In-situ measurement of nitrate in soil

The invention claimed is: 1. A system for measuring with the aid of light absorption spectrometry the concentration of one or more analytes in porewater in soil, the system comprising: one or more monitoring unit(s), each monitoring unit comprising a porewater sampler, an optical flow cell with a tube connecting the liquid inlet port of said optical flow cell to said porewater sampler; and vacuum arrangement to enable extraction of porewater, said vacuum arrangement comprising a sampling cell charged with vacuum, with a tube connecting the optical flow cell's outlet port to the sampling cell; at least one light source for generating a light beam to be transmitted through said optical flow cell; and at least one detector for obtaining spectral information from the beam exiting said optical flow cell. 2. A system according to claim 1 , comprising: one or more monitoring unit(s), each monitoring unit consisting of a porewater sampler, an optical flow cell and a sampling cell, with tubes connecting the liquid inlet and outlet ports of said optical flow cell to said porewater sampler and sampling cell, respectively; a vacuum generating device to enable extraction of porewater, said device being a vacuum pump for charging the sampling cell with vacuum; at least one light source for generating a light beam to be transmitted through said optical flow cell; and at least one detector for obtaining spectral information from the beam exiting said optical flow cell. 3. A system according to claim 1 , comprising an array of individual monitoring units installed at different locations across a field to create a network of sampling points in said field. 4. A system according to claim 3 , wherein the system comprises a single light source and a single detector. 5. A system according to claim 4 , further comprising a mechanical control unit to divert the light beam generated by said single light source between the optical flow cells of the individual monitoring units, wherein the mechanical control unit comprises fiber optic multiplexer. 6. A system according to claim 1 , comprising an array of individual monitoring units installed along a borehole with the aid of a sleeve inserted into the borehole and filled to achieve tight contact to the wall of the borehole, to create a network of sampling points along said borehole. 7. A system according to claim 6 , comprising a single light source and a single detector. 8. A system according to claim 6 , wherein the optical flow cell has a front face through which a light beam travelling from the light source via an illumination optical fiber enters said optical flow cell, and a rear face through which a light beam exiting the optical flow cell is guided via a sample optical fiber to the detector, wherein the optical flow cell is provided with an optical arrangement comprising at least one of the following: one or more lenses mounted in the front side and/or one or more lenses mounted in the rear side of said optical flow cell; one or more deflectors and/or mirrors mounted in the front side and/or one or more deflectors and/or mirrors mounted in the rear side of said optical flow cell; wherein the optical arrangement is configured to focus the light beam traveling via the illumination optical fiber onto said optical flow cell, and/or to reflect light beam exiting said optical flow cell back to the said optical flow cell; and wherein the system further optionally comprises one or more of spatial light modulator and/or modulators at the output of said illumination fiber or inlet of said sample fiber, wherein each optical flow cell is associated with a specific code or frequency; the system further comprising a controller and a computer to assign each monitoring unit with said code or frequency. 9. A system according to claim 1 , wherein the porewater sampler comprises a porous interface in the form of a lateral surface of a cylinder designed to have a minimal inner dead volume or an elongated body bounded by a porous lateral surface with a spacer disposed within the interior defined by said lateral surface, said spacer occupying at least 90% of the volume of said interior space. 10. A system according to claim 9 , wherein the porewater sampler comprises a pipe bounded by a lateral surface made of porous ceramic material and a cylindrical spacer coaxially positioned within said pipe. 11. A system according to claim 1 , wherein tube connecting the liquid inlet port of the optical flow cell to the porewater sampler is made of chemically resistant plastic with inner diameter from 1.0 to 2.0 mm. 12. A system according to claim 11 , wherein the volume of the cavity in the optical flow cell is from 1 to 2 ml. 13. A method of quantitative in-situ and real time monitoring with the aid of light absorption spectrometry of one or more analytes in porewater, the method comprising: extracting porewater from soil using a porewater sampler, to produce a porewater stream; directing said porewater stream into an optical flow cell; transmitting light beam across the porewater stream flowing through the optical flow cell; obtaining spectral information from the beam exiting the optical flow cell to determine the concentration of one or more analytes in the porewater with the aid of a first calibration curve constructed at a first selected wavelength suitable for the chemical composition of the soil and concentration range of said analyte; and switching to a second calibration curve constructed at a different wavelength if the concentration measured is not within said concentration range associated with said first calibration curve. 14. A method according to claim 13 , comprising discharging the porewater stream to a sampling cell to enable collection of samples. 15. A method according to claim 13 , wherein the method is for multi-point measurements across a field from a plurality of sampling points, each point equipped with a monitoring unit consisting of porewater sampler, an optical flow cell and optionally a sampling cell. 16. A method according to claim 15 , wherein the first and second calibration curves are chosen from a preset library of calibration curves generated by obtaining raw samples from one or more sampling points in the field, following which the raw samples are optionally spiked and diluted, to create a low and high concentration ranges solutions which are used to form calibration curves adoptable for the chemical composition of the porewater in each individual sampling point. 17. A method according to claim 16 , wherein the wavelength at which a calibration curve is created is determined by a procedure comprising the steps of: A) obtaining a set of samples S i {S 1 , S 2 , S 3 , . . . , S i , . . . , S n }, B) determining concentrations C i (C 1 , C 2 , C 3 , . . . , C i , . . . , C n ) of said samples; C) measuring the absorbance intensity versus wavelength across a predetermined range spanning the λ 1 to λ final region for each sample S i (1≤i≤n), to ascribe to each sample S i a set of absorbance readings A(i) (1≤i≤n): A(i){A(i)) λ1 , A(i) λ2 , A(i)) λ3 . . . A(i) λk , . . . A(i)λ final }, wherein A(i)) λk indicates the absorbance intensity measured for sample Si at a specific wavelength λ k , D) determining optimal wavelength λ o for calibration, by searching for a set of data consisting of A(i)λ o (1≤i≤n) which fits the best to the set of data of known concentrations C i (1≤i≤n). 18. A method according to claim 13 , wherein the analyte is nitrate ion and the light beam is a light beam in the 190 to 850