Patent Document

STATEMENT REGARDING FEDERALLY SPONSORED RESEARCH 
     This invention was made under Contract DE-AC05-000R22725 between the U.S. Department of Energy and the assignee of the present invention. The Government has certain rights in this invention. 
    
    
     BACKGROUND OF THE INVENTION 
     The field of the invention is ion mobility spectrometers. Ion mobility spectrometry (IMS) is an important method for detecting drugs, explosives, VOCs, and chemical warfare agents at ambient pressure. Explosives generally have high electron affinities and drugs and chemical warfare (CW) agents have high proton affinities. When these chemicals enter the reactor of an ion mobility spectrometer (IMS), negative and positive ions of these samples will be preferentially formed. Such a preference allows a high sensitivity of IMS technology in detecting trace explosives, drugs, and CW agents. Some commercial ion mobility spectrometers are available for detecting the above chemicals. 
     Miniaturization of such instruments provides advantageous applications in the field. However, a typical problem for commercial hand-held IMS is loss of sensitivity. For example, the sensitivity of a desktop size IMS detector now used in airports, is about 1 nanogram for explosives. The sensitivity of a smaller, handheld version, would be reduced more than 100 times. The main reason for the reduced sensitivity is the use of a nickel-63 (Ni 63 ) radioactive source for ionization. Nickel-63 emits electrons with 67 keV kinetic energy. The low stopping power of the high-energy electrons in gases generates less ions in the small volume of the miniature IMS ionization chamber, resulting in the low sensitivity. In addition, a nickel-63 source has potential hazards due to its radioactive nature. An example of an ion-producing device with a nickel-63 radioactive source is disclosed in Turner et al., U.S. Pat. No. 6,225,623, issued May 1, 2001. For general information concerning the principles of ion mobility spectrometry, reference is made to Eiceman, G. A. and Karpas, Z., “Ion Mobility Spectrometry,” CRC Press, Boca Raton Fla., USA, 1994. 
     In Taylor et al., U.S. Pat. No. 5,684,300, issued Nov. 4, 1997, and PCT Pub. No. WO 03/11554, published June 10, 1993, pulses with various polarities, amplitudes, and widths are generated by a RF oscillator and are used to produce ions through a corona discharge. Certain features of these pulses are undefined, which tends to limit the performance of this kind of spectrometer. An ion gate is used to control ions entering an ion mobility channel and the electronics require that the device have extra size. 
     SUMMARY OF THE INVENTION 
     The invention is a method and apparatus for providing a pulsed discharge ionization source particularly designed for miniature ion mobility spectrometers (IMS), but also usable in other analytical instruments. The invention uses a pulse to generate a corona around a tip of non-radioactive (non-doped) material to generate ions from a sample gas and to signal the start of ion motion. 
     In a further aspect of the invention, the applied potential comprises a pulse component and a dc base voltage component, which reduces the pulse component. This reduces noise and power consumption. 
     Miniaturized ion mobility spectrometers equipped with the pulsed discharge ionization source of the present invention have the following advantages: (1) high sensitivity because the ions are concentrated in a very small volume, (2) the use of an ion gate and its associated electronics is unnecessary, and (3) a high dynamic range is available because the ionization rate can be adjusted. The present invention provides a method and an apparatus in which ions are generated in a highly confined space and time, which results in high sensitivity for miniature IMS detectors. A processor-based electronic control enables timing of the initial ion motion with the ionization pulse. This provides a device without the need for an ion extract gate for ions entering a drift chamber. This reduces the size of the drift chamber body, the electronics control package, and power consumption. The invention also provides for increased dynamic range by adjusting the pulse height or by adjusting the DC bias. 
     Other objects and advantages of the invention, besides those discussed above, will be apparent to those of ordinary skill in the art from the description of the preferred embodiments which follows. In the description reference is made to the accompanying drawings, which form a part hereof, and which illustrate examples of the invention. Such examples, however are not exhaustive of the various embodiments of the invention, and therefore reference is made to the claims which follow the description for determining the scope of the invention. 
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS 
     FIG. 1 is a schematic view of a first embodiment of an apparatus for practicing the method of the present invention; 
     FIG. 2 is a schematic view of a second embodiment of an apparatus for practicing the method of the present invention; 
     FIG. 3 is a graph of ion detection current vs. time vs. dc bias voltage; 
     FIG. 4 is a graph of ion detection current vs. drift time for moist air and for nitrogen supplied to the drift chamber; 
     FIG. 5 is a graph of arcing threshold voltage vs. distance between two electrodes for generating an ion-producing corona; and 
     FIG. 6 is a graph of arcing threshold voltage vs. pulse height for generating an ion-producing corona. 
    
    
     DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS 
     Referring to FIG. 1, the present invention is practiced in a miniature ion mobility spectrometer (IMS)  10  employing a pulsed corona discharge ion source as shown in FIG.  1 . 
     FIG. 2 shows a second miniaturized embodiment of the apparatus featuring a microelectronic CPU  51 . 
     In FIGS. 1 and 2, the device has a cylindrical body  11  comprised of ten ( 10 ) stacked, annular metal electrodes  12 - 19 ,  22  and  23  which are separated by annular spacers  21  (5-mm thick and 8 mm ID) of a dielectric material such as Teflon. This forms a drift channel  24  which can be in the range from 1.7 mm-2.5 mm in diameter and 35-50 mm in effective length. In FIG. 1, the drift channel is specifically 2.5 mm in diameter and 47 mm in length, respectively. 
     Nine miniature resistors (not shown), each with 2 MΩ resistance, 1% tolerance, are connected between the electrodes  12 - 19 ,  22  and  23  to form a voltage divider. The first electrode  12  is biased with a power supply  20  to provide an ion drift voltage, with the voltage being distributed to the intermediate electrodes  13 - 19 ,  22  and  23  through these resistors. The last electrode  23  is connected to an electrical ground  40 . The next to the last electrode  22  is connected to a 470-pf capacitor  39  to suppress transients. An ion detector electrode  25  is located in the drift chamber  24  between the last electrode  23  and the next to last electrode  22 . Positive or negative potentials can be applied to the detection electrode  25  for detecting positive and negative ions, respectively. 
     A nickel-tipped electrode  26  of non-radioactive (non-doped) material with an end radius of curvature of approximately 25 μm is mounted at the entrance of the drift chamber  24 . The second drift channel electrode  13  is used as the counter electrode for corona discharge with the distance to the tip  26  being larger than the threshold distance for discharge zone as illustrated in FIG.  5 . The corona-producing tip  26 , together with the second electrode  13  of the IMS channel, formed a tip-ring corona discharge element. 
     A sample gas is supplied from reservoir  38  in FIG. 1 through a flow meter  37  to an inlet into the corona discharge end of the drift chamber  24 . A carrier gas, in this case, nitrogen, is supplied from a source  35  through a filter  34  and a second flow meter  33  to an inlet into the detection end of the drift chamber  24 . These gases exit the drift chamber through valve  41  and outlet  42 . In FIG. 2, where parts similar to FIG. 1 have the same number, a sample gas is received from a source  43 , while dry air enters from a supply  53  into an entrance at the opposite end of the drift chamber  24 . The dry air includes both drift gas and reactant gas. All of these gases exit from exit  42 . 
     A corona is produced at the electrode  26  by applying an electrical pulse having a width of from 40 ns to 100 μs, a pulse height varying from 0.2-3.3 kV and a repetition rate (frequency) of 20 Hz. The pulse is generated as a base dc voltage component originating at a high voltage source  36  and a varying pulse component generated by a pulse generator comprising high voltage source  29 , amplifier  28  and pulse generator  27 , which generates pulses on the order of 5 volts before they are amplified. These pulses are summed with a base dc voltage through capacitor C 1 . The resulting amplified high-voltage pulse is applied to the corona tip electrode  26 , which is seen in FIG.  1 . During the high voltage pulse, ions are generated in the vicinity of the tip  26 . After the pulse, the ions move along the drift channel  24  through the carrier gases under the influence of the drift field bias provided by voltage supply  20 . 
     The corona discharge pulse also provides a start signal for timing the ion mobility movements. For each pulse, ions are separated according to their travel time to reach the ion detector  25  located at the end of the channel  24 . There, an ion current is produced and is transmitted to a current amplifier  30  connected to electrode  25 . The time difference between the start signal and arrival of ions is detected by a time-to-digital converter (TDC)  31  and is transmitted to a computer  32  for analysis. If a digital oscilloscope  31  is used instead of time-to-digital converter  31 , the start pulse triggers the oscilloscope. The ion arrival signal is recorded by the scope and sent to the computer  32 . 
     The detector  25  is connected to an amplifier  30  in FIG. 1 which amplifies the signals. The oscilloscope is connected to an Apple Macintosh computer  32  running a Labview application program in FIG.  1 . This is a lab prototype embodiment for demonstrating the operation of the invention. In FIG. 2, the components in FIG. 1 are designed for reduced size in a commercial embodiment. 
     Ion mobility spectra of both positive and negative ions were measured as a function of pulse width. For positive ions, the ion current increased with pulse width and saturated. For negative ions, the ion current peaked rapidly and then decayed with increased pulse width. 
     Ion mobility spectra of negative ions produced by pulsed corona discharge and by ionization of air were measured as a function of drift bias voltage from −600 VDC to −1700 VDC as seen in FIG.  3 . The pulses had 1.08 μs width and +2600V amplitude. The sample air was at atmospheric pressure and room temperature. The drift gas was N 2 , which was fed from a source  35  through a filter  34  and flow meter  33  at the detector end of the IMS channel  24  with a flow rate of 20 sccm (standard cubic centimeter per minute). 
     A typical mobility spectrum of positive ions generated by pulsed corona discharge ionization of air is shown in FIG.  4 . For producing positive ions, the pulse potential applied to the tip  26  was also positive, the same polarity as used for generating negative ions, with a height of 3100 VDC and a width of 14.5 μs. 
     The corona discharge properties depend on the distance between the tip  26  and the counter electrode  13 . The counter electrode can be either a ring or a tip. This is illustrated in FIG.  5 . For distances less than 1.96 mm, no ionization occurred until a threshold of potential, about 1900 VDC was reached. At and above the threshold, spark breakdown occurred, which preceded the establishment of a stable corona. The voltage threshold was found to increase as a function of distance, as shown in FIG. 5, up to 2400 volts at 1.96 mm. Stable corona discharge conditions could not be found in this distance range. When the distance was larger than 1.96 mm, corona discharge occurred at a threshold that was a function of the drift bias. 
     Corona discharge was also generated by a combination of a base dc potential in combination with a pulsed voltage potential. As seen in FIG. 1, a dc voltage supply  36  is connected to a dc pulse generator  27 , an amplifier  28  and a second dc supply  29  through capacitor C 1 . As seen in FIG. 2, dc voltage supply  45  is connected to a pulse amplifier  47  and a pulse height control circuit  48  through a capacitor  46 . In FIG. 2, the pulse is commanded by the microelectronic CPU  51  through a digital-to-analog converter  49 . The base dc potential, which varied from 0 to 3000 volts, was superimposed on the pulsed potential. The combined potentials permit independent variation of the dc potential, pulse height, and pulse width to the corona tip. For a given pulse height, the ion mobility spectrum current can be measured as a function of dc bias voltage. For a higher pulse voltage, the current exhibited a threshold for the dc bias and increased to a saturation level. The dc threshold was found to linearly decrease from 3000 VDC to 200 VDC as the pulse height was increased from 200 VDC to 3000 VDC, as shown in FIG.  6 . Therefore, ions could be generated with lower voltage pulses if the dc base voltage were raised. The detector  25  in FIG. 2 is connected in close proximity to an amplifier  44  which amplified the small signal. This signal is then digitized by digitizer  50  to filter noise, and is then read by the microelectronic CPU  51 . For a specific substance, thresholds are set, and if a threshold is exceeded, a visual indication is provided to a user through an alarm display  52 , such as by illuminating an icon or changing the color of an object on a display screen. The electronic circuits  20  and  44 - 52  in FIG. 2 can be made quite compact and can be mounted on circuit boards. These can be packaged with the drift chamber body  11  in a package the size of a lightweight notebook computer of the type having a titanium case. 
     The pulsed corona ionization source of the present invention eliminates the need for the ion gate of the prior art near the ion source. It also provides for a smaller drift chamber and a smaller body for housing the drift chamber. The invention also provides a method for timing the movement of the ions between the source and the detector. The use of a dc voltage comprising a pulse element and a base voltage element reduces the pulse component, which reduces noise and power consumption. 
     This has been a description of detailed examples of the invention. It will apparent to those of ordinary skill in the art that certain modifications might be made without departing from the scope of the invention, which is defined by the following claims.

Technology Category: 3