Chemical mechanical polishing machine

A CMP machine includes several polishing tables mounted on a carousel, which rotates in one direction. Each of the polishing tables includes a polishing pad. Each polishing pad can polish one wafer on its first surface. Each polishing pad also has one distributing duct used to supply slurry onto the polishing pad. An exhaust duct is included to exhaust slurry, in which the exhaust duct has a first end and a second end. The first end of the exhaust duct is coupled to slurry. A regulating valve is included to regulate slurry exhaust. An exhaust pump is included to produce a exhausting force of slurry. The exhaust pump is coupled to the second end of the exhaust duct. A regulating valve controller is included to control the regulating valve.

BACKGROUND OF THE INVENTION 
1. Field of the Invention 
This invention relates to semiconductor fabrication equipment, and more 
particularly to a chemical mechanical polishing machine, which has a 
capability to control a slurry exhaust status. 
2. Description of Related Art 
As integration of a semiconductor device increases, in accordance with the 
needs of interconnects in a reduced dimension of a metal-oxide 
semiconductor (MOS) transistor, it is necessary to design a circuit with 
at least two levels of interconnect metal layers. The multilevel 
interconnect structure usually include several inter-layer dielectric 
(ILD) layers and several inter-metal dielectric (IMD) layers for a purpose 
of isolation between the interconnect metal layers. When design rules 
become finer, the quality of the ILD layers or the IMD layers is necessary 
to be higher. For example, a higher quality of planarization on the ILD 
layers or the IMD layers is desired. 
In order to allow the multilevel interconnect structure to be more easily 
formed and a pattern to be more precisely transferred, it is essential to 
have a good planarization quality on a wafer surface which has uneven 
surface due to some device structure being formed underneath. Moreover, 
planarization quality also affect the precision of an alignment system. If 
the wafer is not properly planarized, not only a photo-mask cannot be 
precisely aligned but also a probability of fabrication error can 
increase. 
In semiconductor fabrication, planarization technologies are essential to 
allow a high-density photolithography process can be performed because a 
planar surface can avoid a light scattering phenomenon during the 
photolithography process. The pattern transfer therefore can be precisely 
obtained. Currently, the planarization technologies includes two most 
common process. One is spin-on glass (SOG) technology, and the other one 
is chemical mechanical polishing (CMP) technology. The SOG technology can 
planarize a local region with very high quality, and the CMP technology 
can globally planarize the wafer with an acceptable quality even though 
the planarization quality is not as good as the quality of the SOG 
technology. However, when the semiconductor fabrication achieves a 
sub-half-micron fabrication level, the SOG technology becomes insufficient 
to the need of planarization due to a globally high pattern density. The 
CMP technology becomes the only one having capability to globally 
planarize the wafer in very-large scale integration (VLSI) fabrication or 
even in ultra-large scale integration (ULSI) fabrication. 
A CMP process makes use of a polishing object like a polishing knife with a 
reagent to polish the uneven surface contour so as to planarize the 
surface. In the CMP process, the reagent is usually referred to as a 
slurry. Slurry usually includes a solution mixed with silica in colloidal 
phase or materials in dispersed phase such as aluminum, KOH or NH.sub.4 
OH. The grinding particles are extremely hard and have a diameter of about 
0.1-0.2 .mu.m. Basically, these particles are used to polish the wafer 
surface. A wafer is held by holder on it backside. The front side is 
properly pressed onto a polishing pad which is held by a polishing table. 
Both the wafer and the polishing pad are rotating with a controlled speed. 
So the wafer surface is polished and planarized. 
In order to prevent the wafer surface from being scratched due to impure 
particles in slurry, before slurry is transported to the polishing pad, 
slurry is necessary to be filtered by a filter. 
FIG. 1 is a top view of a conventional CMP machine. In FIG. 1, inside a 
platen 10, there are a housing 20, a carousel 30 on the housing 20, and 
several polishing heads 40a 40b, 40c, 40d, 40e, and 40ef evenly 
distributed on the rim of the carousel 30. The carousel 30 rotates in one 
direction. Moreover, an exhaust duct 50 is connected to the housing 20 on 
one end. The other end of the exhaust duct 50 has a damper valve 60, and 
an exhaust pump 70. The exhaust pump 70 provides a driving force to 
exhaust slurry. 
However, the damper valve 60 in the conventional CMP machine is controlled 
by hand. This is very inconvenient to control a slurry exhaustion. 
Moreover, when polishing process temporarily stop, slurry is not supplied. 
If the damper valve 60 is not closed in time, the exhaust pump 70 can 
continuously exhaust slurry and causes the polishing heads 40e and 40f, 
which are close to one end of the exhaust duct 50, to be over-dried. This 
over-dried polishing heads 40e and 40f have a poor polishing capability 
when the polishing process starts again so that the planarity of the CMP 
process is deteriorated. 
SUMMARY OF THE INVENTION 
It is therefore an objective of the present invention to provide a CMP 
machine with a capability to control the slurry exhausting status so that 
slurry is avoided to be over-dried due to a continuous slurry exhaust when 
slurry is not supplied at a temporary stop stage of the CMP process. The 
quality of the CMP process is therefore maintained. 
In accordance with the foregoing and other objectives of the present 
invention, a CMP machine with a capability to control the slurry 
exhausting status is provided. The CMP machine of the invention includes 
several polishing tables mounted on a carousel, which rotates in one 
direction. Each of the polishing tables includes a polishing pad. Each 
polishing pad can polish one wafer on its first surface. Each polishing 
pad also has one distributing duct used to supply slurry onto the 
polishing pad. An exhaust duct is included to exhaust slurry in which the 
exhaust duct has a first end and a second end. The first end of the 
exhaust duct is coupled to slurry. A regulating valve is included to 
regulate slurry exhaust. An exhaust pump is included to produce a 
exhausting force of slurry. The exhaust pump is coupled to the second end 
of the exhaust duct. A regulating valve controller is included to control 
the regulating valve. So, the CMP machine of the invention is accomplished 
.

DETAILED DESCRIPTION OF THE EMBODIMENT 
A chemical mechanical polishing (CMP) machine of the invention using a 
regulating valve controller to control a regulating valve so that slurry 
is not over-dried. The CMP machine includes several polishing tables. Each 
of the polishing tables can polish one wafer. One of the polishing tables 
is described following: 
FIG. 2A is a schematic drawing illustrating a top view of a polishing table 
of a CMP machine, according, to a preferred embodiment of the invention. 
FIG. 2B is a schematic drawing illustrating a side view of a polishing 
table of a CMP machine, according to a preferred embodiment of the 
invention. In FIG. 2A and FIG. 2B, a polishing table 105 includes a holder 
110 to hold a wafer 120. A polishing pad 130 is held by the polishing 
table 105. A tube 140 is used to transport slurry 150 to the polishing pad 
130. A supplying pump 160 is globally used to produce the transporting 
force to transport the slurry 150 through the tube 140. The number of the 
supply pump 160 is preferably one in the whole CMP machine. It is not 
necessary to have one supplying pump 160 for each polishing table 105. 
When the polishing process is performed the polishing table 105 and the 
holder 110 rotate along their individual directions 180a, 180b. The holder 
110 holds the wafer 120 from its backside 190. A front side 195 of the 
wafer 120 is pressed onto the polishing pad 130 as to polish the front 
side 195, on which are there many device structures formed. The supplying 
pump 160 continuously transport the slurry 150 through the tube 140 onto 
the polishing pad 150 near the wafer 120. The front side 195 can react 
with the slurry 150 so as to ease the surface to be more easily polished. 
The slurry contains abrasive grinding particles allow the surface to be 
mechanically polished. This is the CMP process, which includes mechanical 
and chemical mechanisms. The CMP process is therefore a planarization 
process, because it can polish away the convex part on the front side 195 
of the wafer 120 so as to get a planar surface. 
FIG. 3, is a schematic drawing illustrating a top view of a CMP machine, 
according to a preferred embodiment of the invention. In FIG. 3, inside a 
platen 100, there are a housing 200, a carousel 300 on the housing 20, and 
several polishing tables 400, such as six, evenly distributed on the rim 
of the carousel 300. The polishing tables 400 are describe in FIG. 2A and 
FIG. 2B. The carousel 300 rotates in one direction. Moreover, an exhaust 
duct 500 is connected to the housing 200 on one end. The other end of the 
exhaust duct 500 has a damper valve 600, and an exhaust pump 70. The 
exhaust pump 700 provides a exhausting force to exhaust slurry. 
Furthermore, a controller 800 is included and is coupled to the damper 
valve 600 so as to control the on/off of the damper valve 600 in time. 
When the slurry 150 of FIG. 2B is not supplied due to a temporary stop of 
operation, the controller 800 closes the damper valve 600 in time. The 
exhaust pump 700 does not locally over-dry slurry near to the end of the 
exhaust duct 500. As described in FIG. 1, if the polishing tables 400 near 
to the of the exhaust duct 500, they may have a poor efficiency of 
polishing due to over-dried slurry. 
A control signal line 810 is used for a coupling between the controller 800 
and an operator 900. The control signal line 810 can be any means, which 
can allow the operator 900 to send a signal to the controller. The 
controller 800 can even serve as a vale by itself. When the slurry 150 is 
not supplied, the operator can send a control signal to the controller 800 
to close the damper valve 600. When the slurry start to supply the 
operator send a control signal to the controller 800 to open the damper 
valve 600. It is the characteristic that the invention controls the damper 
valve 600 remotely. In the conventional process, the damper valve 60 of 
FIG. 1 has to be closed by hand. Since the damper-valve 800 can be 
remotely controlled, the over-dried phenomenon is effectively avoided. The 
polishing quality is maintained. The wafer has a stable uniformity. The 
yield rate is thereby increased. 
In conclusion, several characteristics of the invention are following: 
1. The damper valve 600 can be remotely controlled preferably through the 
controller 800 and the signal control line 810 so that the slurry 
exhausting status is properly controlled in time. The polishing, quality 
is maintained. The wafer has a stable uniformity. The yield rate is 
thereby increased. 
2. The invention controls the damper valve 600 through the controller 800. 
When the CMP process is performing the operator can remotely open the 
damper valve 600 in time. When the CMP process is stopped, the operator 
can remotely close the damper valve 600 in time without do it by hand. 
The invention has been described using an exemplary preferred embodiment. 
However it is to be understood that the scope of the invention is not 
limited to the disclosed embodiment. On the contrary, it is intended to 
cover various modifications and similar arrangements. The scope of the 
claims, therefore, should be accorded the broadest interpretation so as to 
encompass all such modifications and similar arrangements.