Process for forming apertures in a metallic sheet

A process of forming an aperture in a metallic sheet including the steps of: PA1 a) defining at least one feature in a sheet of metallic material; PA1 b) laser drilling the at least one feature but not entirely removing it from the metallic sheet, the at least one feature being partially filled by metallic material which has melted and resolidified; and then PA1 c) chemically etching the metallic sheet and the melted and resolidified metallic material wherein the etchant attacks and at least partially dissolves the melted and resolidified metallic material, weakening the bond of the melted and resolidified metallic material to the metallic sheet.

FIELD OF THE INVENTION 
This invention relates generally to a process of forming metal sheets with 
apertures and more particularly to a process of forming metal masks with 
apertures having high aspect ratios. 
BACKGROUND OF THE INVENTION 
Metal sheets having apertures (such as holes, gaps, slits, slots or other 
openings) have many decorative and utilitarian uses. One utilitarian use 
is as a metal mask. Such metal masks are often used as templates for 
selectively exposing a material or workpiece to various manufacturing 
operations. For example, they may be used to screen conductive metal paste 
material onto a substrate to form desired features, such as conductive 
lines between electrical components of a circuit card. They may also be 
used to control the areas machined during laser ablation operations. Metal 
masks may also be used in photolithography operations where only certain 
areas of a photoresist are to be exposed. The features defined by such 
masks, particularly those used in integrated circuit fabrication, are 
often very small and must be defined with a high degree of precision. As 
the drive towards denser circuits continues, so does the need for masks 
capable of precisely defining very small and closely spaced features. 
Close spacing of the features, which results in less mask material between 
them, makes mask strength an increasingly important mask characteristic. 
It should be understood that while the present invention is particularly 
directed to forming metal masks, the present invention is also generally 
applicable to the forming of apertures in metallic material for many 
decorative and utilitarian uses. 
One way of making metal masks stronger is by increasing the thickness of 
the metal material used to form the mask. However, conventional methods of 
making masks generally lose their precision when applied to material 
thicknesses which are significantly greater than the smallest feature to 
be defined. 
It would be desirable to be able to form metal masks and other metallic 
objects with apertures that are smaller in size than the thickness of the 
metallic material. 
In general, it would also be desirable to have an improved process for 
forming apertures in metallic sheets. 
In photolithography, one conventional means for forming metal masks, a 
photoresist is applied to a metal sheet and the photoresist is then 
exposed and developed to define features. Thereafter, the metal sheet with 
the photoresist layer is etched so as to replicate the feature defined by 
the photoresist in the metal sheet. However, features having dimensions 
significantly smaller than the thickness of the metal (i.e., an aspect 
ratio greater than 1) cannot be formed due to the isotropic nature of the 
etching portion of the process. That is, the etchant continues to remove 
material in the lateral direction until it has penetrated the thickness of 
the material. This lateral material removal also causes the rounding of 
inside corners of mask features, resulting in inside corners having a 
radii of no less than half the thickness of the mask material, thereby 
making square corners impossible to obtain by conventional 
photolithographic methods. The ability to form sharp corners on thick 
metallic masks is highly desirable (i.e., wire bond pads thus have more 
area). 
LaPlante et al., U.S. Pat. No. 5,168,454, the disclosure of which is 
incorporated by reference herein, discloses a laser drilling technique 
employing a laser in the 3-10 W (average power) range which is used to 
machine apertures as small as 0.5 mils in a workpiece. However, this 
technique does not work well when applied to metal sheets having 
thicknesses as great as 25 mils. In the case of thick metal sheets, the 
material to be removed is not fully severed from the body of the metal 
sheet due to non-uniform penetration by the laser through the thickness of 
the metal and melting and resolidifying of the metallic material (i.e., 
rewelding) in the kerf area, thereby retaining the feature in the metal 
sheet. The rewelded material, and hence the feature, cannot be easily 
removed by mechanical operations such as punching or flexing without 
damaging the metal mask. 
Increasing the power of the laser to the 100-200 W (average power) range 
would result in full penetration of thick metal sheets but also poor 
accuracy, poor edge definition, rounded corners, larger cut width, and 
possibly also warping of the metal sheets. 
Howrilka et al., IBM Technical Disclosure Bulletin, 21, No. 3, p. 961 
(August 1978), the disclosure of which is incorporated by reference 
herein, discloses the laser drilling of a blind hole in an epoxy substrate 
followed by etching in an acid to remove debris in the bottom of the hole. 
Since an epoxy substrate is drilled, there is no possibility of rewelding 
of the metallic feature to the adjacent metal sheet. 
Melcher et al., U.S. Pat. No. 4,283,259, the disclosure of which is 
incorporated by reference herein, has disclosed maskless chemical and 
electrochemical machining wherein an energy source, such as a laser, is 
used to induce local heating in the workpiece while being simultaneously 
submerged in an etchant to speed up the chemical etching reaction and 
thereby preferentially remove material from the heated area. However, the 
thickness of the workpiece material must still be nearly as thin as the 
smallest dimension to be etched due to the isotropic nature of the 
etchant. 
IBM Research Disclosure 26969, September 1986, p.572, the disclosure of 
which is incorporated by reference herein, discloses dry laser etching of 
a 1 mil wide slot in a 2 mil thick molybdenum mask. The laser, typically 
in the 5-10 W power range, penetrates the molybdenum by locally heating 
and oxidizing molybdenum to MoO.sub.3 which is volatile at the elevated 
temperature caused by the local heating. The volatilized MoO.sub.3 is 
carried away by a moving gas stream. Any recrystallized MoO.sub.3 that is 
deposited on the molybdenum mask may be removed mechanically or by 
dissolution in a solvent. This technique, however, does not lend itself to 
other metals, such as stainless steel, whose gas phases occur at or above 
their melting points. Nor would this technique be feasible for thick metal 
sheets since with thick sheets, it is difficult to provide enough heat to 
vaporize all the metal. And, even if vaporized, the vaporized metal would 
redeposit on the walls adjacent to the holes being drilled. Further, for 
thick material, all the material is not uniformly removed, leaving bridges 
of material within the kerf. 
Others have proposed localized atmospheres to assist or promote the laser 
working process. 
Yoshida et al., U.S. Pat. No. 5,187,148, the disclosure of which is 
incorporated by reference herein, discloses a sputtering method wherein a 
laser causes ablation of a target, thereby causing the generation of a 
laser plasma. Oxygen is supplied to the laser plasma. 
Dulcy et al., U.S. Pat. No. 4,972,061, the disclosure of which is 
incorporated by reference herein, discloses the laser irradiating of a 
surface to roughen it, thereby generating a surface plasma. A localized 
atmosphere (nitrogen or oxygen) is provided at the surface to promote a 
chemical change at the surface. 
While the prior art is replete with methods for the working of metals with 
a laser, there still remains a need for a process for forming small 
apertures with a laser in sheets (thick or thin) of metallic material. 
Accordingly, it is a purpose of the present invention to have an improved 
process for forming small apertures in sheets of metallic material. 
It is another purpose of the present invention to have an improved process 
for forming small apertures in sheets of metallic: material wherein a 
laser is used. 
It is a further purpose of the present invention to have an improved 
process for forming small apertures with a laser in sheets of metallic 
material wherein the size of the aperture can be significantly smaller in 
dimensions than the thickness of the metallic sheet. 
It is a further purpose of the present invention to have an improved 
process for forming square-cornered apertures with a laser in sheets of 
(thick) metallic material wherein the radii of the corners of the 
apertures can be significantly smaller in dimension than half the 
thickness of the metallic sheet. 
These and other purposes of the present invention will become more apparent 
after referring to the following description considered in conjunction 
with the accompanying drawings. 
BRIEF SUMMARY OF THE INVENTION 
The purposes of the invention have been achieved by providing a process of 
forming at least one aperture in a metallic sheet comprising the steps of: 
a) defining at least one feature in a sheet of metallic material; 
b) laser drilling the at least one feature but not entirely removing it 
from the metallic sheet, the at least one feature being partially filled 
by metallic material which has melted and resolidified; and then 
c) chemically etching the metallic sheet and the melted and resolidified 
metallic material wherein the etchant attacks and at least partially 
dissolves the melted and resolidified metallic material, weakening the 
bond of the melted and resolidified metallic material to the metallic 
sheet.

DETAILED DESCRIPTION OF THE INVENTION 
Referring to the drawings in more detail, and particularly referring to 
FIGS. 5, there is shown a metallic sheet 10 having at least one feature 12 
defined therein. In a preferred embodiment of the invention, there will be 
a plurality of such features. The remaining description of the invention 
will be directed to the preferred embodiment wherein there are a plurality 
of features, although it should be understood that the invention is 
readily applicable to the situation where there is only a single feature. 
The features 12 may actually be defined by, for example, traversing the 
beam with an x-y table or galvo type scanner on the metallic sheet 10 but, 
as will be more typically the case, the features 12 will be defined by 
being programmed into a computer (not shown) as disclosed in the 
aforementioned U.S. Pat No. 5,168,454. 
The features 12 may take the form of any geometric shape. As shown in FIGS. 
5 (and other Figures as well) for purposes of illustration and not 
limitation, the features 12 are circular but they could also be square, 
rectangular, triangular, irregularly shaped, just to name a few. 
After the features 12 have been defined, they may be drilled with a laser 
(not shown). Laser drilled features are noted by the reference number 12'. 
The particular laser is unimportant provided it is suitably chosen to 
penetrate the desired metallic material. Also, it is preferred that it be 
computer controlled. The present inventors have found that the laser 
apparatus disclosed in the aforementioned U.S. Pat. No. 5,168,454 is 
particularly well suited for the purposes of the present invention. 
It should be understood that "feature", as used herein, represents the 
metal shape to be removed by laser drilling, resulting in the formation of 
an aperture. When the metallic sheet 10 is used as a screening mask, 
metallic paste will be forced through the aperture, replicating the 
feature on a substrate. In the most general aspect of the invention, the 
laser moves about the features until at least part of the features have 
been drilled. The laser will cause the drilled metallic material within 
the features to melt. Some of this melted material resolidifies within the 
features so that the feature is not entirely removed after laser drilling. 
As a practical matter, the smallest features will be of approximately the 
same size as the spot size of the laser (for example, 8 microns). It will 
be assumed that the features 12 in FIG. 5A are about 8 micron circles 
which, when drilled, will form approximately 8 micron diameter apertures. 
After drilling, features 12' contain some melted and resolidified metallic 
material 13. Then, according to the present invention, the metallic sheet 
10 and melted and resolidified metallic material 13 are chemically etched 
in a suitable etchant. After a predetermined amount of time, the melted 
and resolidified metallic 13 will be attacked and dissolved by the 
etchant, resulting in apertures 20. 
As the feature size increases, it is not practical to move the laser over 
the entire surface of the feature 12. Rather, the laser drilling is 
accomplished by directing the laser around the periphery 14 of the 
features so as to outline the features 12' as shown in FIG. 1. The laser 
causes the metallic material around the periphery 14 of the features 12' 
to melt. However, some of this melted material resolidifies along the 
periphery 14 of the features 12'. As more clearly seen in FIG. 2, the 
periphery 14 is made of portions 18 where the metallic material has melted 
and resolidified so as to form a "bridge" and portions 16 where the 
metallic material has been completely removed. In appearance, the 
"rewelding" of the features 12' to the metallic sheet 10 looks very much 
like perforations one would see in, for example, a perforated sheet of 
paper. In like manner, the rewelded features 12' may be removed from the 
metallic sheet by mechanical manipulation such as by bending or twisting. 
This mechanical manipulation can, however, cause the metallic sheet 10 to 
become undesirably distorted. 
According to the present invention, however, the metallic sheet 10 is now 
chemically etched by a suitably chosen etchant. In particular, the 
chemical etchant attacks and at least partially dissolves the melted and 
resolidified material 18 at the periphery 14 of the features 12' so that 
the melted and resolidified material 18, which previously bonded the 
features 12' to the metallic sheet 10, is severely weakened with the 
result that the features 12' are barely held in place by the melted and 
resolidified material 18. Usually, a very minimal amount of pressure will 
cause features 12' to fall out of the metallic sheet 10. And, as is often 
the case, the melted and resolidified material 18 will be completely 
attacked and dissolved during chemical etching so that features 12' fall 
out of the metallic sheet 10 by themselves (or possibly with slight 
agitation) in the etchant. Upon removal from the etchant, or after slight 
pressure to remove any remaining features 12', the resultant product is 
metallic sheet 10 having apertures 20 as shown in FIG. 3. 
For thicker metallic sheets where a corner is desired with a radii of less 
than half the thickness of the material, the laser beam is directed about 
the periphery of the feature and, by virtue of its small spot size, 
creates a corner with a radii as small as 4 microns. After drilling, the 
melted and resolidified metallic material is chemically etched as above, 
resulting in apertures with corners having radii not significantly larger 
than 4 microns. 
It should be noted that the step of chemically etching may cause the 
metallic sheet 10 to be attacked as well as the melted and resolidified 
material 18. This effect will be minimal as the etchant will typically 
preferentially attack the melted and resolidified material 18, which is 
essentially porous, due to its greater surface area. 
The resulting article may have many uses, both utilitarian and decorative. 
However, a preferred use of the present invention is as a mask, either for 
screening metallic pastes or to shield the underlying substrate during 
laser ablation or lithography. 
Further, since the step of chemical etching occurs for a very short amount 
of time, features may be produced which have an aspect ratio of 1 or 
greater. The aspect ratio can be defined as the depth of the feature 
divided by its width. 
The material of the metallic sheet may be any metallic material that is 
susceptible to laser drilling such as molybdenum, steels, stainless steel, 
titanium, nickel, aluminum, copper, brass, etc. The most preferred 
metallic materials are molybdenum and stainless steel. 
In a preferred embodiment of the invention, the laser drilling is done in 
an oxygen-containing atmosphere so that oxides will form in the metallic 
material 18 that has undergone melting and resolidifying. The entire laser 
drilling apparatus need not be encapsulated with the oxygen-containing 
atmosphere to be effective. Rather, all that is necessary is to have a 
localized oxygen-containing atmosphere at the feature that is being laser 
drilled. This may simply be accomplished by directing a flow of the 
oxygen-containing atmosphere at the feature that is being laser drilled. 
The oxygen-containing atmosphere may simply be air or alternatively 
oxygen. It is believed that the chemical etchant can be tailored to 
preferentially attack the oxides that form as the melted and resolidified 
material 18 so that the metallic sheet 10 itself will not be attacked to 
any appreciable extent. For example, in the case of a molybdenum metallic 
sheet 10, the oxide that forms is MoO.sub.3. The metallic sheet 10 with 
laser drilled feature 12' may then be etched with a 50/50 mixture of 30% 
hydrogen peroxide and ammonium hydroxide (full strength) which attacks and 
dissolves the melted and resolidified material 18 (thereby causing the 
feature 12' to fall out of the metallic sheet 10) but does not attack the 
molybdenum metallic sheet 10 to any appreciable extent. 
As noted previously, the metallic sheet 10 may be minimally attacked during 
the chemical etching step. Referring now to FIGS. 4A, 4B and 4C, there is 
shown an alternative embodiment of the present invention wherein the 
metallic sheet 10 is protected during the step of chemically etching by a 
protective film. The protective film 22 is applied to the metallic sheet 
10 as shown in FIG. 4A. The protective film 22 may be applied to only one 
side of the metallic sheet 10 for partial protection, as shown in FIG. 4A, 
or may be applied to both sides (not shown) of the metallic sheet 10 for 
nearly complete protection. Thereafter, the protective film 22 and 
metallic sheet material 10 are simultaneously processed with a laser (not 
shown) and subsequently etched to form apertures 24 in the protective film 
and apertures 20 in the metallic sheet 10. The resulting structure is 
shown in FIG. 4B. Finally, the protective film 22 is stripped by a 
suitable solvent, leaving the metallic sheet 10 with apertures 20 as shown 
in FIG. 4C. 
The protective film 22 may be any material that is resistant to the 
chemical etchant, preferably can be drilled with the same laser that is 
used to drill the metallic sheet 10, and can be easily stripped from the 
metallic sheet after etching. Such protective films 22 thus may include 
polyimides, photoresists, photosensitive polyimides,, epoxies, silicon 
coatings, enamels, lacquers and other similar coatings. Alternatively, 
other materials, such as gold, aluminum, anodized aluminum, chromium, 
glasses, etc., which are non-reactive (or at least not as reactive) to the 
chemical etchant may also be used. 
A further variation of the invention is shown in FIG. 6. There, a laser 
(not shown) is utilized to drill partially through a metallic sheet 10. As 
shown in FIG. 6A, metallic sheet 10 has features 12' which have been 
partially drilled by a laser. Areas 15 are open. Referring now to FIG. 6B, 
there is melted and resolidified metallic material 13 sitting on the 
undrilled portion of feature 12'. After immersion in a suitable chemical 
etchant, melted and resolidified metallic material 13 is removed, leaving 
only partially laser drilled feature 12', as best seen in FIG. 6C. This 
aspect of the invention may have particular applicability to screening 
masks where open areas are required for screening paste to form lines. 
Features 12' are tabs which provide structural integrity to the open areas 
of the screening mask. This aspect of the invention is also generally 
applicable to forming metallic sheets with blind holes or other apertures 
which do not completely perforate the metallic sheet. 
The purposes and advantages of the present invention will become more 
apparent after referring to the following Example. 
EXAMPLE 
The present invention was utilized to form 0.0020 inch vias in a 0.0100 
inch thick sheet of stainless steel. A Q-switched Nd:YAG laser was 
operated according to the teachings of the aforementioned U.S. Pat. No. 
5,168,454 at a power of 1.25 watts at 1 khz with a spot size of 8 microns 
to outline a circular feature having a diameter of 0.0018 inches. The 
drilled stainless steel sheet was then placed in an etchant bath and 
ultrasonically agitated at 40 degrees C. for about one hour. The etchant 
consisted of, in weight percent, 77% water, 20% nitric acid and 3% 
hydrofluoric acid. After removal from the bath, the features were 
completely removed, leaving apertures (vias) of 0.002 inch diameter. The 
post-etch thickness of the stainless steel sheet was 0.0098 inches. 
Thus, vias having an aspect ratio of about 5 were formed in a stainless 
steel sheet. The stainless steel sheet was minimally affected by the 
etchant. 
It will be apparent to those skilled in the art having regard to this 
disclosure that other modifications of this invention beyond those 
embodiments specifically described here may be made without departing from 
the spirit of the invention. Accordingly, such modifications are 
considered within the scope of the invention as limited solely by the 
appended claims.