The present invention relates to a novel dielectric sensing method and apparatus for detection and classification of chemical and biological materials.
A dielectric is a substance or material that has very low electrical conductivity. The dielectric constant of a material is the ratio of the strength of an electric field in a vacuum to that in the dielectric for the same distribution of charge. The dielectric property of a material, whether it is solid, liquid or gas, generally changes with material property, chemical property and excitation frequency. There are many methods for measuring the dielectric properties of materials, such as lumped element, transmission line, free-space, and resonate techniques. These techniques, depending on sample size and geometry can provide accurate determination of complex dielectric constants of materials in a laboratory setting. However, though many methods of measuring the dielectric properties of materials exist in the literature, such methods lack specificity in identifying materials. Few chemical or biological sensors based on such dielectric measurements exist at this time.
A need exist for an effective real-time dielectric sensor for detection and classification of chemical and biological species.
A principal object of the present invention is to provide a dielectric sensing method and apparatus for detection and classification of chemical and biological materials.
In brief, a dielectric sensing method and apparatus are provided for detection and classification of chemical and biological materials. Resonance patterns of a sample within a resonator are detected for identifying a shift in resonance frequency and a change of line width before and after introduction of the sample. The resonance patterns can be generated either as a function of sample concentration or as a function of excitation frequency for a given sample. The identified shift in resonance frequency and change of line width are used for determining a complex dielectric constant of the sample for the material detection and classification.
In accordance with features of the invention, a degree of selectivity at any excitation frequency is enabled for the dielectric sensing method of the invention from the manner in which the complex dielectric constant of a material affects the resonance pattern of the resonator with respect to shift in resonance frequency and the change in line width. By selecting the excitation frequencies to generally correspond to one of the resonance frequencies of the sample material under test, the degree of selectivity and the sensitivity of detection are enhanced.
In accordance with features of the invention, a cylindrical microwave cavity resonator is used for dielectric sensing and changes in the resonant frequency and quality factor before and after introduction of the sample for small perturbation to the cavity field are identified. The cylindrical microwave cavity resonator is used for gas and solid samples and an RF parallel-plate resonator is used for subsurface liquid contaminant detection.
The present invention together with the above and other objects and advantages may best be understood from the following detailed description of the preferred embodiments of the invention illustrated in the drawings, wherein:
Features of the preferred embodiment include a new method that provides a degree of selectivity based on the extent to which the complex dielectric constant of a material affects the signal pattern of a resonator. A microwave cavity has been used to demonstrate the proof of principle of selectively detecting gas-phase chemicals and biological macromolecules. The method is applicable at any excitation frequency from RF to terahertz range; however, if the excitation frequency is selected to correspond to one of the resonance frequencies, relaxation-type or spectroscopic, of the material under investigation, the degree of selectivity and the sensitivity of detection can be improved significantly. For example, dielectric materials exhibit relaxation-type resonance at microwave frequencies, and DNA molecules appear to exhibit distinct resonance interactions at terahertz frequencies. With such unique absorption spectra being identified for materials, the method can be applied to a standoff sensing configuration. The resonance-enhanced dielectric method, thus, holds the potential for a fast first screening of chemical or biological agents in the form of gas, powder, or aerosol.
This resonance technique, because of its high quality factor, offers higher detection sensitivities than non-resonant techniques. The method of the invention has a range of applications in including pollutant monitoring, automobile exhaust gas emissions, detection of biowarfare agents in the form of aerosols or powdered spores, chemical warfare agents and long-term monitoring of subsurface contaminant plumes.
The dielectric property of a material is described by its complex dielectric constant, denoted by ∈=∈′−j∈″. The real part, ∈′, is known as the permittivity, and the imaginary part, ∈″, represents the loss in the material. The loss may be due to dielectric damping of the vibrating dipoles and/or due to its conductivity, σ. The equivalent loss is described by (∈″+σ/ω), where ω is the frequency in radians. Dielectric constants of materials are often stated in terms of relative permittivity, ∈r′ and the loss tangent, tan δ, in which ∈r′=∈′/∈0, where ∈0 is the permittivity of free space, and tan δ=(ω∈″+σ)/ω∈′.
The dielectric constant of a material generally changes with the excitation frequency, physical property, chemical property, and constituent volume contents. A variation of complex electric susceptibility χe of a typical solid or liquid dielectric material and χe is related to dielectric constant by χe=1+∈r′−j∈r″, which includes dipole (χed), ionic (χei), and electronic (χee) polarizations. In the RF and MW frequency range, the well-known Debye equation gives the variation of ∈r′ and ∈r″ as a function of frequency:
where ∈′rs and ∈′r∝ are the real part of permittivity at zero and very large frequencies, respectively, and τ is the relaxation time constant of the material. Near the relaxation frequency of the material, the ∈′ sharply decreases with frequency and ∈″ exhibits resonance behavior.
The dielectric constant of gases depends on the polar nature of the molecule, as well as frequency of excitation, pressure, and temperature. The real part, ∈r′ is generally related to square of the index of refraction, and the imaginary part, ∈r″ is related to spectral absorption of gases corresponding to rotational, vibrational, or electronic energy transitions that occur at microwave, infrared, and optical frequencies, respectively.
Resonant perturbation techniques offer a sensitive means of measuring the dielectric properties of low-loss and medium-loss materials. Resonant perturbation techniques are suitable for gases, solids, or liquids, and allow flexibility in sample size and shape. Commonly used resonant devices include transmission-line resonator in the RF, cylindrical cavity in the microwave, and Fabry-Perot cavity in the millimeter-wave spectral ranges. The complex dielectric constant of a sample placed in a resonator can be deduced from the changes in the resonant frequency and the quality factor before and after introduction of the sample for small perturbation to the cavity field. The underlying perturbation equations are:
where f0 and fs are the resonant frequencies, QU0 and QUs are the unloaded quality factors, E0 and Es are the electric field in the cavity, before and after introduction of the sample, respectively, and Vs and Vr are the sample and resonator volumes, and C is assumed to be a constant for small perturbations. In this case, the shift in resonance frequency δF denoted by the left hand side of Equation (3) is proportional to the ∈r′, and the change in line width δT denoted by the left hand side of Equation (4) is proportional to ∈r″. The dielectric sensing technique of the preferred embodiment uses these two measurement parameters in the material detection and identification scheme.
Having reference now to the drawings, in
Microwave cavity resonator 100 of the preferred embodiment includes a cylindrical microwave cavity 102, for example, made of brass with a radius labeled R of 2 cm and a height labeled H adjustable from 1.5 cm to 4 cm by a cavity adjusting screw mechanism generally designated by reference character 104. Cylindrical microwave cavity 102 can support resonance frequencies for the adjustable height of 1.5 cm and 4 cm corresponding to 13.5 GHz to 10 GHz, respectively.
Cylindrical microwave cavity 102 is coupled by a pair of loop antennas 106. Each loop antennas 106 is attached to a respective SMA connector 108 and mounted on an upper cavity plate 110. The coupling strength can be varied by adjusting the relative position of the pair of loop antennas 106 with respect to the cavity face. Cylindrical microwave cavity 102 includes a lower cavity plate 112 having a gas inlet 114 and a gas outlet 116. The positions of the gas inlet 114 and gas outlet 116 do not have much bearing on the measurement sensitivity because the gas samples occupy the whole cavity space 102. Solid samples, however, must be placed at locations of maximum electric or magnetic field for sensitive measurements. A sample holder 118 for solids samples preferably is located on the bottom plate 112 at 0.48×radius where the magnetic field is maximum.
The cavity response is measured by a vector network analyzer (VNA) 120 using the S21 transmission mode. Vector network analyzer 120 can be implemented, for example, with a HP 8720D vector network analyzer. Data is collected from the vector network analyzer 120 by a personal computer 122 using GPIB interface 124 and processed in the computer 122 using, for example, LabVIEW application software.
The network analyzer 120, after two-port calibration at the cavity ports with open, short, and load, was set to measure the cavity transmission parameter S21 from port 1 to port 2.
Referring to
where f is the resonance frequency of the resonator and δf is the full width at half maximum of the resonance line. The unloaded quality factor, QU is then obtained from:
where QU is the unloaded quality factor and |S21 p| is the peak value of the magnitude of S21; the calculated QU for the response in
Referring to
The microwave cavity 102 has been used for dielectric testing of biomolecules. The biomolecules were prepared or procured in powder form and were introduced in known quantities into a Teflon sample holder 118 located at 0.48×radius on the bottom plate 112, where the magnetic field is maximum. The bottom plate 112 is mounted on a computer controlled translation stage (not shown) so that the bottom plate can be lowered for sample loading and raised to the same position for closing the cavity.
Four powder samples were tested in the cavity by recording the S21 parameters at varying concentrations. The samples tested were acetaminophen (powdered Tylenol caplet), isobutylphenyl propionic acid (powdered Ibuprofen caplet), bovine albumin (protein) from Sigma-Aldrich, and herring sperm DNA from Sigma-Aldrich. The cavity with the Teflon sample holder was tuned to a reference resonance frequency of 10.43 GHz.
In
Referring now to
where d is the plate separation and w the width of the plates 502, 504. The width w=2 in. and plate separation d=0.25 in. was selected to provide a characteristic impedance of 50 Ω. A 6 in. long (height of the plates indicated by arrow L) open resonator 500 was connected to a 5.5 in. long coaxial cable 506. A weak coupling 508 was used to excite the resonator 500. Reflection coefficient (S11) measurements were made using the same HP 8720D vector network analyzer 120 and data processing using computer 122 as shown in
Topsoil was placed in a conventional oven and dried. A fixed amount of the topsoil, 447 g, was then placed into a plastic container. The parallel plate sensor plates 502, 504 were then inserted three inches into the topsoil by a computer-controlled translation stage (not shown). Various chemicals were injected between the plates by means of a syringe at 0.5 cc increments from 0.5 to 4.5 cc. Data were collected at each concentration after a one minute interval to allow for the chemical to migrate through the soil. Four chemicals were tested including isopropanol, acetone, methanol, and ethanol.
In brief summary, a new dielectric sensing technique has been provided for detection and identification of chemical and biological materials in gas, liquid, or solid form. The microwave cavity resonator 100 of
While the present invention has been described with reference to the details of the embodiments of the invention shown in the drawing, these details are not intended to limit the scope of the invention as claimed in the appended claims.
The United States Government has rights in this invention pursuant to Contract No. W-31-109-ENG-38 between the United States Government and Argonne National Laboratory.