WO2010118735A1

WO2010118735A1 - Micro-metering system having a pulsed laser

Info

Publication number: WO2010118735A1
Application number: PCT/DE2010/000424
Authority: WO
Inventors: Marcus Lörgen; Olaf Mertsch; Arne Schleunitz; Daniel Schondelmaier; Ivo Rudolph; Antje Mertsch
Original assignee: Helmholtz-Zentrum Berlin Für Materialien Und Energie Gmbh
Priority date: 2009-04-18
Filing date: 2010-04-13
Publication date: 2010-10-21
Also published as: DE102009018021B4; DE102009018021A1

Abstract

Known micro-metering systems for use in a variety of technical fields (print technology, EUV generation, metrology, chemical/biotechnological analytics) generate discrete fluid quantities into the femtogram range by way of micropumps, ultrasonic exciters, solenoid valves or displacement membranes. As an alternative, with the micro-metering system according to the invention, minimal gas clouds having discrete quantities up into the picogram and femtogram range are generated with a defined frequency and pulse duration by way of a pulsed laser (11). For this purpose, a rising capillary (07) self-filling with fluid (06) is provided, which protrudes into the flow duct (05) with a nozzle opening (09). The focus (13) of the pulsed laser (11) is directed at the nozzle opening (09) or at the rising capillary (07). The emitted laser pulses (12) have variable energy which is greater than the evaporation energy of the fluid (06), so that with each laser pulse (12) a gas cloud (02) is introduced into the flow duct (05) (depending on the laser focus (13), either by direct evaporation or by pressure pulse). Preferably laminarly stratified air flows in the flow duct (05). In order to prevent the gas clouds (02) from diffusing, the concentration thereof can be provided in the low pressure ranges (23) of an ultrasonic wave (22).

Description

DESCRIPTION

Microdosing system with a pulsed laser

DESCRIPTION

The invention relates to a Mikrodosiersystem for non-contact introduction of discrete quantities of fluid from a fluid reservoir into a walled and flowed through by a carrier gas flow channel via a metering with a front-side metering by means of a generator unit for generating the discrete fluid quantities, the metering and the generator unit outside the flow channel are arranged.

A microdosing system is a device with which microscopically small discrete quantities of fluid can be ejected in a volume range of less than one milliliter, preferably below one microliter into the femtoliter range. A distinction must be made between the contacting dosage, in which the amount of fluid is drawn off by contact with a substrate, and the non-contact dosage, in which the amount of fluid is released freely into the room. The non-contact dosage has the great advantage over the contacting dosage that no contact with the substrate and therefore no costly adjustment measures must be made with simultaneous risk of substrate damage. Therefore, the contactless dosing is the subject of many developments. The progressive miniaturization in almost all technical fields is an industry, Development laboratories and research institutions face ever new challenges. Smaller quantities of adhesives, oils, inks and a large number of other media must be dosed reliably with the shortest possible cycle times. In addition to the aspect of precise metering, there is also the aspect of a metered dosage which is required for analytical investigations, for example in the fields of pharmaceutics and biotechnology. Overall, a variety of different Mikrodosiersystemen in different fields is known.

STATE OF THE ART

In the field of inkjet printing technology, EP 1 212 133 B1 discloses droplet generation by pressure, exerted by one over one

Displacement diaphragm or a plunger actuated actuator known. In this case, self-filling rising capillaries are used as vertical metering lines in a print head, at whose lower ends are metering openings in which the fluid to be ejected is present. Self-filling stiffening capillaries are also known, for example, from DE 101 23259 A1, in which a

Microdosing system for microstructuring is presented. Furthermore, EP 0 158 485 A2 discloses a droplet generator in which fluid is pumped from a reservoir into a capillary as a dosing line. At the lower end there is a metering, which is arranged in the constriction of a venturi. Gas flowing through the venturi draws the drops out of the capillary, with the parameters of the gas and the venturi defining the drop parameters.

In the field of generation of extreme ultraviolet (EUV) radiation, it is further known, for example from US Pat. No. 6,493,423 B1, to use free-jet

Microdosing used, the finest droplets of fluid drip into a chamber in which the droplets then as targets of a laser pulse be irradiated and generate EUV radiation. Another type of droplet generating in the field of EUV radiation is known from DE 10260376 A1, in which supersaturated fluid vapor is passed under high pressure via a heatable expansion channel with a supersonic nozzle at its end. A pulsed electromagnetic valve releases the vapor into a vacuum chamber and forms liquid droplet targets upon cooling.

In the field of measurement technology, it is known from the prior art to use lasers in the droplet generation for the measurement of droplet parameters by detecting and evaluating different pulse parameters of a laser pulse after passing through the droplet (compare, for example, JP 2006047235 A, DE 603 04323 T2 ).

In the field of chemical analysis by detection of gaseous substances, it is known from US 6,601,776 B1 to pulse-heat a tubular Reservoirtank filled with a pressurized medium, so that it leads to a pulsed pressure increase and thus to a Discharge of droplets via openings in the reservoir tank comes. A similar arrangement is known from DE 10 2004030 769 A1 for the generation of droplets in the femtoliter range, but in this case the reservoir tank is divided in two by a pressure membrane under the action of a pressure source.

Also known in the field of chemical analysis is the so-called "laser ablation", in which solid or liquid target substances are evaporated in the smallest amounts by bombardment with a laser pulse and supplied to a spectrometer This method was used to analyze proteins previously immobilized and subsequently broken down by ultrashort laser pulse bombardment. In addition, it is also known from DE 690 10410 T2 to fix the substance to be examined by freezing on the substrate.

It is furthermore known from DE 2837799 A1 to drop a fluid directly onto a conveyor belt in a vacuum chamber by means of a microdispensing device with a micromembrane pump. On the conveyor belt, the drop is then moved into the focus of a laser and evaporated by a laser pulse. Alternatively, a continuous stream of gas can be directed onto the conveyor belt in the laser focus, while the conveyor belt serves to remove unevaporated residues. In a third embodiment, the drop is dripped freely into the vacuum chamber and evaporated by the laser pulse. The drops are generated by means of pressure pulses via a pressure membrane in the fluid reservoir, wherein the pressure pulse frequency is synchronized again with the laser pulse frequency. The generated molecules / atoms fly through a predetermined distance and are chromatographically detected with respect to their time of flight (TOF).

From DE 3735787 C2 a drop nebulizer is known in which a free fluid jet from a fluid reservoir via a nozzle expires and is passed through a field of two ultrasonic oscillators. Both oscillators form a standing sound wave with common nodes. The fluid jet is atomized in a node.

The closest prior art, from which the present invention proceeds, is disclosed in DE 199 26 464 A1. A microdosing system is described with the aid of which drops, there ink, as discrete fluid quantities, diameters between 5 μm and 200 μm, are ejected in a contactless manner into a hollow-cylindrical walled, few mm long flow channel. The flow channel is continuously flowed through by a pressurized carrier gas, for example air, which accelerates the drops and transports them to a substrate). The fluid is discharged from a fluid reservoir via a metering line which is widely dimensioned with respect to the drop dimensions and a metering opening is introduced axially into the flow channel from the end face thereof. The generator unit for the drops is an ultrasonic unit. The fluid jet emerging from the metering orifice is broken up into a high number (typically 64,000 / s) drops by means of ultrasound excitation and thereby charged electrically. Electric baffles then direct the drops onto the substrate to create a printed image.

TASK

The TASK for the present invention is therefore to provide an alternative Mikrodosiersystem that can easily deliver gas clouds with low-concentration substances and a defined frequency and duration of releases in a flow channel. The inventive solution for this task can be found in the main claim and the independent claim, advantageous developments of the invention are shown in the subclaims and explained in more detail below in connection with the invention.

The microdosing system according to the invention has an embodiment of the dosing line as a self-filling rising capillary, which penetrates the wall of the flow channel at least with the dosing opening. Capillaries are tubes with very small inner diameters. Due to the surface effects, which come to the fore in comparison with larger pipes, liquids with high surface tension in capillaries rise automatically (physical effect of capillarity). The end of the riser capillary is designed as a narrowing nozzle opening. Since this is located in the flow channel, the fluid to be metered, which rises by the design of the riser capillary without further pump technology in this, always automatically in the nozzle opening at the transition to the flow channel. Furthermore, the generator unit is designed as a pulsed laser whose focus is aligned either with the nozzle opening or with the riser capillary is. In this case, the emitted laser pulses to a variable energy greater than the evaporation energy of the fluid, so that the pending in the nozzle opening fluid is ejected as a defined gas cloud as a discrete fluid quantity in the flow channel each time a laser pulse. This is done either by direct energy input into the fluid when the laser focus is directly aligned with the nozzle opening. However, the gas cloud output can also be reached indirectly if the laser focus is aligned with the riser capillary. Due to the generated pressure pulse in the riser capillary when the laser pulse hits the fluid is expelled into the flow channel and evaporates there by relaxation behind the nozzle opening to a gas cloud as a discrete amount of fluid. This alternative is suitable for the dosing of fluids whose evaporation energy is correspondingly low, but the surface tension still has to be sufficient for the capillary effect.

In order to achieve the abovementioned object, the invention provides a microdosing system in which the fluid containing the substances contained is converted into the gas phase by means of a pulsed laser. For this purpose, the fluid is carried up by utilizing capillary forces in the riser capillary up to the metering opening and transported away from there by the carrier gas flowing in the flow channel. In this case, a gas cloud is generated in the dosing through direct laser bombardment or the fluid is ejected by indirect laser bombardment on the riser capillary through the pressure pulse generated in the capillary and thereby evaporates. By pulsing the laser, the frequency and duration of the gas clouds can be precisely defined. By changing the energy input by the laser pulse into the fluid fluids with different evaporation energies can be converted into the gas phase. Depending on the size of the evaporation energy, a direct or indirect laser pulse bombardment can take place, in particular fluids with low evaporation energy can be vaporized by indirect laser bombardment of the riser capillary, which reduces the risk of substance decomposition. Such microdosing under laser use for gas cloud formation offers the advantage of high-precision adjustability, so that gas clouds with different volumes into the Femtoliterbereich in high-precision and reproducible - even in their temporal occurrence - generated and can be discharged into the flow channel. Especially for applications in the field of (bio) chemical analysis, the microdosing system according to the invention is thus particularly suitable.

Preferably, the nozzle opening may be variable in diameter. This can be realized either by providing different nozzles or by providing a nozzle opening with an adjustable diameter, for example according to the iris principle. Preferably, an array of a plurality of riser capillaries may be provided, each nozzle orifice having a different diameter. The concentration or size of the generated gas cloud is then controlled by the control of the laser, the laser focus is then aligned with the corresponding nozzle opening or riser, thereby determines the size of the nozzle opening of the riser capillary (microcapillary) as a function of the penetration depth of the laser light in the fluid to be vaporized is the amount and concentration in the gas cloud generated by a laser pulse. In addition, with the aid of state-of-the-art microstructuring technology, the riser capillaries can be manufactured so small and so accurately that reproducible volumes can be evaporated with high precision. At the nozzle opening of the riser capillary a drop of a certain size is formed, which is determined by the surface tension and the diameter of the nozzle opening. This drop is then evaporated by the impinging laser pulse, wherein it is also possible to apply the energy required for the evaporation of the droplet also by a plurality of laser pulses.

Furthermore, the microdosing system according to the invention may advantageously be characterized by an alignment of the laser focus on the nozzle opening with a diametrical arrangement of the laser with respect to the nozzle opening. The laser pulses then pass through the flow channel exactly in diameter. The laser can also be arranged at any other angle to the metering, from which a laser focusing on the metering is possible. In an indirect excitation by laser pulse bombardment of the riser capillary, the laser can be arranged in any position, preferably laterally and preferably orthogonal to the riser capillary, outside the flow channel. In any case, a very compact construction of the microdosing system according to the invention results, in particular even if the riser capillary is preferably arranged below the flow channel, so that the fluid in the riser capillary rises vertically upwards. The gas clouds then enter the flow channel in the lower center in a streamlined manner and are detected by the carrier gas, which preferably forms a laminar flow, and transported away (in the direction of a detector). In this case, the flow channel is preferably flowed through continuously by the carrier gas. A pulsed flow is also possible, but the frequency must of course be matched to the frequency of the laser pulses or the gas clouds.

Due to the preferably laminar and continuous flow in the flow channel, the mass transport of the generated gas clouds between the flow layers takes place by diffusion. In order to curb or prevent smearing of the pulse pattern within the flow channel due to these transport mechanisms, in the microdosing system according to the invention a device for generating a pressure wave extending in the flow direction can advantageously be provided in the flow channel. The frequency of the pressure wave is tuned to the frequency of the pulsed laser so that each generated gas cloud is concentrated in a low pressure region of the pressure wave. Always between two high-pressure areas, a gas cloud in a low pressure area is transported contiguous, a smearing of the gas cloud is thereby reliably prevented. In this case, a sound source may be preferred as a device for generating the longitudinal

Pressure wave can be used. For example, by the preferred use of an ultrasonic source with an ultrasonic frequency in the range 20 kHz and 1 GHz, in particular a megasonic frequency between 400 kHz and 2 MHz, ultrasound waves can be generated, with the aid of which the individual gas clouds are kept and transported separately with the substances contained by the local pressure differences in the flow channel and transported so that mixing of the carrier gas and the gas cloud safely prevented becomes. The sound waves can be delivered continuously or pulsed into the flow channel.

The fluid can be of a liquid or gaseous nature, so that it rises automatically in the ascending capillary. At the end of the riser capillary, the fluid at the nozzle opening is then transferred to the gaseous state or kept there, when the fluid is a gas, and introduced into the flow channel. In a preferred embodiment of the microdosing system according to the invention, it may also be provided to position a cooling element below the freezing point in the area of the nozzle opening for cooling the fluid present in the nozzle opening, the laser focus then being aligned with the nozzle opening. By the cooling element, the pending in the nozzle opening fluid is very local (possibly even. Only partially in the nozzle opening) transferred to the solid state, which in individual cases, especially depending on the substance contained in the fluid, may be advantageous since the The substance to be examined can then be better positioned in the dosing opening and thus better in the laser focus. By way of the cooling element, it is possible to achieve such a localized freezing that complete evaporation of the solid fluid is ensured, so that subsequently new fluid can flow in.

The microdosing system according to the invention can preferably have as a pulsed laser a semiconductor, solid state or gas laser which can generate high pulse frequencies with high accuracy. The use of the simplest laser diodes is also readily possible. Due to the design of micro and nano channels, the micro dosing system according to the invention can be dimensioned extremely compact. The nozzle opening may be a United From a cross section in the micron range to a cross section in the nm range. As the carrier gas, air may preferably be used. Inert gases, which do not undergo mixing with the substances in the fluid, but can also be used. The fluid may preferably be a liquid or gaseous fluid of different vaporization energy from / with an ester, an ether, aromatics, aliphatic hydrocarbons, lactones, alkaloids, organic solvents, fragrances or pheromones and / or a derivative or a mixture thereof. As further preferred parameters for the microdosing system according to the invention may further be the generation of gas clouds with volumes in the range of 1 fl to 10 ul, a flow rate in the range of 1 .mu.m / s to 20 m / s, a laser wavelength up to a range of 10 μm, in particular in the UV, VIS or IR range, a repetition rate of the pulsed laser between 1 Hz and 1 GHz, a frequency of the gas clouds between 1 Hz and 100 kHz, a diameter of the riser capillary in a range of 10 μm and 1 mm, a diameter of the nozzle opening between 10 nm and 50 microns and / or a length of the flow channel can be called up to 1 m. Further details of the microdosing system according to the invention can be found in the following specific description part.

In practice, the microdosing system according to the invention may preferably be used with a modular design. In this case, a first module, consisting of laser, fluid reservoir, supply lines for the carrier gas and flow channel and a second module, consisting of riser capillary and nozzle opening, is used. The components of the two modules are variable in their parameter values. The modules can then be used depending on the application. In particular, the second module can be exchanged according to the requirement / application; different modules can then offer, for example, different sized nozzle openings. Embodiment

Embodiments of the microdosing system according to the invention are explained in more detail below with reference to the schematic figures for a further understanding of the invention. Showing:

FIGURE 1 is a schematic of the microdosing system with laser-assisted

Generation of gas clouds and

FIG. 2 shows the microdosing system according to FIG. 1 with additional sound-supported concentration of the gas clouds

DETAILED DESCRIPTION FIG. 1 shows the microdosage system 01 for contactless introduction of gas clouds 02 as discrete quantities of fluid from a fluid reservoir 03 into a flow channel 05 of the invention through which a carrier gas 04 flows schematically in the entirety and in a magnification section (circle, only ALTERNATIVE A). The gas clouds 02 may preferably have volumes in the range from 1 μl to 100 μl, but volumes may also be produced down to the range of 1 ml. The fluid may be a liquid or gaseous fluid of different vaporization energy, for example an ester, an ether, various aromatics, aliphatic hydrocarbons, lactones, alkaloids, organic solvents, fragrances or pheromones. Likewise, derivatives or mixtures thereof can be supplied to a detector, for example a mass spectrometer or a chromatograph, for biochemical analysis at the outlet of the flow channel.

The fluid 06 is transferred via a self-filling riser capillary 07 as dosing into the flow channel 05. The riser capillary 07 is preferably located in a radial plane of the flow channel 05 and points to its central axis. The riser capillary 07 may preferably have a diameter in one Range of 10 microns and 1 mm, wherein the selected diameter is also dependent on the fluid used (in liquids must occur due to the surface tension of the capillary effect, gases rise automatically) and may be above or below. In the flow channel 05, which may preferably have a length of a few centimeters up to 1 m, air may be present as carrier gas 04, which may flow at a flow velocity in the range of 1 μm / s to 20 m / s. The formation of a laminar flow 08 is preferred. Also advantageous is a continuous flow through the flow channel 05. At a very low ejection frequency of the gas clouds 02, the preferred ejection frequency is between 1 and 100,000 releases per second, the flow can also be pulsed accordingly.

The riser capillary 07 is located outside the flow channel 02 and has an end-side narrowing nozzle opening 09 as a metering opening. Preferably, the narrowest diameter of the nozzle opening 09 may be in a range between 10 nm and 50 microns. Through the nozzle opening 09, which breaks through the wall 10 of the flow channel 05, the gas clouds 02 are discharged into the flow channel 05. In the illustrated embodiment, the riser capillary 07 is arranged below the flow channel 05, so that the gas clouds 02 enter the flow channel 05 in its lower center and can be optimally absorbed by the carrier gas 04. For example, the nozzle opening 09 can also be guided into the middle of the flow channel 05, but here attention must be paid to a sufficient rigidity of the riser capillary 07 and to a vortex avoidance in the channel flow. In the illustrated embodiment, the riser capillary 07 is well supported in the wall 10 of the flow channel 05 and therefore can be flexible outside as well.

To generate the discrete gas clouds 02, a pulsed laser 11 is used in the microdosing system 01 according to the invention as a generator unit-likewise located outside the flow duct 05. It can be For example, be a semiconductor, solid state or gas laser. CO ₂ gas lasers, for example, generate laser pulses 12 up to the fs range with high accuracy and creep resistance. A repetition rate of the pulsed laser 11 between 1 Hz and 1 GHz and a laser wavelength of up to a range of 10 μm, in particular in the UV, VIS or IR range, is preferably used. In this case, the laser pulses 12 have a variable energy content, which is greater than the evaporation energy of the pending in the nozzle opening 09 fluid. The focus 13 of the laser 11 is aligned in the illustrated embodiment (ALTERNATIVE A) directly to the nozzle opening 09 of the riser capillary 07, so that the upcoming in the nozzle opening 09 fluid evaporates a gas cloud 02 directly into the flow channel 05 at each impinging laser pulse 12. Furthermore, in the embodiment shown, the laser 11 is arranged diametrically opposite the nozzle opening 09, so that the laser pulses 12 pass through the flow channel 05 centrally along its diameter.

Optionally, with a focus 13 of the laser 11 directly onto the nozzle opening 09 (ALTERNATIVE A), a cooling element, for example a Peltier element, can be arranged so that the pending fluid freezes locally so that an improved laser bombardment is possible (not shown in FIG. 1). , Due to its selected energy content, the entire solid, frozen fluid is then vaporized by the laser pulse 12 so that new fluid can flow into the nozzle opening 09.

In the ALTERNATIVE B in FIGURE 1, an arrangement of the laser 11 is shown laterally from the riser capillary 07, and in particular orthogonal thereto. The focus 13 of the laser 11 is now aligned with the riser capillary 07 so that the laser pulses 12 impinge on the riser capillary 07 and trigger a pressure pulse in their interior, whereby each fluid (in volatile form) as a gas cloud 02 from the nozzle opening 09 in the flow channel 05 is launched. FIG. 2 schematically shows a sound source 20 for generating a pressure wave 22 running in the flow direction 21 in the flow channel 05, whereby smearing of the gas clouds 02 in the laminar flow 08 in the flow channel 05 can be avoided. In this case, the frequency of the pressure wave 22 is tuned to the frequency of the pulsed laser 11 such that each generated gas cloud 02 is concentrated in a low-pressure region 23 between two high-pressure regions 24 of the pressure wave 22. The sound source 20 preferably has an ultrasound frequency in the range of 20 kHz and 1 GHz, in particular a megasonic frequency between 400 kHz and 2 MHz.

Due to the small dimensions of the microdosing 01 according to the invention in the form of micro and nanochannels (flow channel 02, riser capillary 07) and the controllable energy input by means of a laser 11, the concept presented allows the highly accurate, adjustable dosage of dilute and undiluted fluids 06 in the form of gas clouds 02 with discrete amounts into the pico and femtogram range with a defined frequency and pulse duration. Thus, the microdosing 01 according to the invention is particularly suitable for applications in the chemical and biotechnological field.

For example, butyl acetate having an enthalpy of vaporization of about 40 kJ / mol, a density of 0.88 g / mol and a molecular weight of 116 g / mol can be used for the analysis as volatile liquid for evaporation. The riser capillary can have a diameter of 20 .mu.m and the nozzle orifice a diameter of 2 .mu.m (narrowing 10: 1). The flow channel may have a diameter of 2 mm and a length of 10 cm. Therefore, the components used are microcomponents. For evaporation, a pulsed IR laser with 1200 nm wavelength and a power of 1 W can be used. The opening of the ascending capillary (micro capillary) allows an ideal spherical volume of 4.2 μm ³ (1 μm radius), corresponding to 4.2 fi (femtoliters). This volume contains 4,3 -10 ^"10 moles of n-butyl acetate, which is to be evaporated with a laser pulse, the energy required is 17 μJ, ie the laser pulse with a power of 1 W must be 17 μs long in order to obtain the laser pulse corresponding energy is applied (P = 1 W, E = 1, 7-10 ^'5 J, ^■ * t _pu _s = E / P = 17 μs), for example, the carrier gas flows through the flow channel at 0.5 m / s the repetition rate of the laser should be 200 Hz, then a mean distance of the vaporized gas clouds of 2.5 mm sets in (all numerical values given are only reference values for corresponding value ranges).

LIST OF REFERENCE NUMBERS

01 microdosing system

02 gas cloud

03 fluid reservoir

04 carrier gas

05 flow channel

06 fluid

07 climbing capillary

08 laminar flow

09 nozzle opening

10 wall

11 pulsed laser

12 laser pulse

13 laser focus

20 sound source

21 flow direction

22 pressure wave

23 low pressure area

24 high pressure area

Claims

1. Microdosing (01) for non-contact introduction of discrete quantities of fluid from a fluid reservoir (03) in a walled and flowed through by a carrier gas (04) flow channel (05) via a dosing with an end-side dosing by means of a generator unit for generating the discrete amounts of fluid wherein the dosing line and the generator unit are arranged outside the flow channel (05),

Characterized by an embodiment of the metering line as a self-filling rising capillary (07), which penetrates the wall (10) of the flow channel (05) at least with the metering opening, which is designed as a narrowing nozzle opening (09), and a formation of the generator unit as a pulsed laser (11) whose focus (13) is aligned with the nozzle opening (09) or on the riser capillary (07) and whose emitted laser pulses (12) have a variable energy greater than the evaporation energy of the fluid (06), with each laser pulse ( 12) a gas cloud (02) is introduced into the flow channel (05).

2. Microdosing according to claim 1, CHARACTERIZED by a variable diameter of the nozzle opening (09) or an array arrangement of several riser capillaries (07) with nozzle openings (09) of different diameters.

3. microdosing system according to claim 1,

Marked by an alignment of the laser focus (13) on the nozzle opening (09) with a diametrical arrangement of the pulsed laser (11) relative to the nozzle opening (09).

4. microdosing system according to claim 1,

Marked by an alignment of the laser focus (13) on the riser capillary (07) with an orthogonal arrangement of the pulsed laser (11) to the riser capillary (07).

5. microdosing system according to claim 1,

CHARACTERIZED BY an arrangement of the riser capillary (07) below the flow channel (05).

6. microdosing system according to claim 1,

CHARACTERIZED BY a laminar flow (08) of the carrier gas (04) in the flow channel (05).

7. Mikrodosiersystem according to claim 1, characterized by a device for generating a in the direction of the flowing carrier gas (04) (flow direction (21)) extending pressure wave (22) in the flow channel (05), wherein the frequency of the pressure wave (22) so on the Frequency of the pulsed laser (11) is tuned, that each generated gas cloud (02) in a low pressure area (23) of the pressure wave (22) is concentrated between two high pressure areas (24).

8. microdosing system according to claim 7,

CHARACTERIZED BY a sound source (20) as a device for generating the pressure wave (22) running in the flow direction (21).

9. microdosing system according to claim 1,

CHARACTERIZED BY a cooling element in the region of the nozzle opening (09) for cooling the fluid (06) present in the nozzle opening (09) below the freezing point is provided, wherein the laser focus (13) is directed to the metering opening (09).

10. Mikrodosiersystem according to claim 1, CHARACTERIZED BY a semiconductor, solid state or gas laser as a pulsed laser (11).

11. microdosing system according to claim 1,

CHARACTERIZED BY AIR as carrier gas (04).

12. microdosing system according to claim 1,

Characterized by a liquid or gaseous fluid (06) of different evaporation energy from / with an ester, an ether, aromatics, aliphatic

Hydrocarbons, lactones, alkaloids, organic solvents, fragrances or pheromones and / or a derivative or a mixture thereof.

13. microdosing system according to claim 1,

MARKED BY

Gas clouds (02) with a volume in a range of 1 fl to 10 ul, a flow rate in the range of 1 .mu.m / s to 20 m / s, a laser wavelength up to a range of 10 .mu.m, in particular in the UV, VIS or IR range, a repetition rate of the pulsed laser (11) between 1 Hz and 1 GHz, a frequency of the gas clouds (02) between 1 Hz and 100 kHz, a diameter of the riser capillary (07) in a range of 10 microns and 1 mm, a diameter of the nozzle opening (09) between 10 nm and 50 microns and / or a length of the flow channel (05) not equal to zero up to 1 m.

14. microdosing system according to claim 7,

CHARACTERIZED BY an ultra-sound frequency in the range 20 kHz and 1 GHz, in particular a megasonic frequency between 400 kHz and 2 MHz.

15. microdosing system according to claim 1 and / or 7,

Characterized by a modular construction with a first module consisting of laser (11), fluid reservoir (03), supply lines for the carrier gas (04) and flow channel (05), and a second module consisting of riser capillary (07) and nozzle opening ( 09), whereby the components of the two modules are variable in their parameter values.