1. Field of the Invention
The present invention relates to detecting instruments for use in leak detection of a gas, particularly to a process for manufacturing a reference leak.
2. Discussion of the Related Art
A reference leak is an artificial instrument for use in leak detection of a specific gas. The reference leak has a constant leak rate for the specific gas under a given condition such as a specific temperature and a specific pressure at the gas intake side. The reference leak has been widely used in periodical leak detection and calibration of a helium mass spectrometer leak detector.
Conventional reference leaks can generally be classified into the three types: platinum wire-glass leaks, squeezed metal tube leaks, and silica membrane helium leaks. A leak rate of the platinum wire-glass leak is generally in the range from 10−6˜10−8 torr·l/s. The platinum wire-glass leak is obtained by implanting a platinum wire into a glass body by way of a glass-to-metal unmatched sealing method. Due to a coefficient of thermal expansion of the platinum wire being unmatched with that of the glass body, a plurality of leak gaps are then defined at an interface between the platinum wire and the glass body. The platinum wire-glass leak is then obtained. However, during the manufacturing process of the platinum wire-glass type leak, the leak gaps' shapes, sizes, and numbers are randomly formed and therefore cannot be artificially controlled. A leak rate of the reference leak has to be calibrated by other reference calibration instruments after the reference leak is manufactured. Additionally, the leak rate of the reference leak is sensitive to temperatures. The leak rate may vary due to a change of the number and distribution of the leak gaps as a result of a change of the temperature. This temperature dependence may cause uncertainties (i.e., potential for an increased margin of error) with respect to the leak rate of the platinum wire-glass leak.
The squeezed metal tube leak is generally obtained by punching a tube of an oxygen free copper into a flattened piece by a hydraulic pressure device. The squeezed metal tube comprises a plurality of leak gaps, the leak gaps functioning as leak channels for the gas. A leak rate of the squeezed metal tube type reference leak is generally in the range from 10−6˜10−8 tor·l/s. However, similar to the platinum wire-glass leak, shapes, sizes, and numbers of the leak gaps of the squeezed metal tube leak are also formed randomly making such leak gaps unpredictable and therefore artificially uncontrollable.
The silica membrane helium leak is generally in a form of a blown bubble. The blown bubble is generally a thin, spherical membrane formed of silica glass. The silica glass membrane is porous and allows helium (He) gas to pass therethrough while blocking other kinds of gases from passing therethrough. Likewise, a leak rate of such a reference leak is unpredictable and has to be calibrated by other reference calibration instruments. The leak rate of the reference leak is also sensitive to temperatures.
Therefore, a heretofore unaddressed need exists in the industry to address the aforementioned deficiencies and inadequacies with respect to reference leaks and their method of manufacture, in particular.
In one aspect of the present invention, there is provided a method for making a reference leak. The method comprises the steps of: (a) preparing a substrate; (b) forming a patterned catalyst layer on the substrate, the patterned catalyst layer comprising one or more catalyst blocks; (c) forming one or more predominantly one-dimensional, elongated nano-structures extending from the corresponding catalyst blocks, such elongate nano-structures being formed by a chemical vapor deposition method; (d) forming a leak layer of one of a metallic material, a glass material, and a ceramic material on the substrate, the one or more elongate nano-structures being partly or completely embedded in the leak layer; and (e) removing the one or more elongate nano-structures and the substrate to obtain a reference leak with one or more leak holes defined therein.
The substrate may be a silicon substrate. A crystal plane orientation of the silicon may be selected from the group consisting of (111), (110), and (100) crystal plane orientations. The patterned catalyst layer generally comprises a material selected from the group consisting of gold, iron, cobalt, and silver. A thickness of the patterned catalyst layer is generally in the range from 0.2 nm to 10 nm. The thickness of the patterned catalyst layer is preferably approximately 1 nm. A size (i.e., diameter) of the catalyst block is preferably less than 1 μm. The catalyst layer may be formed by an evaporation deposition method, a sputtering deposition method, or an electroplating method. The catalyst layer may be patterned by a photolithography method or by an electron beam etching method. The patterned catalyst layer may also be formed by a printing method.
The elongate nano-structures are, advantageously, generally selected from the group consisting of silicon nanowires, silicon dioxide nanowires, gallium nitride nanowires, indium phosphide nanowires, and zinc oxide nanowires. A length of the elongate nano-structure is generally in the range from 100 nm to 100 μm. A diameter or width of the elongate nano-structure is generally in the range from 10 nm to 500 nm.
The metallic material used for the leak layer may, advantageously, be selected from the group consisting of copper, nickel, and molybdenum, and alloys composed substantially of one or more of these metals. The leak layer may be formed, e.g., by one of an evaporation deposition method, a sputtering deposition method, an electroplating method, a chemical vapor deposition method and a metal organic chemical vapor deposition method. The one or more elongate nano-structures may later be effectively removed by one of a reactive ion etching method, a wet etching and a plasma etching method, for example.
In another aspect of the present invention, there is a provided a method for making a reference leak having a custom-tailored leak rate for use in leak detection of a gas. The method includes the steps of:
(a) forming one or more elongate nano-structures on a substrate, a diameter and a length of the one or more elongate nano-structures being predetermined according to the following equations:
Q=n×(P1−P2)×Y (1)
Y=12.1×√{square root over (29/M)}×√{square root over (T/293)}×(D3/L) (Knusen equation) (2)
wherein,
Q represents the custom-tailored leak rate,
n represents the number of the elongate nano-structures,
P1 represents a pressure of the gas intake side of the reference leak,
P2 represents a pressure of the gas outlet side of the reference leak,
Y represents a conductance of the reference leak,
M represents a molecular weight of the gas,
T represents an operational temperature,
D represents a diameter of the one or more elongate nano-structures, and
L represents a length of the one or more elongate nano-structures;
(b) forming a leak layer of one of a metallic material, a glass material, a composite material, and a ceramic material on the substrate with the one or more elongate nano-structures embedded therein; and
(c) removing the one or more elongate nano-structures and the substrate to obtain a reference leak with one or more corresponding leak holes defined therein.
A length of each of the elongate nano-structures is preferably not less than 20 times a diameter thereof.
In still another aspect of the present invention, there is provided a method for making a reference leak. The method comprises the steps of: (a) forming one or more elongate nano-structures on a substrate; (b) forming a leak layer of one of a metallic material, a glass material, a composite material, and a ceramic material on the substrate with the one or more elongate nano-structures partly or completely embedded therein; and (c) removing the one or more elongate nano-structures and the substrate to obtain a reference leak with one or more corresponding leak holes defined therein.
Other advantages and novel features will become more apparent from the following detailed description when taken in conjunction with the accompanying drawings, in which:
Many aspects of the invention can be better understood with reference to the following drawings. The components in the drawings are not necessarily to scale, the emphasis instead being placed upon clearly illustrating the principles of the present invention. Moreover, in the drawings, like reference numerals designate corresponding parts throughout the several views.
Reference will now be made to the drawings to describe a preferred embodiment of the present invention in detail.
Referring initially to
The leak layer 3 is, advantageously, generally formed of one of a metallic material, a glass material, a composite material, and a ceramic material. The metallic material, if chosen, may usefully be selected from the group consisting of copper, nickel, and molybdenum, and alloys composed substantially of at least one of such metals. The material of the leak layer 3 is selected depending on the specific kind of a gas which the reference leak is utilized to detect. For instance, if the reference leak 10 is utilized to detect He gas, the material of the leak layer 3 is preferably a metallic material, because the metallic material is impermeable to He gas. If the reference leak is utilized to detect air, oxygen (O2) gas, or argon (Ar) gas, the material of the leak layer 3 is preferably a glass material or a ceramic material, because the glass material and the ceramic material are impermeable to air, O2 gas, and/or Ar gas.
The leak through holes 31 may be shaped as cylindrical holes or polyhedral holes. The number of the leak through holes 31 may be custom-tailored. In other words, the number of the leak through holes 31 may be predetermined prior to making the reference leak 10. Preferably, the leak through holes 31 have substantially same length L and diameter D, and are substantially parallel to each other. Likewise, a shape, a length, and a diameter of each of the leak through holes 31 may also be custom-tailored and, thereby, predetermined prior to making the reference leak 10. The length L and the diameter D of each of the leak through holes preferably satisfy the following requirement: L≧20 D. The diameter of each of the leak through holes 31 is generally in the range from 10 nm to 500 nm. The length of each of the leak through holes 31 is generally in the range from 100 nm to 100 μm. A leak rate of the reference leak 10 is generally in the range from 10−15 to 10−18 tor·l/s. The reference leak 10 can be employed, for example, in leak detection and calibration of a helium mass spectrometer, in measurement of pumping speed of micro vacuum pump, and in supplying a microflow gas in experiments in the field of gas-solid interface technology.
Referring now to
If the reference leak 10 has a custom-tailored leak rate, a diameter and a length of each of the one or more elongate nano-structures 11 can be predetermined according to the given custom-tailored leak rate, which will be explained in detail below.
In step (a), referring to
Referring to
Referring to
In step (b), referring to
In step (c), referring to
If the leak rate of the reference leak is custom-tailored, the length and the diameter of the elongate nano-structure can also be predetermined prior to making the reference leak according to the following equations:
Q=n×(P1−P2)×Y (1)
Y=12.1×√{square root over (29/M)}×√{square root over (T/293)}×(D3/L) (Knusen equation) (2)
wherein,
Q represents the custom-tailored leak rate in units of torr times liter per second (Torr L/s),
n represents the number of the elongate nano-structures, where n is a natural number,
P1 represents a pressure of the gas intake side of the reference leak in units of torrs,
P2 represents a pressure of the gas outlet side of the reference leak in units of torrs,
Y represents a conductance of the reference leak in units of liter per second (L/s),
M represents a molecular weight of the gas,
T represents an operational absolute temperature in units of Kelvins,
D represents a diameter of the one or more elongate nano-structures in units of centimeters, and
L represents a length of the one or more elongate nano-structures in units of centimeters. Further, the length L and the diameter D of the elongate nano-structures satisfy the following requirement:
L≧20D (3)
In the illustrated embodiment, the reference leak 10 is used to detect leakage of He gas. If a pressure of He gas P1 is the standard atmospheric pressure, i.e. 760 torrs, the temperature T is equal to 293 K, and a mean free path of He gas λHe is satisfied with the following requirement:
λHe>50 nm (4), and
λHe>(⅓)×D (5),
the equation (2) can thus be simplified as follows:
Y=12.1×√{square root over (29/M)}×(D3/L) (6)
In an exemplary embodiment, if L=5 μm, D=100 nm, P1=760 torrs, P2=0 torr, n=1, M=4 (the molecular weight of He is equal to 4 g/mol), and T=293 K, the conductance of the reference leak Y can be obtained according to the equation (6):
Y=12.1×√{square root over (29/4)}×((10−5)3/5×10−4)≈6.51×10−11 L/s.
The leak rate Q of the reference leak can be obtained according to the equation (1):
Q=(760−0)×0.6.51×10−11≈4.95×10−8 Torr. L/s
In this case, if P1=1 torr, can reach up to 6.51×10−11 Torr. L/s. On the contrary, understandably, according to the custom-tailored the leak rate Q of the reference leak 10, the length, the diameter, and the number of the leak through holes can be predetermined according to the aforementioned equations prior to making the reference leak 10.
It is to be further understood that the above-described embodiments illustrate the scope of the invention but do not restrict the scope of the invention. Variations may be made to the embodiments without departing from the spirit or scope of the invention as claimed herein.
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