WO1999027572A1 - Method for delivery of hydrogen fluoride gas - Google Patents
Method for delivery of hydrogen fluoride gas Download PDFInfo
- Publication number
- WO1999027572A1 WO1999027572A1 PCT/US1998/024382 US9824382W WO9927572A1 WO 1999027572 A1 WO1999027572 A1 WO 1999027572A1 US 9824382 W US9824382 W US 9824382W WO 9927572 A1 WO9927572 A1 WO 9927572A1
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- gas
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Classifications
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- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01L—SEMICONDUCTOR DEVICES NOT COVERED BY CLASS H10
- H01L21/00—Processes or apparatus adapted for the manufacture or treatment of semiconductor or solid state devices or of parts thereof
- H01L21/02—Manufacture or treatment of semiconductor devices or of parts thereof
- H01L21/02041—Cleaning
- H01L21/02043—Cleaning before device manufacture, i.e. Begin-Of-Line process
- H01L21/02046—Dry cleaning only
- H01L21/02049—Dry cleaning only with gaseous HF
-
- G—PHYSICS
- G01—MEASURING; TESTING
- G01F—MEASURING VOLUME, VOLUME FLOW, MASS FLOW OR LIQUID LEVEL; METERING BY VOLUME
- G01F15/00—Details of, or accessories for, apparatus of groups G01F1/00 - G01F13/00 insofar as such details or appliances are not adapted to particular types of such apparatus
- G01F15/02—Compensating or correcting for variations in pressure, density or temperature
- G01F15/04—Compensating or correcting for variations in pressure, density or temperature of gases to be measured
- G01F15/043—Compensating or correcting for variations in pressure, density or temperature of gases to be measured using electrical means
Definitions
- This invention relates to the measurement and delivery of gas in an accurate and precise manner.
- control of the amount of gas delivered is important. In most cases, it is desirable to accurately deliver a specified amount of gas and to repeatably, or precisely, deliver this desired amount. A common method for accomplishing this is by use of mass flow controllers.
- a measurement device such as a mass flow controller does not directly measure either the number of molecules of gas or the total mass of the gas. Rather, the mass flow controller measures a property of the gas, such as heat capacity, thermal conductivity, other properties, or other combinations of these properties. For the majority of gases, the measured property can be accurately and precisely correlated with a specific number of molecules, or equivalently, mass of the gas. Mass flow controllers are commonly used in the semiconductor industry for measuring gas flows in wafer processing equipment.
- gases such as hydrofluoric acid (HF) and acetic acid
- HF hydrofluoric acid
- acetic acid Certain gases, such as hydrofluoric acid (HF) and acetic acid, pose special problems when attempting to accurately and precisely measure and deliver an amount of gas.
- gases At equilibrium most gases have an association number, or average number of molecules in a gas phase cluster, of about 1.
- a gas with an association number of about one is substantially unpolymerized with the majority of the gas molecules existing as monomers.
- a mass flow controller is a suitable device for measuring such gases.
- a few gases, however, such as the previously mentioned hydrofluoric and acetic acids have association numbers greater than 1 for a wide range of temperatures and pressures far from their critical points. For example, at ambient temperature and pressure, HF has an association number near 3.5. This means that on average an HF molecule is a member of a cluster involving 3 to 4 HF molecules.
- the present invention provides a method for measuring an accurate and precise amount of gas.
- the invention applies to hydrogen fluoride, as well as to any other gas that may be substantially polymerized in the gas phase, such as acetic acid.
- the temperature and pressure of the gas to be delivered are controlled so that the gas is placed in a substantially unpolymerized state. This means that the majority of the gas molecules will exist as unassociated monomers.
- This unpolymerized gas is then measured by a suitable method, such as by use of a mass flow controller, or any other appropriate measuring device or method.
- the present invention further provides a method for controlling the temperature and pressure of a gas to place it in a substantially unpolymerized state, measuring the substantially unpolymerized gas, and then delivering the measured gas to a desired process.
- This invention also discloses a method for controlling the temperature and pressure of a gas so that the association number of the gas is close enough to 1 that the gas can be measured with sufficient accuracy and precision.
- a desired quantity of gas is then measured.
- An association number close enough to one may constitute an association number between 1 and about 1.3, more preferably between 1 and about 1.2, or most preferably between 1 and about 1.1.
- the measuring may be accomplished using a mass flow controller or any other suitable method for measuring a quantity of gas.
- the gas may then be delivered to a desired process. The nature of this desired process may dictate the level of control required on the association number during the measuring step.
- This invention also discloses a specific apparatus for accurate and precise measurement of HF gas.
- the temperature and pressure of a reservoir of HF gas are controlled to achieve a substantially unpolymerized state and the HF gas is measured using a suitable device.
- Figure 1 shows the association number of HF as a function of temperature at 1 atmosphere of pressure.
- Figure 2 shows the association number of HF as a function of pressure at 26° C.
- FIG. 3 is a schematic illustration of an apparatus suitable for performing the invention. Description of the Invention
- the invention provides for accurate and precise measurement of gases where the association number is a noticeable function of pressure and/or temperature.
- gases include but are not limited to hydrofluoric acid and acetic acid.
- the invention also includes gases containing two or more components, such as a mixture of HF and argon or a mixture of acetic acid and nitrogen, where some or all of the components of the gas have an association number substantially greater than one at ambient conditions.
- the invention requires placing the gas in a state where the association number for all components is one or substantially one. This is accomplished by modifying the temperature and pressure of the gas so that the association number is forced to one or close to one.
- the temperature and pressure modification is preferably carried out in a reservoir.
- This reservoir can take many forms.
- the reservoir could be a holding tank.
- Such a holding tank is fed from a chemical source, such as a gas cylinder.
- the pressure and temperature of the gas in the holding tank are altered to achieve a substantially unpolymerized state before measuring the gas.
- the reservoir is a section of pipe or tubing.
- Altering the temperature of the reservoir is preferably accomplished using some form of heat tracing.
- Heat tracing involves applying a heating source, such as linear resistive heating tape, along the entire length of the exterior of an object to be heated and then insulating the object/heater combination.
- the heating source may be controlled by a single feedback loop for the entire heat tracing, or the heat tracing may be partitioned with an independent feedback loop controlling the temperature in different sections. This latter method allows for finer control of the temperature over large areas of heat tracing.
- a suitable thermocouple for monitoring the temperature of the line and providing information for the feedback loop is a type J thermocouple.
- Both the linear resistive heating tape and the type J thermocouple are available from Omega Engineering, Inc. of Stamford, Connecticut.
- An example of a suitable temperature controller is the model CN3402 controller available from Omega Engineering, Inc.
- other heaters such as heating coils or heat lamps may be used to heat the reservoir.
- gas which is flowing through the pipe must spend enough time in the reservoir to attain a substantially unpolymerized state.
- the reservoir could be a gas cylinder which is heated to an appropriate temperature using a blanket heater or another appropriate method.
- a blanket heater or another appropriate method.
- Other embodiments are also possible and will be apparent to those skilled in the art.
- the goal of the invention is to place the gas in a state such that methods typically available for measuring a desired amount of gas will provide an accurate measure.
- this usually means placing the gas in a state such that properties of the gas typically used for indirectly measuring the number of gas molecules, such as heat capacity and thermal conductivity, will correlate in an accurate and precise manner with the actual number of gas molecules.
- this constitutes changing the temperature and pressure of the gas so that the gas is placed in a substantially unpolymerized state.
- the association number is a function of both temperature and pressure. Therefore, modifying the pressure of the gas will change the temperature necessary to achieve a substantially unpolymerized state.
- a gas at higher pressure must be heated to a higher temperature. The exact correlation among pressure, temperature, and association number will vary depending on the gas.
- Figure 1 shows the dependence of association number on temperature at 1 atmosphere of pressure for HF gas at equilibrium.
- the association number varies strongly with temperature between 20° C and 50° C. Thus, small changes in temperature in this region will result in noticeable changes in the association number of HF. Above 55° C, however, the association number of HF depends only weakly on temperature.
- Figure 2 shows the dependence of association number on pressure at 26° C for HF gas at equilibrium. The association number is a strong function of pressure from pressures near 20 kPa to over 100 kPa. From these plots, it is clear that the association number of HF is a strong function of both temperature and pressure for a variety of conditions near room temperature and atmospheric pressure.
- Another method of defining the invention includes controlling the pressure and temperature of the gas so that the degree of association of the gas molecules changes to a value close to 1. For example, at atmospheric pressure as the temperature of HF gas increases, the degree of association starts to asymptotically approach 1. Due to this asymptotic character, the dependence of the association number with changes in temperature or pressure will become smaller. Thus, it may be sufficient for some applications to only reduce the degree of association of the gas to 1.3, as this will sufficiently reduce variations in the amount of measured gas to give stable process performance. For other applications, it may be sufficient to reduce the degree of association to 1.2, and still other applications may require lower values such as 1.1.
- a suitable measuring device is a thermal or pressure mass flow controller, such as a 2000 seem nitrogen-calibrated thermal mass flow controller available from MKS Instruments, Inc. of Andover, Massachusetts, but other devices may be used.
- the measuring device should be in an appropriate condition to maintain the gas in a substantially unpolymerized state during the measurement.
- the mass flow controller should also be at 70° C to ensure that the gas retains its unpolymerized or unassociated state during the measurement.
- substantially unpolymerized is distinct from completely unpolymerized. For example, complete dissociation of all HF gas phase clusters will not occur until 100° C or higher at atmospheric pressure, but the association number may sufficiently approach 1 at 60° C to provide desired measuring accuracy and repeatability.
- the gas can now be delivered to a desired process.
- this process may be directly connected to the measuring device, connected to the measuring device by a pipe, or connected in any other way which allows gas delivered by the measuring device to be received by the process chamber. Because the gas was measured in a well-defined state, the total number of molecules of gas received by the process chamber is known. Even if the final desired process operates under temperature and pressure conditions which lead to subsequent repolymerization or association of the delivered gas, the behavior will be reproducible as the correct quantity of gas will arrive at the process. Thus, the temperature and pressure of the process may differ from the temperature and pressure of the reservoir and the measuring device.
- the gas may also be mixed with other gases prior to delivery to the process chamber.
- the measuring device itself could be a final destination for the gas. In this case, the desired process would be run in the measuring device itself, and delivery to the measuring device would also constitute delivery to the process.
- FIG. 3 shows an embodiment of the present invention.
- a gas bottle 10 is connected via pipe 20 to a mass flow controller 30.
- the temperature of pipe 20 and mass flow controller 30 is controlled using heat tracing, which is accomplished with heater tape 22.
- Thermocouple 24 provides temperature information for the temperature controller 26 for the temperature control feedback loop.
- Pipe 20 constitutes the reservoir in this embodiment.
- the gas passes through pipe 40 to process chamber 50.
- a second pipe 42 may intersect pipe 40 at 44, so that after the gas is measured at mass flow controller 30, one or more additional gases may be mixed with the said measured gas prior to delivery to process chamber 50.
- additional pipes may intersect process chamber 50, so that one or more gases may delivered to the process chamber independently of the measured gas.
- the pressure or the temperature or both of the process chamber 50 as well as pipe 40 leading to the process chamber may also be regulated.
- Figure 3 shows heat tracing on pipe 40 to maintain pipe 40 at the same temperature as pipe 20 and mass flow controller 30.
- the pressure and temperature of the process chamber and the pipe leading to the process chamber need not be the same as the pressure and temperature of the reservoir or of the mass flow controller.
- the temperature of the HF bottle may be regulated.
- This comparative example illustrates the inaccuracy and the difficulties in measuring and delivering a specific quantity of gas having an association number of substantially greater than one.
- a gas with an association number of 1 like N2
- the rate at which a chamber of fixed volume will fill from a fixed lower pressure to a fixed higher pressure will vary linearly with the flow rate. The variance will be within the error tolerance of the mass flow controller.
- this comparative example illustrates that there is a non-linear response of fill rate with respect to flow.
- a 6 liter chamber was filled from 10 Torr to 110 Torr by passing HF gas through a 2000 seem nitrogen-calibrated thermal mass flow controller made by MKS Instruments, Inc.
- the bottle was chilled to 19° C, the lines and the mass flow controller were held at 22° C, and the chamber was heated to 27° C.
- the measured flow through the mass flow controller was doubled from 0.25 slm to 0.50 slm.
- the chamber filled in 192 seconds.
- the chamber filled in 39 seconds.
- the fill rate changed by a factor of five due to a factor of two change in the flow rate. This indicates that the amount of HF entering the chamber does not correlate directly with the indicated flow of the mass flow controller, leading to uncertainties in the amount of HF introduced.
- a 5 pound HF bottle is connected to a process chamber via 0.25 inch diameter stainless steel pipes, with a 2000 seem nitrogen-calibrated mass flow controller made by MKS Instruments, Inc. inserted between the process chamber and the bottle to regulate the flow.
- the bottle temperature is maintained at 20° C.
- the pipes connecting the mass flow controller to the bottle and the chamber, as well as the mass flow controller itself, are heat traced to allow heating of these parts. The heat tracing is accomplished using linear resistive heating tape.
- the temperature of the pipes and the mass flow controller are set to 70° C, with Type J thermocouples acting both to monitor the pipe temperature as well as to provide information to a temperature controller to maintain a desired temperature.
- the pipe connecting the HF bottle and the mass flow controller is 20 inches long. The mass flow controller is then activated to allow a flow of 0.5 slm to pass from the bottle to the process chamber.
- the current invention is useful in any process in any industry where it is necessary to measure and deliver an accurate amount of a gas which has an association number substantially greater than 1 at ambient conditions. It will be readily apparent to those skilled in the art that this invention has utility for purposes other than those detailed in this disclosure. The information presented above is not intended to limit the scope of application of this invention.
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Abstract
A process for accurately and precisely measuring gases which have association numbers substantially greater than 1 at ambient conditions. The temperature and pressure of the gas are modified so that the gas is substantially unpolymerized during measurement. The gas may then be delivered to a desired process.
Description
METHOD FOR DELIVERY OF HYDROGEN FLOURIDE GAS
Background of the Invention
This invention relates to the measurement and delivery of gas in an accurate and precise manner.
In any situation where gas phase chemical reactants are delivered to a reaction, control of the amount of gas delivered is important. In most cases, it is desirable to accurately deliver a specified amount of gas and to repeatably, or precisely, deliver this desired amount. A common method for accomplishing this is by use of mass flow controllers.
A measurement device such as a mass flow controller does not directly measure either the number of molecules of gas or the total mass of the gas. Rather, the mass flow controller measures a property of the gas, such as heat capacity, thermal conductivity, other properties, or other combinations of these properties. For the majority of gases, the measured property can be accurately and precisely correlated with a specific number of molecules, or equivalently, mass of the gas. Mass flow controllers are commonly used in the semiconductor industry for measuring gas flows in wafer processing equipment.
Certain gases, such as hydrofluoric acid (HF) and acetic acid, pose special problems when attempting to accurately and precisely measure and deliver an amount of gas. At equilibrium most gases have an association number, or average number of molecules in a gas phase cluster, of about 1. A gas with an association number of about one is substantially unpolymerized with the majority of the gas molecules existing as monomers. A mass flow controller is a suitable device for measuring
such gases. A few gases, however, such as the previously mentioned hydrofluoric and acetic acids, have association numbers greater than 1 for a wide range of temperatures and pressures far from their critical points. For example, at ambient temperature and pressure, HF has an association number near 3.5. This means that on average an HF molecule is a member of a cluster involving 3 to 4 HF molecules.
The variation in association number of HF, or other gases which form multi- molecule gas phase clusters under many conditions, leads to problems when attempting to measure a specific quantity of gas by using a mass flow controller to define a flow. As a result, measuring and delivering an accurate amount of HF gas under ambient conditions is difficult.
Summary of the Invention
The present invention provides a method for measuring an accurate and precise amount of gas. The invention applies to hydrogen fluoride, as well as to any other gas that may be substantially polymerized in the gas phase, such as acetic acid. First, the temperature and pressure of the gas to be delivered are controlled so that the gas is placed in a substantially unpolymerized state. This means that the majority of the gas molecules will exist as unassociated monomers. This unpolymerized gas is then measured by a suitable method, such as by use of a mass flow controller, or any other appropriate measuring device or method.
The present invention further provides a method for controlling the temperature and pressure of a gas to place it in a substantially unpolymerized state, measuring the substantially unpolymerized gas, and then delivering the measured gas to a desired process.
This invention also discloses a method for controlling the temperature and pressure of a gas so that the association number of the gas is close enough to 1 that the gas can be measured with sufficient accuracy and precision. A desired quantity of gas is then measured. An association number close enough to one may constitute an association number between 1 and about 1.3, more preferably between 1 and about 1.2, or most preferably between 1 and about 1.1. Again, the measuring may be accomplished using a mass flow controller or any other suitable method for measuring a quantity of gas. The gas may then be delivered to a desired process. The nature of this desired process may dictate the level of control required on the association number during the measuring step.
This invention also discloses a specific apparatus for accurate and precise measurement of HF gas. The temperature and pressure of a reservoir of HF gas are controlled to achieve a substantially unpolymerized state and the HF gas is measured using a suitable device.
Brief Description of the Drawings
Figure 1 shows the association number of HF as a function of temperature at 1 atmosphere of pressure.
Figure 2 shows the association number of HF as a function of pressure at 26° C.
Figure 3 is a schematic illustration of an apparatus suitable for performing the invention.
Description of the Invention
The invention provides for accurate and precise measurement of gases where the association number is a noticeable function of pressure and/or temperature. Examples of such gases include but are not limited to hydrofluoric acid and acetic acid. The invention also includes gases containing two or more components, such as a mixture of HF and argon or a mixture of acetic acid and nitrogen, where some or all of the components of the gas have an association number substantially greater than one at ambient conditions. The invention requires placing the gas in a state where the association number for all components is one or substantially one. This is accomplished by modifying the temperature and pressure of the gas so that the association number is forced to one or close to one.
The temperature and pressure modification is preferably carried out in a reservoir. This reservoir can take many forms. For example, in one embodiment the reservoir could be a holding tank. Such a holding tank is fed from a chemical source, such as a gas cylinder. The pressure and temperature of the gas in the holding tank are altered to achieve a substantially unpolymerized state before measuring the gas.
In another embodiment the reservoir is a section of pipe or tubing. Altering the temperature of the reservoir is preferably accomplished using some form of heat tracing. Heat tracing involves applying a heating source, such as linear resistive heating tape, along the entire length of the exterior of an object to be heated and then insulating the object/heater combination. The heating source may be controlled by a single feedback loop for the entire heat tracing, or the heat tracing may be partitioned with an independent feedback loop controlling the temperature in different sections. This latter method allows for finer control of the temperature over large areas of heat tracing. A suitable thermocouple for monitoring the temperature of the line and providing information for the feedback loop is a type J thermocouple. Both the linear resistive heating tape and the type J thermocouple are available from Omega
Engineering, Inc. of Stamford, Connecticut. An example of a suitable temperature controller is the model CN3402 controller available from Omega Engineering, Inc. Alternatively, other heaters such as heating coils or heat lamps may be used to heat the reservoir. In this embodiment, gas which is flowing through the pipe must spend enough time in the reservoir to attain a substantially unpolymerized state.
In still another embodiment, the reservoir could be a gas cylinder which is heated to an appropriate temperature using a blanket heater or another appropriate method. Other embodiments are also possible and will be apparent to those skilled in the art.
The goal of the invention is to place the gas in a state such that methods typically available for measuring a desired amount of gas will provide an accurate measure. As mentioned above, this usually means placing the gas in a state such that properties of the gas typically used for indirectly measuring the number of gas molecules, such as heat capacity and thermal conductivity, will correlate in an accurate and precise manner with the actual number of gas molecules. In one embodiment, this constitutes changing the temperature and pressure of the gas so that the gas is placed in a substantially unpolymerized state. This means that the majority of the gas molecules exist as monomers and do not participate in a multi-molecule gas phase cluster. The association number is a function of both temperature and pressure. Therefore, modifying the pressure of the gas will change the temperature necessary to achieve a substantially unpolymerized state. To reduce the association number of a gas to a specified level, a gas at higher pressure must be heated to a higher temperature. The exact correlation among pressure, temperature, and association number will vary depending on the gas.
The correlation among temperature, pressure, and association number is depicted for HF gas in Figures 1 and 2. Figure 1 shows the dependence of association number on temperature at 1 atmosphere of pressure for HF gas at equilibrium. The association number varies strongly with temperature between 20° C and 50° C.
Thus, small changes in temperature in this region will result in noticeable changes in the association number of HF. Above 55° C, however, the association number of HF depends only weakly on temperature. Figure 2 shows the dependence of association number on pressure at 26° C for HF gas at equilibrium. The association number is a strong function of pressure from pressures near 20 kPa to over 100 kPa. From these plots, it is clear that the association number of HF is a strong function of both temperature and pressure for a variety of conditions near room temperature and atmospheric pressure.
Another method of defining the invention includes controlling the pressure and temperature of the gas so that the degree of association of the gas molecules changes to a value close to 1. For example, at atmospheric pressure as the temperature of HF gas increases, the degree of association starts to asymptotically approach 1. Due to this asymptotic character, the dependence of the association number with changes in temperature or pressure will become smaller. Thus, it may be sufficient for some applications to only reduce the degree of association of the gas to 1.3, as this will sufficiently reduce variations in the amount of measured gas to give stable process performance. For other applications, it may be sufficient to reduce the degree of association to 1.2, and still other applications may require lower values such as 1.1.
Once the gas is placed in a substantially unpolymerized state, it is then measured. A suitable measuring device is a thermal or pressure mass flow controller, such as a 2000 seem nitrogen-calibrated thermal mass flow controller available from MKS Instruments, Inc. of Andover, Massachusetts, but other devices may be used. Preferably, the measuring device should be in an appropriate condition to maintain the gas in a substantially unpolymerized state during the measurement. Again, using hydrogen fluoride gas as an example, if the gas is driven into a substantially unpolymerized state by raising the temperature of the gas to above 70° C at 760 Torr,
then the mass flow controller should also be at 70° C to ensure that the gas retains its unpolymerized or unassociated state during the measurement.
It is important to note that substantially unpolymerized is distinct from completely unpolymerized. For example, complete dissociation of all HF gas phase clusters will not occur until 100° C or higher at atmospheric pressure, but the association number may sufficiently approach 1 at 60° C to provide desired measuring accuracy and repeatability.
Having accurately measured the gas, the gas can now be delivered to a desired process. We will denote this process as occurring in a process chamber, although the desired process could also take place in a pipe or other structure. The process chamber may be directly connected to the measuring device, connected to the measuring device by a pipe, or connected in any other way which allows gas delivered by the measuring device to be received by the process chamber. Because the gas was measured in a well-defined state, the total number of molecules of gas received by the process chamber is known. Even if the final desired process operates under temperature and pressure conditions which lead to subsequent repolymerization or association of the delivered gas, the behavior will be reproducible as the correct quantity of gas will arrive at the process. Thus, the temperature and pressure of the process may differ from the temperature and pressure of the reservoir and the measuring device. Once the gas is measured, it may also be mixed with other gases prior to delivery to the process chamber. Note also that it is conceivable that the measuring device itself could be a final destination for the gas. In this case, the desired process would be run in the measuring device itself, and delivery to the measuring device would also constitute delivery to the process.
Figure 3 shows an embodiment of the present invention. A gas bottle 10 is connected via pipe 20 to a mass flow controller 30. The temperature of pipe 20 and
mass flow controller 30 is controlled using heat tracing, which is accomplished with heater tape 22. Thermocouple 24 provides temperature information for the temperature controller 26 for the temperature control feedback loop. Pipe 20 constitutes the reservoir in this embodiment. After measurement at mass flow controller 30, the gas passes through pipe 40 to process chamber 50. Optionally, a second pipe 42 may intersect pipe 40 at 44, so that after the gas is measured at mass flow controller 30, one or more additional gases may be mixed with the said measured gas prior to delivery to process chamber 50. Optionally, additional pipes may intersect process chamber 50, so that one or more gases may delivered to the process chamber independently of the measured gas. Optionally, the pressure or the temperature or both of the process chamber 50 as well as pipe 40 leading to the process chamber may also be regulated. Figure 3 shows heat tracing on pipe 40 to maintain pipe 40 at the same temperature as pipe 20 and mass flow controller 30. However, the pressure and temperature of the process chamber and the pipe leading to the process chamber need not be the same as the pressure and temperature of the reservoir or of the mass flow controller. Optionally, the temperature of the HF bottle may be regulated.
Comparative Example
This comparative example illustrates the inaccuracy and the difficulties in measuring and delivering a specific quantity of gas having an association number of substantially greater than one. When metering a gas with an association number of 1 , like N2, through a mass flow controller, the rate at which a chamber of fixed volume will fill from a fixed lower pressure to a fixed higher pressure will vary linearly with the flow rate. The variance will be within the error tolerance of the mass flow controller. However, this comparative example illustrates that there is a non-linear response of fill rate with respect to flow.
A 6 liter chamber was filled from 10 Torr to 110 Torr by passing HF gas through a 2000 seem nitrogen-calibrated thermal mass flow controller made by MKS Instruments, Inc. The bottle was chilled to 19° C, the lines and the mass flow controller were held at 22° C, and the chamber was heated to 27° C. The measured flow through the mass flow controller was doubled from 0.25 slm to 0.50 slm. At 0.25 slm of HF flow, the chamber filled in 192 seconds. At 0.50 slm of flow, the chamber filled in 39 seconds. The fill rate changed by a factor of five due to a factor of two change in the flow rate. This indicates that the amount of HF entering the chamber does not correlate directly with the indicated flow of the mass flow controller, leading to uncertainties in the amount of HF introduced.
Below is an example of how to implement this invention. The described flow is accurately measured due to the elevated temperature of the reservoir and the mass flow controller.
Example of Invention
A 5 pound HF bottle is connected to a process chamber via 0.25 inch diameter stainless steel pipes, with a 2000 seem nitrogen-calibrated mass flow controller made by MKS Instruments, Inc. inserted between the process chamber and the bottle to regulate the flow. The bottle temperature is maintained at 20° C. The pipes connecting the mass flow controller to the bottle and the chamber, as well as the mass flow controller itself, are heat traced to allow heating of these parts. The heat tracing is accomplished using linear resistive heating tape. The temperature of the pipes and the mass flow controller are set to 70° C, with Type J thermocouples acting both to monitor the pipe temperature as well as to provide information to a temperature controller to maintain a desired temperature. The pipe connecting the HF bottle and
the mass flow controller is 20 inches long. The mass flow controller is then activated to allow a flow of 0.5 slm to pass from the bottle to the process chamber.
The current invention is useful in any process in any industry where it is necessary to measure and deliver an accurate amount of a gas which has an association number substantially greater than 1 at ambient conditions. It will be readily apparent to those skilled in the art that this invention has utility for purposes other than those detailed in this disclosure. The information presented above is not intended to limit the scope of application of this invention.
Claims
1. A method of measuring an accurate and precise amount of gas having an association number of substantially greater than 1 at ambient conditions, comprising the steps of: controlling the temperature and pressure of the gas to place the gas in a substantially unpolymerized state; and measuring a quantity of said substantially unpolymerized gas.
2. The method of claim 1 further comprising the step of delivering said measured quantity of gas.
3. The method of claim 1 wherein said gas is HF.
4. The method of claim 1 wherein said gas comprises one or more chemicals.
5. The method of claim 3 wherein said temperature is at least 55┬░ C and said pressure is less than 101 kilopascals.
6. The method of claim 3 wherein said temperature is at least 70┬░ C and said pressure is less than 120 kilopascals
7. The method of claim 1 wherein said controlling step is done in a reservoir.
8. The method of claim 1 wherein said measuring step is done using a mass flow controller.
9. The method of claim 2 wherein said delivered gas is delivered to an environment having a pressure and temperature different from the pressure and temperature during said controlling step.
10. The method of claim 2 wherein said delivered gas is delivered to an environment having a pressure and temperature different from the pressure and temperature of said measuring step.
11. The method of claim 2 wherein said delivered gas is mixed with other gases subsequent to said measuring step but prior to said delivering step.
12. A method of accurately measuring an amount of gas, comprising the steps of: controlling the temperature and pressure of the gas so that the association state of the gas is between 1 and about 1.3, and measuring a quantity of said controlled gas.
13. The method of claim 12 further comprising the step of delivering said measured quantity of gas.
14. The method of claim 12 wherein said gas is HF.
15. The method of claim 12 wherein said controlling of temperature and pressure is done in a reservoir.
16. The method of claim 12 wherein said measuring is done using a mass flow controller.
17. The method of claim 13 wherein the said delivered gas is delivered to an environment having a pressure and temperature different from the pressure and temperature of the gas during said controlling step.
18. The method of claim 13 wherein said delivered gas is delivered to an environment having a pressure and temperature different from the pressure and temperature of the gas during said measuring step.
19. The method of claim 12 wherein the temperature and pressure of the gas are controlled so that the association state of the gas is between 1 and about 1.2.
20. The method of claim 12 wherein the temperature and pressure of the gas are controlled so that the association state of the gas is between 1 and about 1.1.
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US97503397A | 1997-11-20 | 1997-11-20 | |
US08/975,033 | 1997-11-20 |
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Cited By (1)
Publication number | Priority date | Publication date | Assignee | Title |
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