Geotextile

The invention claimed is: 1. A geosynthetic element for a geotechnical engineering application for forming solid calcium carbonate in a soil material, the geosynthetic element comprising: bacteria carriers comprising calcifying bacteria, the calcifying bacteria being arranged to propagate from the bacteria carriers to a surrounding soil material; and a flow network comprising openings on the surface of the flow network to allow a reactant to propagate from the flow network to the surrounding soil material along the flow network to produce solid calcium carbonate, the flow network further comprising a set of inlets for feeding the reactant into the flow network, and a set of outlets for feeding out at least a portion of the reactant from the flow network. 2. The geosynthetic element according to claim 1 , wherein the geosynthetic element comprises at least one of the following: a membrane, a grid, a drain and a system of expandable tubes. 3. The geosynthetic element according to claim 2 , wherein the membrane is a rollable mat with no holes through the mat. 4. The geosynthetic element according to claim 1 , wherein the bacteria carriers comprise cavities for receiving the calcifying bacteria, and wherein the cavities are connected to the flow network. 5. The geosynthetic element according to claim 4 , wherein the cavities comprise a biodegradable layer, a sieve-like element, a soluble membrane or a combination thereof to allow the calcifying bacteria and the reactant to escape the cavities. 6. The geosynthetic element according to claim 1 , wherein the flow network comprises a set of tubes, the tubes being connected to each other with connecting elements. 7. The geosynthetic element according to claim 6 , wherein the tubes are arranged to receive the calcifying bacteria and the reactant, and wherein the calcifying bacteria and the reactant are arranged to escape the tubes through the openings. 8. The geosynthetic element according to claim 1 , wherein the geosynthetic element comprises a first end plate and a second end plate for connecting expandable fibres to them and for allowing the fibres to longitudinally expand between the first and second end plates when separated from each other. 9. The geosynthetic element according to claim 8 , wherein the flow network comprises expandable tubes between the first and second end plates, the expandable tubes comprising the openings. 10. The geosynthetic element according to claim 8 , wherein the expandable fibres comprise a bacterial resin coating. 11. The geosynthetic element according to claim 1 , wherein the flow network comprises a set of substantially parallel running tubes, and wherein a sleeve is arranged around the set of tubes. 12. A method of inducing microbiologically induced calcium carbonate precipitation in a geomaterial by using a geosynthetic element for carrying bacteria and a reactant in a flow network comprising openings on the surface of the flow network to allow the reactant to escape the flow network to the surrounding geomaterial along the flow network, the flow network further comprising a set of inlets for feeding the reactant into the flow network, and a set of outlets for feeding out at least a portion of the reactant from the flow network, the method comprising: introducing the bacteria to the geosynthetic element in predetermined locations such that the bacteria are arranged to propagate from the geosynthetic element to the surrounding geomaterial; placing the geosynthetic element to an installation location of the geosynthetic element to come in contact with the geomaterial; and feeding the reactant into the flow network through the set of inlets to allow the reactant to be circulated in the flow network and to allow at least a portion of the reactant and the bacteria to be propagated from the geosynthetic element to the geomaterial to produce solid calcium carbonate in the geomaterial. 13. The method according to claim 12 , wherein the method further comprises feeding additional bacteria into the flow network through the set of inlets. 14. The method according to claim 12 , wherein the reactant is fed into the flow network by using batch flows of fixed or varying intervals, or by a continuous reactant flow. 15. The method according to claim 12 , wherein the bacteria are at least one of the following: lyophilised bacterial cells, vegetative bacterial cells, bacterial spores and a bacterial resin coating.