BE1029039A1 - Method for reducing ammonia emissions - Google Patents

Abstract

The present invention relates to a method for reducing ammonia emissions when fertilizing agricultural land, comprising the steps of: a. creating a fertilizer strip on the agricultural land, b. distributing a fertilizer on the fertilization strip, and c. applying a liquid over the fertilizer and/or the fertilizer strip, characterized in that the fertilizer and/or the liquid comprises a lime product, which lime product comprises a limestone in a concentration comprised between 20.0 and 100.0 m%.

Description

METHOD FOR REDUCING AMMONIA EMISSION

TECHNICAL FIELD The invention relates to a method for reducing ammonia emission. More particularly, the invention is located in the technical field of reducing ammonia emissions during the fertilization of agricultural soils.

BACKGROUND ART For some time now, the pressure on agricultural land in developed areas has been increasing strongly. The demand for agricultural products continues to rise, while the available agricultural area is constantly decreasing. An important reason for this is the ongoing i5 population growth. Thus, the aim in the agricultural sector is to optimize the efficiency and yield of an agricultural land as much as possible, in order to continue to meet this increasing demand. However, intense agricultural activity, especially the cultivation of domesticated plants, necessitates the use of fertilizers which have some negative effects. A major disadvantage of fertilization is the so-called ammonia emission. The agricultural and horticultural sector is responsible for about 95% of the total "ammonia emission" in Flanders, with a large part of the ammonia emission being due to the use of fertilizers and to the processing of livestock. manure, In high concentrations ammonia emission can be harmful to humans, animals and the environment. For example, ammonia contributes to the acidification of the environment, ammonia can precipitate on the land, and harmful effects can arise when inhaling large and high concentrations of ammonia. In addition, ammonia has a depleting effect on biodiversity, harming plants with a preference for poor soils and being overgrown by nitrogen-loving plants. adverse effects for humans, animals and the environment can be reduced, and agricultural yields are not adversely affected.

© BE2021/5040 The present invention aims to solve at least some of the above-mentioned problems or drawbacks.

SUMMARY OF THE INVENTION To this end, the present invention provides in a first aspect a method according to claim 1, comprising the steps of (a) creating a fertilizer strip on the farmland, (b) distributing a fertilizer on the fertilizer strip, and ( c) applying a liquid over the fertilizer and/or the fertilizer strip, wherein the fertilizer and/or the liquid comprises a lime product, which lime product comprises a limestone in a concentration comprised between 20.0 and 100.0 m%. Due to the exceptional microstructure of the lime product, and in combination with this specific application method, a considerable reduction of the ammonia emission during fertilization is obtained. Preferred forms of the method are given in claims 2 to 16.

FIGURES FIG. 1 shows the particle size distribution of a cococolitic chalk suspension according to an embodiment of the present invention, FIG. 2 shows the results of a lab test comparing ammonia emissions between different emission reduction treatments according to the present invention, 8 hours after their application and at 15 m 3 fertilizer per hectare. fig. 3 shows the results of a lab test comparing the ammonia emission between different emission reduction treatments according to the present invention, 8 days after their application and at 15 m 3 fertilizer per hectare. fig. 4 shows the results of a lab test comparing ammonia emissions between different emission reduction treatments according to the present invention, 8 hours after their application and at 30 m 3 fertilizer per hectare.

fig. 5 shows the results of a lab test comparing ammonia emissions between different emission reduction treatments according to the present invention, 8 days after their application and at 30 m 3 fertilizer per hectare.

DETAILED DESCRIPTION The present invention relates to a method for reducing ammonia emissions in the fertilization of an agricultural soil.

Unless otherwise defined, all terms used in the description of the invention, including technical and scientific terms, have the meaning as generally understood by those skilled in the art of the invention. For a better assessment of the description of the invention, the following terms are explicitly explained.

“A”, “the” and “the” in this document refer to both the singular and the plural unless the context clearly dictates otherwise. For example, “a segment” means one or more than one segment, The terms “comprise”, “comprising”, “consist of”, “comprising”, “contain”, “contain”, “contain”, , “including” are synonyms and are inclusive or open terms designating the presence of the following, and which do not exclude or preclude the presence of other components, features, elements, members, steps known from or described in the prior art, Citing numerical intervals through the endpoints includes all integers, fractions and/or real numbers between the endpoints, including these endpoints.

A first aspect of the present invention relates to a method for reducing the ammonia emission in the fertilization of an agricultural land, comprising the steps of: a. creating a fertilizer strip on the agricultural land, b. distributing a fertilizer on the fertilization strip, and c. applying a liquid over the fertilizer and/or the berthing strip,

wherein the fertilizer and/or the liquid comprises a lime product, which lime product comprises a limestone in a concentration comprised between 20.0 and 100.0 m%.

The term "lime product" refers to a product comprising a limestone. Limestone is a sedimentary rock formed by the accumulation of material remains of marine organisms. As a result, a lime product includes calcium carbonate (CaCO3)} and is regularly found fossils in back. The term "calcium carbonate (CaCO3)" denotes a chemical compound that occurs regularly in nature as the mineral calcite. The sedimentary rock limestone and its metamorphic form, marble, are largely composed of calcite. With the term " ammonia emission” refers to the release of ammonia into the environment, in particular as a result of fertilization of agricultural land.

Suitable methods for determining the ammonia emission of a fertilizer are known from the current state of the art, e.g. ammonia emission in wind tunnel research or micrometric reference methods using passive flux samplers, the emission expressed in mg ammonia (NHz) emitted within a specified period of time .

The term "fertilizer" in the light of the present invention is to be considered as any fertilizer from the non-limiting group of animal manures and mineral fertilizers, including ammonium nitrate, ammonium sulphate, urea, liquid nitrogen, moncammonium phosphate, and diammonium phosphate. By extension, mineral fertilizers may also include waste streams from, for example, bio-fermentation plants and air scrubbers, as used in livestock and/or pig stables. In the light of the present invention, the term "fertilizer strip" is to be understood as a soil strip on which a fertilizer can be distributed, and wherein the fertilizer has good contact with the agricultural soil. In particular, a fertilizer strip is such a free and/or cleared soil strip which is situated substantially between the individual plants of a crop.

In the light of the present invention, a "vice agent" belongs to the non-limiting group of water, alcohols, process and/or waste water, possibly contaminated

° BE2021/5040 with nitrogen, phosphates, potassium, ammonium sulphate, or other pollutants. Preferably, the "liquid" comprises at least water.

The lime product as used in the method according to the present invention is able to adsorb part of the ammonia in the fertilizer by means of physisorption based on Van der Waals forces. This reduces the ammonia emission by at least 20%, e.g. compared to turf fertilization. However, the reduced ammonia emission means an increased nitrogen availability for the soil and thus a saving of up to 45 kg nitrogen per hectare. The drawbacks described herein with respect to humans, animals and the environment are moreover considerably reduced by means of the emission reduction obtained. A further advantage is that the system is easily controllable and can be secured. Manure to which lime product has been applied has a much lighter colour, which is still visible after a few days. Furthermore, if the lime product is mainly used after the first cut, a quantity of lime is supplied which compensates for the natural acidification plus the acidification by fertilizers, thus maintaining the soil pH. In addition to the reduction of ammonia emission, the lime product also allows to reduce the release of odor during fertilization. Preferably, the lime product is a chalk product, which chalk product comprises calcium carbonate (CaCO3) in a concentration comprised between 75.0 and 100.0 m%, and wherein the chalk product has a particle size d50 comprised between 0.5 and 20.0 µm.

For the purposes of the present invention, “particle size” is expressed as a “d-value” which indicates the percentage by volume of particles within a particular size range. indicates that 50 v% of the particles in the given distribution have a particle size within this size range. A suitable method for determining particle size is "laser diffraction". A typical laser diffraction particle size determination system includes an optical test bench in which a dispersed sample is exposed to a laser beam, and an array of detectors that accurately measure the intensity of the laser beam scattered by the particles in the sample over a wide range of angles. measure.

Such a system further includes a sample dispersion unit which delivers the particles in a suitable concentration and in a suitable stable state of dispersion to the measurement area of the optical bench. The system is controlled by software

© BE2021/5040 which analyzes the scattering data during the measurement process and then calculates a distribution size distribution. Such a system is commercially available under the name Mastersizer.

In particular, the chalk product described herein has a "coccolitic origin", indicating that chalk is derived from "coccolites", microscopic plates of calcite (CaCO3), derived from the exoskeleton of unicellular marine algae. Chalk of cococolitic origin is thus a fossilized phytoplankton. Due to its exceptional microstructure, chalk of cococolitic origin has a very strong biological activity and a high reactivity, and chalk of cococolitic origin can be distributed very finely and/or accurately over a substrate eg an agricultural soil. The chalk product of the present invention preferably comprises chalk deposited during the Campinian and/or Maastrichtian. The term "deposit" denotes sedimentation, and is a collective term for processes in which particles settle or minerals precipitate from water or another solution. Sedimentary rocks form on or just below the Earth's surface and usually consist of layers that have been deposited on top of each other. The terms "Campinian" and "Maastrichtian" refer herein to the geological period in which the chalk was deposited. The Maastrichtian is the last time cut in the Late Cretaceous and comes after the Campinian. The deposit as described herein dates between 66 and 84 million Year ago.

According to a further or different embodiment, the chalk product has a particle size d50 comprised between 0.5 and 10.0 µm. More preferably, the particle size d50 is comprised between 0.5 and 5.0 µm. The smaller particle size, and in particular the narrower particle size distribution, has the advantage of maximizing the biological activity and reactivity of the chalk, allowing optimum adsorption of ammonia. A smaller particle size, and in particular a narrower particle size distribution, in particular increases the contact surface of the chalk particles and also allows a finer and/or accurate distribution of the chalk product over the fertilizer and/or fertilizer strip, which contributes to a increased efficiency of ammonia emission reduction.

According to a further or different embodiment, the chalk product has a maximum particle size d90 of 200.0 µm. Preferably the maximum particle size d90 of the chalk is 150.0 µm, more preferably 120.0 µm, even more preferably

110.0 µm, even more preferably 100.0 µm, 90.0 µm, 80.0 µm, 70.0 µm, 60.0 µm, 50.0 µm or 40.0 µm, most preferably 30.0 um. The chalk product, in some embodiments, has a pH comprised between 70 and 9.0. This pH value makes the chalk product extremely suitable for use in agriculture, as the optimum pH value of agricultural soils, although generally dependent on the type of agricultural soil, is usually comprised between pH 5.0 and 7.0. Thus, the present method not only makes it possible to considerably reduce the ammonia emission, but also compensates for a reduction in the soil pH as a result of fertilization. Thus, the present method succeeds in reducing ammonia emissions, while supporting agricultural activity, in particular the cultivation of domestic plants.

According to a further or different embodiment, the chalk product is a chalk slurry, which chalk slurry has a dry matter content comprised between 40.0 and 80.0 (mm/m). The term "suspension" refers to a mixture of two substances of which a first substance is mixed in minute particles with a second substance, the first and second substances generally being a solid and a liquid, respectively. When the particles in the mixture are smaller than 100.0 µm, the mixture is generally referred to as a colloidal suspension. the total mass of the mixture. An important advantage of the slurry is that no strong sediment is formed when it is deposited. In comparison, another limestone, eg finely ground dolomite, is much more difficult to suspend than the chalk.

In addition, the precipitation process of cococolitic chalk in a suspension proceeds much more slowly. Incidentally, the precipitated particles can be easily resuspended. The chalk suspension allows a particularly efficient distribution of the chalk over the fertilizer and/or the fertilization strip, and has a particularly large reactive surface area per volume, resulting in a high absorption of ammonia.

Preferably, the dry matter content of the chalk suspension is comprised between 45.0 and 75.0 m%. According to some embodiments, the dry matter content is comprised between 50.0 and 70.0 m%, more preferably between 55.0 and 65.0 m%, even more preferably between 50.0 and 60.0 m%.

According to some embodiments, the liquid in step c comprises the chalk product, which liquid is obtained by mixing the chalk slurry and water in a volumetric mixing ratio comprised between 1:1 and 1:2, distributing the chalk product through the liquid in step c , and in the mixing ratio as described herein, is sufficient in an optimal dosage and distribution of the chalk product over the fertilizer and/or the fertilization strip and leads to an optimal reduction of the ammonia emission. The method has the further advantage that it is carried out in one working pass, which has a cost-reducing effect and causes less compaction of the soil. In some embodiments, the liquid in step c is such a chalk slurry with a dry matter content comprised between 12.5 and 40.0 m%, more preferably between 15.0 and 30.0 m4 . In some embodiments, the fertilizer comprises in step b the chalk product. The liquid here mainly comprises water, whereby the chalk product has been premixed in the fertilizer. the lime product, in particular the chalk product, in some embodiments is used to reduce ammonia emission and odor release from manure in a manure pit. Undermixing of the lime product, in particular the chalk product, in the manure leads to a reduction in foam formation, which prevents manure from foaming up from the manure pit to, for instance, in the stables.

According to a further or different embodiment, the chalk product is dosed onto the agricultural land in steps b and/or c in an amount comprised between 0.25 and 1.00 m 3 chalk product per hectare of agricultural land. In this dosage optimum fertilization is safeguarded while the ammonia emission associated with fertilization is optimally reduced.

In some embodiments, the chalk product is dosed onto the agricultural land in steps b and/or c according to a neutralizing value comprised between 100 and 300 kg CaO/ha agricultural land.

The “neutralizing value” is a laboratory value that represents the theoretical acid neutralizing capacity. Since this value is determined in a very strongly acidic environment, it is often far from a reflection of the ultimate effect on the pH in the soil. After all, the grain size and the speed at which the pH increase takes place also strongly determine the result. The term "reactivity" is therefore used to indicate the speed and effectiveness of the acid neutralizing capacity, and is significantly more relevant for agronomy applications described herein (cf. Regulation (EU) No. 2019/1009). Determination of reactivity is also known in the art and is expressed as a relative percentage to a chosen standard. The reactivity can be determined in hydrochloric acid (pH 2.0} or citric acid {pH 4.1}. The measurement with citric acid is more relevant as the pH is more in line with agricultural reality. The present chalk product has a reactivity of 130% compared to of a standard lime fertilizer with a grain size of maximum 160.0 µm and a calculated MgO content of approximately 0%.

According to some embodiments, the neutralizing value (NW) of the chalk product, in particular the chalk suspension, is comprised between 20 and 30 kg CaO/100 kg, more preferably between 22 and 28 kg CaO/100 kg, still more preferably between 24 and 26 kg CaO0/100 kg. Most preferably, the neutralizing value (NW) of the chalk product is about 25 kg CaO/100 kg.

According to a further or different embodiment, the liquid is distributed over the fertilizer and/or the fertilizer strip in step c by means of spraying, spraying and/or misting. By spraying, spraying and/or misting, there is a homogeneous distribution of the liquid over the fertilizer and /or the fertilizer strip, providing optimum surface coverage, and exceptionally efficient capture of emissive ammonia. The chalk slurry in some embodiments includes a stabilizer selected from the group consisting of clay particles, xanthan gum, acrylates, polyacrylates, or combinations thereof.

Preferably, the stabilizer has a concentration in the chalk suspension comprised between 0.1 and 1.5 g/L. More preferably, the stabilizer has a concentration in the chalk suspension comprised between 0.2 and 1.29/L, even more preferably between 0.5 and 1.0 g/L.

According to a further or different embodiment, the chalk suspension comprises an emission-reducing additive selected from the group of light acids, gypsum, activated carbon, starch, blowdown water, or combinations thereof.

In particular, sulfuric acid (H2SO4) or salts thereof have subsequent beneficial effect. When H2504 or its salts are added to the crystal suspension, the formation of CaSOa4 (gypsum) occurs (with CO: and H:0) as by-products. The use of sulfuric acid and its salts is particularly advantageous as sulfates (504) are an exceptionally absorbable form of sulfur. Depending on the amount of H2504 administered, the composition and effect of the chalk product is also changed. CaSO4 is in fact a substance that has much less or no effect on the pH of the soil, but is a valuable source of the plant nutrient calcium and has an emission-reducing effect. is already sufficiently high, but the concentration of calcium still needs to be increased. Calcium further contributes to the growth of stronger plants with better resistance to 0.3. fungal diseases.

Preferably, the emission-reducing additive has a concentration in the chalk suspension comprised between 0.1 and 5.0 g/L. More preferably, the emission-reducing additive has a concentration in the chalk suspension comprised between 0.2 and 2.5 g/L, still more preferably between 0.5 and 1.0 g/L.

According to a further or different embodiment, the creation of the fertilizer strip in step a and/or the distribution of the fertilizer on the fertilizer strip in step b is performed by means of a coulter fertilizer.

The term "coulter slurry injector" or "slot coulter injector" denotes a drag feel in which the elements press on the soil with at least 5 kg, with the aim of getting the manure on the soil between the grass instead of on the grass, so the coulter injector is able to create the so-called fertilization strip. The advantage of this method compared to sod fertilization is that the manure is not

K BE2021/5040 injected into the sod but placed in between. As a result, the turf remains intact and the bearing capacity is retained, which is a great advantage on clay and peat soils. The machine also requires less pulling power than the sod injector.

Preferably the coulter fertilizer comprises a spraying device suitable for spraying, spraying and/or atomizing the liquid over the fertilizer and/or the fertilizer strip in step c.

In some embodiments, however, the lime product, in particular the chalk product, can be distributed over agricultural land by means of a classical deflector plate, which ensures a homogeneous distribution of the lime product over the agricultural land.

The chalk product in some embodiments comprises an inorganic additive selected from the group of calcium oxide {CaO}, calcium hydroxide {(Ca(OH}2}, sodium hydroxide (NaOH), nitrogen (N}, phosphorus (P), magnesium (Mg), manganese) (Mn), boron {B}, silicon (SD, zinc {Zn}, aluminum (AD, copper (Cu), molybdenum (Mo), sulfur {5}), derivatives or combinations thereof.

The inorganic compounds mentioned herein are usually only difficult to distribute homogeneously over an agricultural soil, for which the present chalk product forms an exceptionally good carrier. Due to the inorganic additive in the chalk product, the chalk product is particularly suitable for agricultural use and may support and/or promote crop growth. The chalk product can possibly be used as a supplement to existing fertilization. A special advantage is linked to the supply of amorphous silicon, which makes plants more resistant to drought, among other things. In some embodiments, the inorganic additive is sulfur or a compound derived therefrom. Since a deficiency of sulfur can decrease the yield of a crop by about 10 to 20%, sulfur is an extremely important element for agriculture. Addition of sulfur to the chalk product also stimulates the nitrogen uptake, and thus contributes to the leaf growth of the crop and to the formation of high-quality proteins,

In addition to the emission-reducing effect, some embodiments of the present invention also have the advantage that less odor is released during fertilization, both when the chalk suspension is used in step b and in step c. Further advantages of the present invention include an improvement in nitrification, Le. the conversion of ammonium to nitrite and nitrate. The method according to the present invention has a buffering action, which favorably influences the conditions for the growth and action of nitrifying bacteria.

Application of the method as described herein has the advantage that the pH of the soil is improved. In particular, the method leads to improving and/or maintaining the pH of an agricultural soil. The result is also very durable, whereby the frequency of re-liming can be reduced compared to commonly used lime products. In what follows, the invention is described by reference to: non-limiting examples illustrating the invention, and which are not intended or should be construed to limit the scope of the invention.

EXAMPLES Example 1: Chalk Slurry The chalk slurry described herein comprises about 49.0m% chalk. The particle size distribution of the chalk in the chalk suspension was determined by laser diffraction (Mastersizer 2000). Hereby, the particle size of the chalk powder was calculated to be d50 = 3.231 µm and d90 = 16.428 µm. The particle size distribution of the chalk in the chalk suspension is shown in Fig. 1. The chalk suspension has a dry matter content of 50 (m/m)%. Due to the fine microstructure of the chalk, the chalk suspension has a very strong biological activity and a high reactivity, and can be used for the efficient reduction of ammonia emissions during fertilization. The suspension has the further advantage that it can be distributed very finely and/or accurately over a substrate by means of atomization. The contact surface of the chalk particles with the treated substrate is exceptionally large. The chalk particles within the above particle size distribution show a very slow sedimentation and, moreover, do not form persistent sediment,

Example 2: reduction of ammonia emissions during fertilization (laboratory test)

The reducing effect on the ammonia emission when fertilizing according to the present method is illustrated by means of a laboratory test, the method comprising the steps: a. creating a fertilization strip on the agricultural land, b. distributing a fertilizer on the fertilizer strip, and c. applying a liquid over the fertilizer and/or the fertilizer strip, wherein the fertilizer and/or the liquid comprise a chalk product, which chalk product comprises a limestone in a concentration between 25.0 and 100.0 m%, which limestone comprises calcium carbonate (CaCO3) in a concentration comprised between 75.0 and 100.0 m%, and wherein the limestone has a particle size d50 comprised between 0.5 and 20.0 µm.

Closed diffusion chambers were used in the laboratory test.

These consist of a saucer of 20 cm in diameter and are 3 cm high filled with loose, field-moist clay soil.

A trench was pressed into the field moist clay soil (step a) by means of a wooden disc, the same size as the saucer and on which a parallel triangle of 20 cm long, 3 cm wide and 1.9 cm deep was mounted.

This method described herein approximates the practice of the trailing foot or coulter slurry injector.

A well-mixed thin cattle slurry was distributed in the resulting trench.

The experimental setup includes 2 different fertilization levels (step Db}: - 15 m3 fertilizer per hectare, and - 30 m3 fertilizer per hectare.

The mixture of chalk suspension and water was manually pipetted over the manure in 7 mixing ratios {slack c}: - 0.00 m3 water per hectare (reference), - 1.40 m° water per hectare, - 0.70 m3 chalk suspension per hectare ,

- 0.35 m° chalk suspension per hectare mixed with respectively 1.05 m3 and 0.70 m3 water per hectare, and - 0.70 m3 chalk suspension per hectare mixed with respectively 0.70 m3 and 0.35 m3 water per hectare.

The mixing ratios of chalk suspension and manure were made by weighing. Application of water to the manure surface was done with a plant sprayer. The tests were carried out at room temperature.

Alternatively, the chalk suspension was mixed under the manure (step b} and only water was pipetted (step c). The following doses of chalk suspension were used: - 0.35 m° chalk suspension per hectare, and - 0.70 m° chalk suspension per hectare. In both cases, 1.40 m3 per hectare of water per hectare was used An overview of the different dosages is shown in Table 1. Table 1. Overview of chalk dosage Treatment Chalk suspension Water Total Application of chalk (m3/ha} (m3/ha} (m3 / ha} ee " 2 0.35 0.70 1.05 step c (water) 3 0.35 1.05 1.40 step c (water) 4 0.70 0.70 step c (water) 5 0, 70 0.35 1.05 step c (water) 6 0.70 0.70 1.40 step c (water) 7 0.00 8 0.35 1.05 1.40 step b (fertilizer) 9 0.35 1,05 1,40 step b (fertilizer) Determination of the ammonia emission was done as follows: an acid zinc was placed over the manure sieuf. This consists of a U-shaped frame of 4 cm high. A Petri dish with a diameter of 9 cm was placed on this frame and filled with 20 mL 0.05 M HC About the g A bucket 24 cm in diameter and 20 cm high was placed throughout to close the saucer. Ammonia that emits is transported by diffusion to the HCl solution, in which the ammonia dissolves. At time points 8, 24, 48, 96 and 168 hours after the start of the experiment, the acid solution was transferred to a sealable plastic test tube and 20 mL of HCl was pipetted into the petri dish each time. At the end of the experiment, the ammonium concentrations were measured using a Discrete Analyzer.

The various treatments were carried out in triplicate. The chalk suspension used is a suspension of very fine chalk particles (< 5.0 µm) with a neutralizing value (NW) of 25 kg CaO/100 kg. The specific gravity of the chalk suspension is 1.45 kg/L. The chalk suspension has a dry matter content of 50 (mM/m) %-. The results are shown in Figures 2-5 and concern the ammonia emissions measured at 15 m3 and at 30 m5 fertilizer per hectare, respectively, after 8 hours and 8 days. Results for three different measurement periods are displayed, The results show up to 35% ammonia emission reduction is achieved. In general, treatments 2, 3, 5, 6, 8 and 9 bring about a significant emission reduction compared to reference 7. At 30 m° per hectare, the emission reductions are approximately 10% with small differences between the treatments. Example 3: reduction of ammonia emission during fertilization (field trial) The reducing effect on ammonia emission during fertilization according to the present method is illustrated by means of a field trial, the method comprising the steps: a. creating a fertilizer strip on the agricultural land, b. distributing a fertilizer on the fertilizer strip, and c. applying a liquid over the fertilizer and/or the fertilizer strip, wherein the fertilizer and/or the liquid comprise a chalk product, which chalk product comprises a limestone in a concentration between 25.0 and 100.0 mc, which limestone comprises calcium carbonate {(CaCO3)} in a concentration comprised between 75.0 and 100.0 m%, and wherein the limestone has a particle size d50 comprised between 0.5 and 20.0 µm. Test fields with a diameter of approximately 25 meters were used for the current field trial. The following preconditions applied: - the ground had recently been mowed,

- the soil temperature was not higher than 25°C, - the precipitation forecast was less than 3 mm within two days after the intended date of fertilizer application, - the trial fields were at least 50 meters apart, - the fields were free of wooded banks or the like height obstacles are at a distance of at least 10 times the height of the obstacles, - the fertilizer applied was recently mixed. The following theoretical treatments were compared in the field trial: - Sod slurry injector (ZB, reference), - Coulter slurry injector (KB 1) using chalk suspension in step c, with mixing ratio chalk suspension to water 1:2, Le. 0.35 m3 chalk suspension per 0.70 m° water per hectare; - coulter fertilizer (KB 2) using chalk suspension in step c, with mixing ratio chalk suspension to water 1:1, Le. 0.70 m° chalk suspension and 0.70 m3 water per hectare; coulter fertilizer (KB 3) using equivalent amounts of chalk suspension in step b and application of water in step c.

In this field trial, the effect of the application of a chalk suspension on the reduction of ammonia emissions was tested with the full-field micro-meteorological method "ZINST", where the ammonia concentration and wind speed are measured at a characteristic height above the field. passive diffusion samplers were used. From the measurement data, the ammonia emission was calculated based on a calculation model. Three measurement rounds were carried out; in August 2019 and in May and June 2020, The 3 field measurements show that the application of diluted chalk suspension in 5 of the 7 measurements give a significantly lower NHZ emission than sod fertilization, One measurement shows an equivalent result to that of sod fertilization and one measurement gives a higher value, Averaged over the 7 measurements, the emission reduction was 28% compared to the reference sod fertilization. respectively 22.8 (coulter fertilization) and 21.6 m3 (sod fertilization} per ha. 1.9 m° diluted chalk suspension was applied per ha, corresponding to 275 NW per ha. No significant pH increase was measured on the peat grassland. The results further show that the emission-reducing effect is greater the more chalk suspension is applied. Based on the results over 3 measurement rounds, it is generally concluded that 20 m? manure in combination with the fertilization method according to the present method, with a diluted chalk suspension, gives an emission reduction compared to sod fertilization. The results are summarized in Table 2.

Table 2. Ammonia emission during different treatments, and overview of applied amounts of manure and chalk suspension (3 field trials) Nr. Manure Gift Manure Gift Sprayable. NW kg NHs NH 0% (m3/ha} NH:-N (m3/ha) Ca0/ha emission emission compared to {kg/ha) {kg/ha} (%)} zB 1 ZB 220 441 698 187 1 KB 17 .5 35.0 1.85 447 3.01 8.6 48 1 KB2 17.5 35.0 2.01 364 2.65 7.6 55 1 KB3 17.5 35.0 0.20 73 6.16 17.6 112 2 ZB 19.8 43.7 17.50 40.1 2 KB1 17.7 38.8 1.83 221 12.91 33.3 83 2 KB2 28.1 64.5 1.82 330 10 .62 16.5 41 2 KB3 24.6 44.2 0.85 307 25.46 57.6 144 3 ZB 27.1 56.9 2.15 160 14.56 25.6 72 3 KB1 28.2 62 .0 1.97 198 10.59 17.2 84 3 KB2 23.0 48.3 15.76 32.6

Claims (16)

CONCLUSIONS A method for reducing ammonia emissions when fertilizing an agricultural land, comprising the steps of: a. creating a fertilizer strip on the agricultural land, b. distributing a fertilizer on the fertilization strip, and c. applying a liquid over the fertilizer and/or the fertilizer strip, characterized in that the fertilizer and/or the liquid comprises a lime product, which calyx product comprises a limestone in a concentration comprised between 20.0 and 100.0 m%. The method according to claim 1, characterized in that the lime product is a chalk product, which chalk product comprises calcium carbonate (CaCO:) in a concentration comprised between 75.0 and 100.0 m%, and wherein the chalk product has a particle size d50 comprised between 0.5 and 20.0 µm. The method according to claim 2, characterized in that the chalk product has a particle size d50 comprised between 0.5 and 10.0 µm. The method according to claim 2 or 3, characterized in that the scribing product has a pH comprised between 7.0 and 9.0. The method according to any one of the preceding claims 2-4, characterized in that the chalk product is a chalk suspension, which chalk suspension has a dry matter content comprised between 40.0 and 80.0 (m/m)}%. The method according to any one of the preceding claims 2-5, characterized in that the liquid in step c comprises the chalk product, which liquid is obtained by mixing the chalk suspension and water in a volumetric mixing ratio comprised between 1:1 and 1. :2. The method according to any one of the preceding claims 2-6, characterized in that the fertilizer in step b comprises the chalk product. The method according to any one of the preceding claims 2-7, characterized in that the chalk product is dosed onto the agricultural land in steps b and/or c in an amount comprised between 0.25 and 1.00 m3 of chalk product per hectare of agricultural land . The method according to any one of the preceding claims 2-8, characterized in that the chalk product is dosed onto the agricultural land in steps b and/or c according to a neutralizing value comprised between 100 and 300 kg CaO per hectare of agricultural land. The method according to any one of the preceding claims 2-9, characterized in that the liquid is distributed over the fertilizer and/or the fertilizer strip in step c by means of spraying, spraying and/or misting. il. The method according to any one of the preceding claims 5-10, characterized in that the chalk suspension comprises a stabilizer selected from the group of clay particles, xanthan gum, acrylates, polyacrylates, or combinations thereof. The method according to claim 11, characterized in that the stabilizer has a concentration in the chalk suspension comprised between 0.1 and 1.5 g/L. The method according to any one of the preceding claims 5-12, characterized in that the chalk suspension comprises an emission-reducing additive selected from the group of light acids, gypsum, activated carbon, starch, blowdown water, or combinations thereof. The method according to claim 13, characterized in that the emission-reducing additive has a concentration in the chalk suspension comprised between 0.1 and 5.0 g/L. The method according to any one of the preceding claims 1-14, characterized in that the creation of the fertilizer strip in step a and/or the distribution of the fertilizer on the fertilizer strip in step b is performed by means of a coulter fertilizer. The method according to claim 15, characterized in that the coulter fertilizer injector comprises a spraying device suitable for spraying, spraying and/or atomizing the liquid over the fertilizer and/or the fertilizer strip in step c.