diode region. A metal
electrode contacts the electrolyte and is surrounded by an annular guard
ring maintained at rf ground, which defines precisely the area of the
diode region.
U.S. Pat. No. 3,811,182, granted to W. J. Ryan et al. on May 21, 1974,
entitled "Object Handling Fixture, System and Process" and of common
assignee with the instant application, discloses vacuum controlled chip
handling apparatus.
In the IBM Technical Disclosure Bulletin publication, entitled "Cooling
System for an Integrated Circuit Tester", by R. C. Chu et al., Vol. 13,
No. 11, April 1971, page 3547, a test chuck is provided into which the
component to be tested is loaded. A reservoir is connected to the chuck by
conduits. The reservoir can be raised and lowered. When the reservoir is
raised, the liquid level is raised above the chuck so that the fluid fills
the chuck by gravitational flow and provides the boiling type cooling for
the electronic component located therein.
In the IBM Technical Disclosure Bulletin publication, entitled
"High-Temperature Chip Handler" by M. J. Mulligan, Vol. 14, No. 4,
September 1971, a conduction heated vacuum pencil is disclosed for
incorporation into a chip handler for preheating semiconductor chips.
In the IBM Technical Disclosure Bulletin publication, entitled "Test
Chamber with Seal and Boot", a test chamber used in testing substrates
populated with integrated circuit chips is disclosed. The testing takes
place in a liquid cooled environment to prevent device burnout and to
minimize the possibility of contaminating the product and the coolant
liquid.
SUMMARY OF THE INVENTION
In a high speed electronic system for testing monolithic semiconductor
chips fabricated by large scale integration techniques, wherein said
semiconductor chips have a first substantially planar surface and a second
substantially planar surface containing an array of conductive pads
thereon, a probe structure for contacting said conductive pads on said
chip, positioning apparatus for positioning said chip with respect to said
probe structure, said position apparatus including a precision
controllable vacuum chuck having a vacuum pencil tip terminating in a
planar surface for engaging said first planar surface of said chip wherein
the improvement comprises: said chip positioning apparatus further
including means for introducing a controlled amount of a liquid between
the interface of the planar surface of said vacuum chuck and said first
planar surface of said semiconductor chip under test, whereby the thermal
contact resistance at the chip/vacuum chuck interface is reduced.
In a method for testing a semiconductor chip having a number of circuits
fabricated therein, said method employing at least a vacuum chuck and a
probe structure, said method including the steps of (a) employing said
vacuum chuck to align and position said chip with respect to said probe
structure for making electrical contact with said circuits, and whereby a
physical interface exists between said chip and said vacuum chuck; (b)
wherein the improvement comprises the step of introducing a liquid in the
interface between said vacuum chuck and said chip; (c) utilizing said
probe structure to subject said circuits on said chip to electrical test
conditions; whereby the temperature of said chip under test is maintained
within a predetermined range during the testing of said chip due
substantially to said liquid reducing the thermal resistance at the
interface between said vacuum chuck and said chip.
It is a primary object of this invention to provide an improved test
fixture for use in a high speed test system wherein the densely spaced
circuitry on semiconductor chips diced from a semiconductor wafer
fabricated by large scale integration techniques is rapidly and accurately
tested.
It is a primary object of this invention to provide an improved test
fixture for use in a high speed integrated circuit chip test system
wherein said fixture includes means for maintaining the temperature of
said chip under test within a predetermined temperature range.
It is a primary object of the invention to provide an improved test fixture
for use in semiconductor chip test system, wherein means is provided for
reducing the thermal contact resistance between the chip/vacuum pencil tip
interface.
It is a primary object of the invention to provide an improved test fixture
for use in a semiconductor chip test system, where said test fixture
includes a planar surface of heat conductive material on which said chip
under test is supported and said test fixture being characterized by the
provision of means for injecting a liquid, for example, water, into the
physical interface existing between said chip under test and said planar
surface of heat conductive material.
It is a further primary object of the invention to provide an improved
method of testing semiconductor chips having a relatively sizeable number
of circuits fabricated therein, wherein the improvement comprises the step
of introducing a liquid, preferably water, to fill the voids between a
substantially planar surface of the chip under test and the substantially
planar surface of a test fixture on which said chip under test is
supported during the testing thereof, whereby the temperature rise of said
chip under test is maintained within a predetermined increment per watt of
energy impressed on said chip under test.
The foregoing and other objects, features and advantages of the invention
will be more apparent from the following more particular description of
the preferred embodiments of the invention, as illustrated in the
accompanying drawing.
In the drawing:
The FIGURE discloses an orthogonal view of a test fixture in accordance
with the preferred embodiment of the invention. The view of the test
fixture is partially in section. In addition to the test fixture a
semiconductor chip and a probe structure are schematically illustrated.
PREFERRED EMBODIMENT
The FIGURE shows a vacuum chuck, or a vacuum pencil assembly 20 which
includes a vacuum pencil tip 3, a thermoelectric module 10 to control the
temperature of the pencil, and a heat sink 7. The heat sink 7, as depicted
by conduits 8A and 8B has water as a coolant circulating therethrough. As
is well known in the art the thermoelectric module 10 and the
thermoelectric control 6 maintain the vacuum pencil tip 3 at a
predetermined temperature. The thermoelectric control module 10 and the
thermoelectric control 6 may respectively be any of a number of suitable
commercially available components. For example, a suitable thermoelectric
control module 10 and control 6 are available from the Cambion Division of
Cambridge Thermionic Co., Cambridge, Massachusetts. The vacuum pencil tip
3 is constructed from a material, such as the metal copper, having high
thermal conductivity. Contained within the vacuum pencil tip is a
thermistor. The thermistor communicates with the thermoelectric control 6.
The vacuum pencil tip 3 includes a planar surface 3A. Communicating with
the planar surface 3A of the vacuum pencil tip are the vacuum port 4, 4A
and the water port 5, 5A.
Still referring to the FIGURE, a portion of a probe structure 1 is
depicted. The probe structure may be generally of the type disclosed and
claimed in the aforeidentified U.S. Pat. No. 3,806,801. The probe
structure 1 includes a plurality of discrete electrical probes 1A oriented
in an array corresponding to the array of conductive pads 2C of
semiconductor chip 2. The semiconductor chip 2 is an integrated circuit
chip diced from a semiconductor wafer prior to testing. The chip 2 may be
essentially square and have a dimension in the order of 100 to 200 mils.
As will be appreciated, by persons skilled in the art, applicants'
invention is not limited to any particular chip size or configuration,
other than the fact that the practice of applicants' invention has
particular utility and advantage in the testing of relatively very small
high circuit density semiconductor chips. The chip 2 has a lower planar
surface 2A which rests upon the planar surface 3A of vacuum pencil tip 3.
The chip 2 has on its upper (second) planar surface the array of
conductive pads 2C. (Merely as an example, a 170 mil .times. 170 mil chip
may have well over 100 discrete pads arranged in an array on a planar
surface thereof). The conductive pads are provided to permit electrical
connection of the circuits within the chip to circuitry external to the
chip. For example, certain of the pads on the chip may be termed
input/output pads, as their functions are to provide inputs to the chip
circuitry (input pads) and to receive outputs from chip circuitry (output
pads). Others of the pads may be termed power pads as their primary
purpose is to provide electrical energy to the chip circuitry.
In a test system of the type known to the art, each of the probes 1A of the
probe structure electrically contacts a discrete one of said array of
pads. The system provides, via the probe structure, power supply
potentials to the device under test. The test system further provides
under control of a test program appropriate input signals, via the probe
structure, to the device under test. Further the test system, via the
probe structure, accepts outputs from the device under test. These outputs
are compared with known acceptable outputs by the test system as a basis
for determining the merit or lack of merit of the device under test. No
further and detail discussion of an electronic test system for testing
semiconductor devices is deemed necessary in that the practice of
applicants' invention is not limited to a particular test system.
Further, any one of numerous test systems known to the art may be employed
to practice applicants' invention. For example, applicants' invention may
be practiced in a test system generally of the type disclosed and claimed
in the afore-identified M. J. Patti, U.S. Pat. No. 3,916,306 or the
afore-identified J. D. Barnard U.S. Pat. No. 3,873,818.
In a test system a typical test cycle will include the following sequence.
The chip 2 is aligned on the vacuum pencil tip surface 3A with the aid of
an optical system and servo mechanism. (The optical system and the servo
system are not shown in the drawing nor is a detail discussion thereof
deemed necessary. Persons skilled in the testing art are highly conversant
with suitable optical and servo systems. The optical and servo system "per
se" form no portion of applicants' invention). After the chip is aligned
the probes 1A of probe structure 1 are brought into physical contact with
the pads 2C of the chip under test. After contact is established between
the probe structure and chip 2 a liquid, preferably water, is introduced
into the chip/vacuum pencil tip interface 2A/3A. It is to be appreciated
that the volume of water introduced is very limited. The volume of water
introduced, however, must be sufficient to flow by capillary action to
fill all the air asperities at the interface surface without any
appreciable overspilling of the water. A suitable sequence for introducing
the water into the interface is, after turning off the vacuum 4, introduce
a predetermined volume of water. The volume of water will be such as to
fill ducts 4A and 5A, provide an adequate amount of water for filling by
capillary action the voids, or air asperities existing between surface 2A
of chip 2 and surface 3A of the vacuum pencil tip 3. A limited amount of
spillage of the water from the interface may be tolerated. It will be
appreciated that the predetermined volume of water introduced will be a
function of the volume of the ports 4A and 5A as well as the volume of the
voids in the interface. It has been found that in the order of one drop of
water will fill the voids in the interface between the chip and vacuum
pencil.
As will be apparent to persons skilled in the art, the practice of
applicants' invention is not limited to the structure depicted in the
FIGURE. For example, the invention may be practiced by structure generally
of the type depicted in the FIGURE and wherein the vacuum pencil assembly
20 is super imposed over the probe structure 1.
As will be apparent, the probes 1A may be brought into contact with the
pads 1C by relative movement between the probe structure 1 and vacuum
pencil assembly 20.
SUMMARY OF THE INVENTION
There has been a growing trend in the semiconductor industry for increased
circuit density. This trend has resulted in an increase in volumetric heat
generation and concurrent decrease in available heat transfer surface.
When devices are tested in wafer form the temperature variations of the
device due to the power input variations is low enough not to cause any
appreciable concern at the testing operation. The low temperature
variation is due primarily to the thermal conductivity of the
semiconductor wafer. The thermal conductivity is sufficiently high so that
effectively the surrounding chips act as an extended surface and thereby
lower the thermal resistance of the device under test.
When devices are tested in chip form, the heat flow is primarily through
the vacuum pencil. Due to the poor heat flow path out of the device,
higher thermal resistance of the chips have resulted. This causes wider
temperature fluctuations. These wider temperature variations can shift the
test limits to such a degree that device under test in chip form is not
feasible. Inability to adequately control the temperature of the device
under test in a chip form has been a severe problem in the semiconductor
testing art. Applicants' invention addresses and provides a solution to
this problem.
The practice of applicants' invention provides a technique for testing
discrete chip devices where the temperature rise is of the same magnitude
as that experienced in testing devices in wafer form. The temperature rise
is less than 2.degree.C/watt for a 0.180 inch .times. 0.180 inch chip.
While the invention has been described and shown particularly with
reference to one of its preferred embodiments, it will be understood by
those skilled in the art to which the work is directed that various
changes in form and detail may be made without departing from either the
spirit or scope of the invention.
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