IT202100015710A1 - FERTILIZER FOR AGRICULTURAL LAND AND RELATED FERTILIZING METHOD - Google Patents

Description

TITLE: FERTILIZER FOR AGRICULTURAL LAND AND RELATED FERTILIZING METHOD

DESCRIPTION

Technical Sector of the Invention

The present invention finds its application, in general, in the agricultural sector. In particular, the solution concerns a fertilizer product and a relative method of fertilizing the land, which has considerable advantages from the point of view of sustainability. ecological and environmental.

Known technique

Is gradually, but widely, the awareness, even in high-level decision-making areas, that the activities? human resources, in general, are too often organized and conceived without taking into account their impact on sustainability? ecological: above all, it is being understood that ? necessary to reform many economic and productive processes in order to change the state of affairs and to reverse some current trends.

For this reason, so-called "ecological transition" measures are being launched all over the world, i.e. reforms are proposed with the effect of making structural changes aimed at restoring environmental sustainability. ecological of the pi? various activities human. Consequently, even the agricultural sector (primary productive activity), both for moral reasons, but also for convenience, or to comply with regulations, will be? more and more affected by changes, characterized by greater sustainability? ecological.

The thing? called ?ecological transition? ? considered a necessity today? not anymore deferable. The studies are not counted, even from the most? prestigious academic and scientific circles, which affirm the urgency of drastically modifying the production models that are widespread today, and adopted by the vast majority of companies. In particular, the excessive production of carbon dioxide (CO2) is a fact which urgently needs to be stopped. ? it is precisely this urgency that requires the introduction of controls and legislative measures aimed, in fact, at obliging a growing number of subjects to embark on a path of ?ecological transition? accelerated. And ? precisely the restoration of the balance of CO2 in the atmosphere which represents one of the fundamental challenges (if not the fundamental challenge) on which? it is urgent to propose solutions in all sectors.

Bench? the measures adopted so far are largely insufficient, something? been done to reduce CO2 emissions. In fact, these emissions continue to be too high, in relation to the capacity? of the terrestrial ecosystem to absorb the excess of CO2, and to restore the necessary quantity? of oxygen in molecular form (O<2>), essential for the ecological balance of the earth. This imbalance has the particularly serious effect of affecting the composition of the upper layers of the atmosphere, with disruptive consequences also on climate change.

However, in addition to the measures aimed at limiting emissions, much can and it must also be done in terms of fixing excess carbon dioxide, once this is already in place. in the atmosphere.

The carbon dioxide fixing process takes place in nature mainly due to the action of chlorophyll photosynthesis operated by green plants, or through other photosynthetic reactions operated by other organisms such as algae and microalgae.

Unfortunately, the aforementioned natural carbon dioxide fixing processes are insufficient to offset current CO2 emissions; therefore, procedures are being studied to artificially create ecosystems capable of fixing carbon dioxide. These ecosystems are called ?Carbon-sink? (literally ?carbon sinks?) and, typically, are confined to controlled contexts, so that particular chemical reactions take place, which generate molecules containing carbon, drawing it from CO2 molecules, and releasing oxygen, typically in the air, in the form of molecular oxygen (O<2>), or in water (H2O). These molecules on which carbon is fixed are non-polluting, and therefore such ?Carbon-sink? actually work as pure CO<2> absorbers.

With reference to the known techniques with which to create ecosystems that act as ?Carbon-sink?, it is worth mentioning some types of bacteria that exist in nature and can also be cultivated/farmed: these bacteria, in fact, are microorganisms that have the important property to be carbon dioxide fixers.

These are bacteria which are currently cultivated for study purposes in laboratories, which are simple to cultivate (at relatively low cost), and which up to now have not found application in the agricultural context, as they are not strictly linked to the production of fertilizers or other crop treatment products.

Among these types of bacteria, we mention:

1) The ?Bacillus subtilis?,

2) The ?Bacillus licheniformis?

3) The ?Nitrobacteria?,

4) The ?Lactobacillus plantarum?, e

5) The ?Methylococcus capsulatus?.

From the general point of view of the ecological impact, and from the more? particular of the carbon dioxide balance, the agricultural sector is not? not as virtuous as it could and should be. In fact, although most of the crops fix carbon dioxide during their growth, for example through the processes of photosynthesis, in many other phases of the cultivation processes, agriculture contributes harmfully to the environment.

In particular, the following practices are still widely used, on which ? necessary to intervene.

Many residues of agricultural production, such as foliage, stems of plants that cannot be used otherwise, etc., are often left in the ground so that the so-called chemical decomposition of organic matter is generated. called humus which has fertilizing functions for the soil. However, the natural decomposition processes are activated by bacteria present on the ground which trigger fermentation processes with the production of greenhouse gases (including C02) which are dispersed into the environment.

This phenomenon of gas dispersion in the atmosphere, in addition to the negative impact on the composition of the atmosphere itself, also has a negative effect on the ground. As it contributes to soil erosion, given that these gaseous fumes disperse various elements through the gaseous compounds, making the soil more? dry and permeable.

More land dry are in turn eroded pi? quickly by the wind, and land pi? permeable retain less water in the surface layers, the cio? where the water is needed for the cultivated plants, so that? crops need more irrigation. Even the fertilizers normally used, both natural ones, that is? manure and the like, and both chemical ones, are integrated into the soil on which they are dispersed through fermentation processes, thus giving also give rise to the phenomena briefly outlined above.

Ultimately, can you? affirm that many agricultural processes ranging from the treatment of land for cultivation, to the actual cultivation up to the harvest and the management of production waste, do not have the character of virtuosity? ecological, and indeed present many problems. In fact, even the use of organic farming techniques, although? introduce measures aimed at limiting the use of polluting substances, do not solve the problems related to the effects of fermentation processes which produce greenhouse gas emissions, and which contribute to soil erosion, their impoverishment and the greater need for of water for irrigation.

Finally, the current fertilization techniques do not contribute optimally to the correct recycling of some types of waste and waste: in fact, both crop waste (or vegetable waste in general) and the use of human and animal sewage, they are sometimes used to produce fertilizers, but the forms of recycling currently implemented have strong contraindications as explained above.

Today, a large part of vegetable waste is macerated and destined for incineration while human and animal sewage is destined for the production of fertilizers in bags, or is treated with quicklime to then be distributed on agricultural fields, some are also destined for combustion , others go to landfill, etc. Each of these solutions does not foresee the absorption of polluting greenhouse gases, it does not foresee the recycling of 100% of this type of organic waste and the greenhouse gas producing bacteria are the only ones to proliferate on this sewage.

In fact, human and animal organic waste (i.e. fairly common substances for the production of fertilizers for agricultural purposes) are accumulations of catabolites made up of 75% water and 25% solid substances. 30% of stool weight? made up of bacteria, normally saprophytes, 15% ? represented by inorganic substances, in particular phosphates and calcium which are normally taken in excess, and therefore partly eliminated with the faeces, 5% ? represented by lipid substances and derivatives, the rest ? represented by mucus, desquamation cells and digestive enzymes. Vegetable waste is made up of 85% water, 10% fibers and the remaining 5% proteins and lipids.

Summary of the Invention

The general purpose of the present invention, therefore, is that of indicating a fertilizing product, and a relative fertilization method, which allows for the recycling in a virtuous and optimal way of organic waste such as vegetable waste and human or animal sewage.

In particular, the indicated fertilizer must protect the treated soil from erosion, being able to rebuild it; moreover, in addition to favoring (as all fertilizers do) the formation of essential nutrients for the luxuriant growth of plants, it must favor the maintenance of humidity. in the surface layers of the soil, preventing its progressive drying up due to excessive permeability? which is determined by resorting to cultivation practices currently pi? spread.

But, above all, the fertilizer indicated in the present invention must trigger metabolic processes involving the organic substances present in the soil which do not involve the production and release of greenhouse gases. On the contrary, said metabolic processes must hopefully favor the fixing of carbon dioxide in molecules more? large non-polluting, retained in the soil, with a beneficial effect for cultivation.

The objects of the present invention can be achieved by making a fertilizer composed of a fertilizing base in turn essentially composed of soil with a significant inert component (for example with a strong clay component) mixed with organic waste of human or animal origin, or vegetable; and said fertilizing base? characterized by the fact that it is populated with a culture of carbon dioxide fixing bacteria, of one or more? species, as well as from worms, preferably of the species (very common)? Eisenia fetida?.

The main advantage of the present invention consists in the fact that, how will it be? better explained below, a fertilizer made according to the teachings of the present invention satisfies all the main requirements for which ? been conceived.

It is observed, from the beginning, that since it is a fertilizer obtained by mixing different components, some of which may already be? present in the soil to be fertilized, such as the base of inert soil, the fertilization can? be carried out in various ways: both by spreading a fertilizer already? substantially ready for use, and either by forming it directly in the field and mixing it through the plowing action that is always carried out on the land between one harvest and another. Therefore, the invention lends itself to the definition of real fertilization methods, even different from each other, and which can have various advantages, depending on the case, also from the point of view of simplicity. of the processing required of the farmer.

It is therefore underlined that, in addition to being possible to conceive different variants of fertilizer as such, by modifying the dosages of the individual components, ? otherwise? It is possible to provide for the practical action of fertilizing with different methods depending on the equipment available for cultivation and according to the areas of use: for example vegetable gardens or very extensive crops. ? it is clear that each fertilizer and each method of fertilization having the essential characteristics indicated in the main claim, or in the dependent claims, must be understood as a possible implementing variant of the same invention.

This invention also has further advantages, which will be more evident from the following description, which illustrates further details of the invention itself through some embodiments and from the attached claims, which form an integral part of the present description.

Detailed Description

The present invention, while offering a solution to a well-defined application problem, i.e. the problem of fertilizing agricultural land by significantly improving the virtuosity? ecological compared to the use of known techniques, refers to the field of agricultural technologies and pedology, more? in particular the partial inhibition of the allelopathic effects and the partial fixation in the soil of greenhouse gases deriving from the catabolism of some bacterial strains present in human and/or animal and/or vegetable organic sewage.

The invention proposes the introduction into the soil of a mixed population of fixing microorganisms (mainly bacteria, but also fungi), together with the use of worms. These organisms come into play in a phase of the life cycle of these organic materials typically used in soil fertilization, but they block that part which involves the generation and release of gas into the atmosphere. The use of this method ? undoubtedly the most respectful of the environment since? the oxidative metabolism of the starch, protein and lipid components eliminates the greenhouse gases CO2, CH4 and NO2.

In an embodiment which has experimentally confirmed the effectiveness of the fertilizer according to the invention, all six types of fixing bacteria listed in the first part of the present description have been used. The fertilizer obtained? the fruit of biodigestion, by a mix of bacteria, of organic sewage of human and/or animal and/or vegetable origin. The mix of bacteria used has the following parts by weight: 10 to 20 parts of ?Bacillus subtilis?, 10 to 25 parts of ?Bacillus licheniformis?, 5 to 15 parts of ?Nitrobacteria?, 10 to 20 parts of ?Lactobacillus plantarum?, 10 to 20 parts of ?Thiobacillus denitrificans?, 10 to 20 parts of ?Methilococcus capsulatus?, to which are added 5 to 10 parts of a microbiological preparation formulated with a strain of fungus ?Trichoderma viride?. On the field sprinkled with organic materials, nematode worms must then be distributed. The bacterial mix fixes greenhouse gases to the soil, mainly CO2, CH4 and NO2, moreover, the presence of these bacteria competes with the bacteria normally present in the soil that produce greenhouse gases, and inhibits their growth.

On the ground what? treated, the distributed worms ensure a further fixation of the CO2 in the soil. The organic waste and the mechanical action of the worms form humus on the treated soil thus obtaining a slow release fertilizer.

The function of each fixative bacterium used in the treatment described above is summarized below, as follows: it should be highlighted how the proposed mix not only produces the sum of the effects of each bacterium, but leads to the formation of an organic balance favorable to the agricultural use of the land. In fact, the population of fixing bacteria is so? composed work for a common purpose, their activities? enzymes work in synergy, and humus so? format has the necessary characteristics to support a pluri-cultivation. In fact, the nutritional characteristics are high, and the slightly basic pH makes it a universal soil, as well as to make it possible to cultivate different plant species on the same field without allelopathic reactions of cross-growth inhibition.

The ?Bacillus subtilis? it has an inhibitory action on the growth of bacteria such as: vibri, Escherichia coli and baculoviral. Produces enzymes such as amylase and protease; these enzymes metabolize the starch and proteins present in organic waste, decomposing them completely.

The ?Bacillus licheniformis?, in the present invention, in addition to the amylase has the lipase which metabolizes the lipidic component. The bacterium can also produce molecules with activity? antibiotic against pathogenic bacteria.

The ?Nitrobacteria? metabolize the? ammonia and / or ammonium salts that are oxidized to nitrates, so as to make them so? bioavailable for plant nutrition.

The ?Lactobacillus plantarum?, in the present invention, ? an anaerobic bacterium and pu? do s? that lignin and cellulose decompose easily under normal conditions. The vegetable fibers are rapidly metabolized and decomposed, an organic and nutrient substance for plants is obtained. The ?Lactobacillus plantarum? it also exerts a significant contrasting action on the polluting bacterial reproduction.

The ?Methylococcus capsulatus? ? a methanotrophy that uses the ribulose monophosphate (RuMP) pathway for formaldehyde assimilation. Methane is first oxidized to methanol, which is then converted to formaldehyde. Formaldehyde is further oxidized to formate and carbon dioxide for energy production or assimilated into biomass.

In the end, ? the introduction into the bacterial mix of a fungal culture in the state of mycelium or spores of a strain of ?Trichoderma viride? is also recommended. In the present invention, this fungal component, which normally is used only as an antagonist of other pathogenic fungal species, pu? produce a variety of enzymatic systems such as:culase, chitinase, zitase, etc. Indeed, the ?Trichoderma viride? ? one of the mushrooms active in cellulase production, and the cellulase produced can? degrade vegetable fiber; Furthermore ? also an organism with properties? antimicrobial, and also has an important effect in the biological control of the proliferation of all polluting bacterial species.

Ultimately, the use of this bacterial mix (possibly enriched with other substances, including non-bacterial ones such as spores and fungi) suppresses the quantity? of anaerobic bacteria, or other harmful bacteria, by competing for nutrients and introduces some molecules with an antibiotic effect.

These characteristics make it an excellent fertilizer, however the indicated bacterial mix also has a great environmental value, because it is metabolizes organic matter preventing the development of ammonia, hydrogen sulphide and greenhouse gases and prevents the growth of polluting bacterial species.

The addition of worms to the soil guarantees a further fixation of the CO2 to the soil by burying the fixed substances and a uniform distribution of the treated organic fertiliser.

The technology of the bacterial mix quickly transforms the organic material preventing, in fact, the fermentation, digests the mass of solid matter reaching a rapid reduction of the fertilizer itself while maintaining humidity. In fact, the lack of release of greenhouse gases into the air prevents the depletion of the soil of all those elements that would be dispersed by the same gases; in this way, the ground remains pi? rich in fibers with an absorbent structure able to hold more? long? water cos? to reduce the need for irrigation.

The bacterial decomposition method combined with the use of worms, therefore, is far superior to the usual conventional methods of fertilizing the soil; Indeed:

? presents a greater effectiveness of the treatment of the organic fertilizer, not dispersing some important components;

? does not produce any residue from secondary pollution: not only does it not produce any greenhouse gas emissions, but also provides a system for fixing greenhouse gases to the ground;

? how will it be? better explained also in the following, presents a notable simplicity? of use;

? does not require special equipment;

? recycles 100% organic waste production;

? finally, and of no small importance, ? a low-cost fertilizer.

The preferred worms are of the species ?Eisenia fetida? that feed on decomposing organic matter, the residue of their metabolism? a compound rich in minerals intertwined in organic agglomerates. The use of these worms therefore counteracts, once again, the release of CO2 into the atmosphere as well as bringing all the benefits that worms bring to the soil, such as for example the creation of small channels that favor the aeration of the soil.

The above mentioned advantages are obtained with a mix of bacteria which must be mixed with human and/or animal and/or vegetable organic waste before and/or after distribution on the soil; then worms must also be distributed on the soil and, when all the optimal conditions are verified, a particularly effective humus is formed.

? clear that the preparation of a fertilizer such as that indicated in the present invention can? take place in many ways, even very different from each other.

A first method of preparation involves composing a fertilizing soil already? complete, in which a fertilizing base, in turn composed of organic waste macerated and mixed with mainly inert generic earth, is enriched by populating it with a bacterial mix such as those described above and with some worms. Such a loam? already ready to be spread on the ground to be fertilized, and is it? a form of preparation suitable for small crops such as, for example, vegetable gardens.

Pi? Interesting ? on the other hand, the fertilization method which involves composing the set of fertilizing substances directly in the field. This second form of preparation, and the consequent method of fertilizing a land, is particularly suitable for fertilizing very large cultivated lands.

The first phase takes place when, after a harvest, the soil is prepared for a new sowing, and consists in the spreading of organic waste of vegetable or animal origin on the field to be fertilized.

Note that this first operation can? also take place following the known practice, only that this operation, if not followed by the subsequent phases, presents a series of contraindications previously described, for which not all organic waste is used in this way.

In fact, in the fertilization method according to the invention, the organic waste spreading phase is ? immediately followed by the tilling of the land. Also this ? a typical operation, only that in common practice the plowing does not necessarily have to take place immediately after the spreading of the organic waste and, above all, the plowing of the field is not? an operation closely linked to fertilization. In the method according to the invention, on the other hand, the plowing takes place before the organic waste spread on the field begins the fermentation process, and it? contextual to the pouring of the bacterial mix on the ground.

The bacterial mix can be poured directly together with its culture environment that ? liquid, or can? be spread in freeze-dried form.

The use of the culture medium in liquid form ? conceptually more simple, as nothing else has to be done other than cultivate the bacteria, but it could be more? problematic transport, in the case of large quantities?.

The use of the bacterial mix in freeze-dried form, and certainly more? practical for the logistical aspects (it involves transporting bags containing a powdered substance), but requires the producer of the bacterial mix to cultivate the bacteria and then freeze-dry them and package them in suitable bags.

In the case of spreading the bacterial mix in liquid form, this can be sprayed directly on organic waste, or a tank can? be mounted on the same tractor that maneuvers the plough, so that it releases the right amount of liquid that pulls the plough. The plowing action then mixes the fixing bacteria in the soil, obtaining the desired result.

If the freeze-dried product is used instead, this can be dissolved in water, and then used as the product in liquid form, or can? be spread ?dry? directly on organic waste.

The worms are then distributed later, but this certainly does not represent a problematic operation.

Concluding Remarks

Ultimately, the fertilizing effect results from the use of organic waste mixed with the soil, thus forming a fertilizing base similar to those used at the dawn of agricultural technology. This fertilizing base, however?, instead? be abandoned to a spontaneous maturation (as happened in antiquity, and still today in many cases), is enriched by a population of bacteria so these fixers which guarantee, working in synergy with each other, a virtuous transformation of the organic substances introduced into the soil.

The synergy of these bacteria and worms reduces the release of greenhouse gases into the atmosphere (compared to what would happen in their absence) and furthermore, you get the benefit of reducing the quantities? of sewage intended for the classic ways of disposal since? these can be dispersed directly on agricultural land as organic fertilizers. Therefore, the present invention is not only a solution to make an excellent fertilizer, but can? be used also for other two important functions, which could also be of prevailing importance with respect to the fertilizing function: the fixation of greenhouse gases to the soil and the decrease of the need? disposal of organic waste.

Furthermore, with respect to the prior art, the initial investment to start production (that is, prepare the bacterial cultures) is? small, and the cost of production ? just as low. In the end, you contribute to the protection of the environment, you transform organic waste into wealth, you can profitably cultivate many plant species on the same field, and you also save money.

All this, in addition to the fact that erosion of the soil is prevented (indeed a reconstruction of the same is carried out) and crops and multi-cultures can be managed with significant water savings (also counteracting the desertification phenomena triggered by certain intensive crops ).

The prior art does not offer solutions like this? advantageous, why? has always aimed to solve problems separately. So the problem of CO<2 > emissions is not ? been addressed in relation to the problem of fertilizing the land; and also the problem of disposing of organic waste, although historically linked to the issue of humus production (whose fertilizing properties have been known for some time)? often been addressed in a s? standing; for example by treating this waste with a view to subsequent incineration or landfill storage, or by stabilizing this waste by mixing it with quicklime to limit fumes due to fermentation.

The present invention, on the other hand, proposes an ecosystemic vision that allows to find an optimal solution for a plurality of of apparently distinct problems, and does not disdain to modify the ecosystem on which it operates in a rather invasive way. In fact, it makes use of? Intuition to exploit the properties? of some organisms, called fixer bacteria which, although present in nature, do not inhabit the land, which is instead populated by other bacteria with polluting effects: after all, the agricultural use of the land? a forced (not spontaneous) use of them.

Therefore, the action of introducing these new organisms in land for agricultural use appears as a measure to be undertaken when one intends to exploit a land in a way that does not reflect its spontaneity. A ?cultivated field? for agricultural exploitation? to all intents and purposes an artificial ecosystem, and as such it must find a new balance, not disdaining other artificial interventions, such as the introduction of other forms of life.

The introduction of these new forms of life, given by the fixing bacteria, seems to reintroduce a virtuous balance in the distortions caused by agricultural crops, at the same time offering answers to a multitude of other imbalances always caused by agricultural activities. human (abnormal production of waste and imbalance in greenhouse gas emissions).

Given its ecosystemic value, this invention, in all likelihood, will reveal the formation of new ecological balances in the environment constituted by the ?cultivated field?, and will be? therefore subject to inevitable refinements and adjustments. For which the bacterial mix could be enriched with new species, or the dosages could be a function of the different soils to be treated, so to achieve ever better results.

In general, therefore, the present invention lends itself to numerous variations while maintaining the claimed prerogatives and, in fact, allows to conceive a new vision of the artificial environment given by a "cultivated field": vision preparatory to researching new forms of ecosystems in virtuous balance, through the introduction of new organisms, in order to achieve a plurality? of results.

Some variants may concern the fertilization methods, for example through a progressive automation of the operations, or through a refinement of the mixing and dosing techniques, possibly as a function of data measured by appropriate sensors, so fertilization to be regulated more and more effectively.

Therefore, above all in the context of evolutionary scenarios, the invention seems to lend itself to incorporating and supporting further development and improvement efforts, capable of improving the performance of the described product. Many further developments can therefore be made by a man skilled in the art without thereby departing from the scope of the invention as it results from the present description and from the claims attached hereto, which form an integral part of the present description; or, if said developments are not included in the present description, they may be the subject of further patent applications associated with the present invention, or dependent on it.

Claims (9)

TITLE: FERTILIZER FOR AGRICULTURAL LAND AND RELATED FERTILIZING METHOD CLAIMS 1. A fertilizer composed of a fertilizing base in turn essentially composed of soil with a significant inert component mixed with organic waste of human, or animal, or vegetable origin; and said fertilizing base? characterized by being populated with a culture of carbon dioxide fixing bacteria of one or more? species, as well as from worms. 2. Fertilizer according to claim 1 wherein at least some of said worms belong to the species ?Eisenia fetida?. 3. Fertilizer according to claim 1 wherein said inert component comprises a significant quantity of clay. 4. A fertilizer according to claim 1 wherein said culture of carbon dioxide fixing bacteria comprises a population of bacterium ?Bacillus subtilis?, or of bacterium ?Bacillus licheniformis?, or of ?Nitrobacteria?, or of bacterium ?Lactobacillus plantarum?, or of bacterium ?Methylococcus capsulatus?, or any combination of these bacteria. 5. A fertilizer according to claim 4 wherein said culture of fixative bacteria is also mixed with a microbiological preparation formulated with a strain of fungus ?Trichoderma viride?. 6. Fertilizer according to claim 5, wherein said culture of fixing bacteria comprises a mix of bacteria and fungi with proportions by weight included in the following limits: from 10 to 20 parts of ?Bacillus subtilis?, from 10 to 25 parts of ?Bacillus licheniformis?, 5 to 15 parts of ?Nitrobacteria?, 10 to 20 parts of ?Lactobacillus plantarum?, 10 to 20 parts of ?Thiobacillus denitrificans?, 10 to 20 parts of ?Methilococcus capsulatus?, and 5 to 10 parts of ?Trichoderma viride?. 7. Fertilization method which provides for the spreading in a land to be fertilized of waste composed of human, animal, or vegetable organic matter, in which said step of spreading organic waste ? immediately followed, before significant fermentation processes of said organic matter begin, by at least two operations performed substantially simultaneously: the. plowing the land e ii. spreading said culture of carbon dioxide fixing bacteria according to claim 4 or claim 5. 8. Fertilizing method according to claim 7, wherein, after said soil plowing operation, said worms are spread. The fertilization method according to claim 7, wherein said culture of fixative bacteria according to claim 4 or claim 5 is spread in the soil in liquid form.