This invention relates to a photo acoustic sample detector for detecting a concentration of sample molecules in a sample mixture, the photo acoustic sample detector comprising, an input for receiving the sample mixture, an acoustic cavity for containing the sample mixture, a light source for sending light into the acoustic cavity for exciting the sample molecules and thereby causing sound waves in the acoustic cavity and a pick up element for converting the sound waves into electrical signals.
The invention further relates to a breath analysis device comprising such a photo acoustic sample detector.
Photo acoustic spectroscopy is a well known technique for measuring concentrations of different molecules in gases, down to ppb (parts per billion) level. This makes it suitable for measuring different molecules present in human breath. Generally lasers are used as light sources in photo acoustic spectroscopy. The laser light is collimated and the laser wavelength is tuned to excite the sample molecules into a higher energy level. This excitation leads to an increase of the thermal energy, resulting in a local rise of the temperature and the pressure inside the acoustic cavity. If the laser intensity is modulated at a resonance frequency of the acoustic cell, the pressure variations result in a standing acoustic wave. The acoustic waves are detected by a pick up element.
A disadvantage of the known photo acoustic sample detectors is that the optical alignment becomes very critical when the diameter of the acoustic resonator is small in order to obtain a low detection limit.
It is an object of the invention to provide a photo acoustic sample detector wherein the optical alignment of the system is less critical. According to a first aspect of the invention, this object is achieved by providing a photo acoustic sample detector according to the opening paragraph, further comprising a light guide, the light source being arranged for illuminating the light guide, the light guide comprising a transparent inner wall at an interface of the light guide and the acoustic cavity and a reflective outer wall at an outside of the light guide for reflecting the light back and forth through the light guide and the acoustic cavity.
When the light arrives at the interface between the light guide and the acoustic cavity, it will pass the transparent wall, travel through the acoustic cavity and enter the light guide again at the light guide-cavity interface at the other side of the acoustic cavity. At an outer wall of the light guide, the light will be reflected. The reflected light may return to the acoustic cavity directly or via one or more additional reflections within the light guide. Because the light reflects back and forth through the light guide and the acoustic cavity, it passes the acoustic cavity many times. Each time the light passes the acoustic cavity it has a chance of exciting sample molecules. When the light passes the acoustic cavity more often, the sensitivity of the detector is significantly enhanced.
In the configuration according to the invention, the direction of the optical rays is not as critical as in the prior art, which enables the use of a divergent light source instead of the collimated laser beam of the prior art photo acoustic sample detectors. It is to be noted that it is known to use a combination of a collimated laser beam and a multi pass configuration. However, that combination needs a highly accurate optical alignment. Furthermore, to enable the multiple beams to pass the acoustic resonator its diameter has to be increased which makes the detection limit worse. According to the invention, the use of the light guide with a transparent light guide-cavity interface and reflective outer walls obviates those strict alignment requirements of the prior art and allows the use of a small diameter acoustic resonator improving the detection limit.
The photo acoustic sample detector according to the invention may use a collimated or uncollimated diode laser as light source, but preferably, the light source comprises at least one light emitting diode (LED). The LED should have an emission spectrum, overlapping an absorption spectrum of the sample molecules. The diode lasers used for known photo acoustic sample detectors have a temperature dependent wavelength. When the laser is not temperature stabilized, the measurement is susceptible to temperature variations. For, e.g., NO2 concentration detection a blue LED forms a very attractive light source because the NO2 absorption spectrum is very broad (so all the LED light is available for sensing) while the broader spectrum of the LED compared to the fine structure in the NO2 absorption spectrum lead to an averaged spectral response which is relatively insensitive to the central wavelength and temperature of the LED. Moreover, LEDs are usually cheaper than diode lasers and available with higher output powers. The prior art photo acoustic sample detectors do generally not use LED light, because it can not be easily collimated and sent along the tube of the acoustical cavity.
The light guide is preferably made of a material with a low optical absorption to prevent photo acoustic signal generation in the light guide which could lead to a background photo acoustic signal during photo acoustic detection of the sample. The outer reflecting walls of the light guide can be made of metal or use can be made of total internal reflection at the light guide walls. When a metal is used, a small part of the light will be absorbed during reflection leading to a photo thermal response. However, due to the fact that the optical light guide thermally isolates the metal reflectors from the acoustic cavity, this will introduce no photo acoustic background signal.
An embodiment of the photo acoustic sample detector according to the invention further comprises an additional light emitting diode with an emission spectrum that is mainly outside the absorption spectrum of the sample molecules. Because the light from the additional LED does not contribute to the detector signal by exciting sample molecules, this additional LED can be used to compensate for background signals caused by light absorption in the neighborhood of the light guide-acoustic cavity interface.
Preferably, the pick up element is optically shielded from the light from the light guide in order to reduce direct excitation of the pick up element.
In one embodiment, a cross section of the light guide is arranged to provide a spiral light path for guiding the light spirally through the light guide and the acoustic cavity from an outer radius of the light guide to an inner radius, such that the light passes through the acoustic cavity twice per rotation. In this embodiment, the number of times that the light passes the cavity is optimized by guiding the light to the acoustic cavity and preventing light from bouncing back and forth in the light guide without passing the acoustic cavity at all. These and other aspects of the invention are apparent from and will be elucidated with reference to the embodiments described hereinafter.
In the drawings:
a shows a cross section of a photo acoustic sample detector with two sample volumes and
The light 50 is guided to the acoustic cavity 3 by a light guide 2. The light guide 2 is made of glass, quartz, PMMA or another (mixture of) material with a low absorption at the wavelengths applied. Preferably, all walls 8 at the interface of the light guide 2 and the acoustic cavity 3 are transparent for allowing the light 50 to enter or leave the cavity 3. All other walls 7 are preferably reflective, for reflecting a high percentage of the light 50 back into the light guide 2. For reflecting the light, total internal reflection, a metal reflection layer or an appropriately chosen dielectric layer stack can be used. At the walls where the rays have an angle suitable for total internal reflection, this method is preferred because the percentage of the light reflected is higher than for reflection on a metal or dielectric layer stack. While the light 50 reflects back and forth within the light guide, it may cross the acoustic cavity 3 many times. The average number of times that the light 50 crosses the acoustic cavity 3 before it is absorbed in the material of the light guide 2 or leaves the light guide 2 at an outer wall 7, may be increased by coating the transparent walls 8 with an antireflective coating. In the embodiment shown in
An additional light source 6 may be provided for enabling background signal compensation. The additional light source 6 emits light 60 at a wavelength that is not or significantly less absorbed by the sample molecules. Consequently, detector signals caused by this additional light source 6 will mainly be caused by direct excitation of the pick up element 4 by the light 60 or by a thermal effect of light 60 that is absorbed at the cavity-light guide interface. The background signal originating from the additional light source 6 may be used for compensating the measurements performed with the main light source 5. Preferably, both light sources 5 and 6 are modulated in antiphase. The intensity of the light source 6 is chosen such that the background signals from both sources cancel each other. The modulated light intensity of the main light source 5 will cause sound waves with an amplitude depending on the sample concentration.
a shows a configuration with a light guide encompassing two acoustic cavities 3a, 3b and two sample flows 1a, 1b. The light 50 from the sources 5 passes through both acoustic resonators. The tuning fork pickup elements 4a, 4b are placed inside the acoustic resonators. The tuning forks are connected in a differential mode and the molecules to be sensed are only present in one of the two sample streams. In this way background signals from a number of origins can be cancelled simultaneously without the use of two wavelength light sources as in the embodiment of
It should be noted that the above-mentioned embodiments illustrate rather than limit the invention, and that those skilled in the art will be able to design many alternative embodiments without departing from the scope of the appended claims. In the claims, any reference signs placed between parentheses shall not be construed as limiting the claim. Use of the verb “comprise” and its conjugations does not exclude the presence of elements or steps other than those stated in a claim. The article “a” or “an” preceding an element does not exclude the presence of a plurality of such elements. The invention may be implemented by means of hardware comprising several distinct elements, and by means of a suitably programmed computer. In the device claim enumerating several means, several of these means may be embodied by one and the same item of hardware. The mere fact that certain measures are recited in mutually different dependent claims does not indicate that a combination of these measures cannot be used to advantage.
Number | Date | Country | Kind |
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07111904.4 | Jul 2007 | EP | regional |
07117960.0 | Oct 2007 | EP | regional |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/IB08/52627 | 6/30/2008 | WO | 00 | 1/5/2010 |