Inhabitants of the soil environment. Soil inhabitants

What animals live in the soil? and got the best answer

Answer from Yatyan[active]
Living organisms - inhabited soils
Various living organisms live in the soil - bacteria, microscopic fungi, small animals. Life in the soil is associated with a lack of light, difficulties in movement, high humidity or lack of water, big amount dying plant roots and plant debris on its surface.
Living organisms living in the soil have various adaptations to the soil environment. A mole, for example, has short front legs and faces not downwards, like those of terrestrial animals, but to the sides: the wide hands are turned back. The fingers with strong, sharp claws are connected by a leathery membrane. With such legs, the mole easily loosens the soil and makes holes in it. The mole's eyes are underdeveloped and hidden by fur. With them he distinguishes only light from darkness. The insect mole cricket has front legs, like those of a mole, digging, and the eyes are less developed than those of the cockchafer.
Moles and mole crickets constantly live in the soil. They can leave the layers in which they are created unfavourable conditions life, into other layers of soil. During drought and winter they move to deeper layers. In contrast, gophers, marmots, badgers, and rabbits feed on the surface of the soil, and in the burrows they make in the soil they reproduce, out of danger and bad weather.
Plants have developed adaptations, including root systems, to the dryness or moisture of the soil. On soils lacking moisture, plants form powerful roots reaching groundwater. Camel thorn, which grows in deserts, has roots that go down to a depth of 20 m.
In plants growing in highly humid places, the roots are located close to the surface of the soil, since in deeper layers, where water displaces all the air, the plant roots do not have enough air.
The soil is constantly inhabited by many invertebrate animals - ants, centipedes, worms, mites, beetles, larvae of beetles and flies, slugs, etc. All of them have adapted to life in the soil environment in their own way and play an important role in soil formation processes. Among them, the largest mass is made up of earthworms. total weight The Earth's earthworms are 10 times larger than the mass of all humanity!

Answer from Yoman Lazarev[active]
moles, for example...

Answer from Joni[guru]
moles!

Answer from ABRAM[guru]
small, gray, lives 3 meters underground and eats stones

Answer from VladCo[guru]
All animals live in the ground, because they have burrows there, but most of them lead a terrestrial lifestyle. Moles, shrews, and dormice are almost always underground (3/4 years)

Answer from Olga Perminova[newbie]
for example: mole, earthworm

Answer from Kristina Protopopova[newbie]
Thank you!!! very detailed and clear

Answer from Lika[newbie]
Not only do they “work” in the soil earthworms, but also their closest relatives are smaller whitish ones annelids(enchytraids, or pot worms), as well as some types of microscopic roundworms (nematodes), small mites, various insects, especially their larvae, and, finally, woodlice, centipedes and even snails.
Affects the soil and is clean mechanical work many animals living in it. They make passages, mix and loosen the soil, and dig holes. All this increases the number of voids in the soil and facilitates the penetration of air and water into its depths. This “work” involves not only relatively small invertebrate animals, but also many mammals - moles, marmots, ground squirrels, jerboas, field and forest mice, hamsters, voles, mole rats. The relatively large passages of some of these animals go 1-4 m deep. The passages of large earthworms also go deep: in most of them they reach 1.5-2 m, and in one southern worm even 8 m. Along these passages, especially in denser soils, plant roots penetrate deeper. In some places, such as steppe zone, a large number of passages and holes are dug in the soil by dung beetles, mole crickets, crickets, tarantula spiders, ants, and in the tropics - termites.

Answer from Yorgey Blinov[newbie]
Worms, mole crickets, ants, mole, antlion....

Answer from Marina Karpushkina[newbie]
Well, for example, a bear, a mole, a dormouse, and a fox

Answer from Jurassic blue[newbie]
moles

Answer from Natalie[newbie]
mole worm spider bugs...
well, I do not know

Answer from Polina Yakovleva[newbie]
centipede, mole cricket, mole, earthworm.

All around us: on the ground, in the grass, in the trees, in the air - life is in full swing everywhere. Even a resident who has never gone deep into the forest big city often sees birds, dragonflies, butterflies, flies, spiders and many other animals around him. The inhabitants of reservoirs are also well known to everyone. Everyone, at least occasionally, has seen schools of fish near the shore, water beetles or snails.

But there is a world hidden from us, inaccessible to direct observation - a peculiar world of soil animals.

There is eternal darkness there; you cannot penetrate there without destroying the natural structure of the soil. And only isolated, accidentally noticed signs show that under the surface of the soil, among the roots of plants, there is a rich and diverse world animals. This is sometimes evidenced by mounds above mole holes, holes in gopher holes in the steppe or holes of shore swallows in a cliff above the river, piles of earth on paths thrown out by earthworms, and they themselves crawling out after the rain, masses of winged ants suddenly appearing literally from underground or fatty larvae of cockchafers that come across when digging up the ground.

Soil is usually called the surface layer earth's crust on land, formed during the weathering of bedrock under the influence of water, wind, temperature fluctuations and the activities of plants, animals and humans. The most important property of the soil, which distinguishes it from the infertile parent rock, is fertility, i.e. the ability to produce a crop of plants (see article "").

As a habitat for animals, soil is very different from water and air. Try waving your hand in the air - you will notice almost no resistance. Do the same in water - you will feel significant resistance from the environment. And if you put your hand in a hole and cover it with earth, it will be difficult to even pull it out, let alone move it from side to side. It is clear that animals can move relatively quickly in the soil only in natural voids, cracks or previously dug passages. If there is none of this, then the animal can advance only by breaking through the passage and raking the earth back, or by “eating” the passage, that is, swallowing the earth and passing it through the intestines. The speed of movement will, of course, be insignificant.

Burrowing animals and their passages in the soil: 1 - toad; 2 - cricket; 3 - harvest mouse; 4 mole crickets; 5 - shrew; 6 - mole.

Every animal needs to breathe to live. The conditions for breathing in soil are different than in water or air. Soil consists of solid particles, water and air. Solid particles in the form of small lumps occupy slightly more than half of its volume; the rest falls on the gaps - pores, which can be filled with air (in dry soil) or water (in soil saturated with moisture). As a rule, water covers all soil particles with a thin film; the rest of the space between them is occupied by air saturated with water vapor.

Thanks to this structure of the soil, numerous animals that breathe through the skin can live in it. If you take them out of the ground, they quickly die from drying out. Moreover, hundreds of species of real freshwater animals live in the soil - the same ones that inhabit rivers, ponds and swamps. True, these are all microscopic creatures - lower worms and single-celled protozoa. They move and float in a film of water covering soil particles.

If the soil dries out, they secrete a protective shell and cease to be active for a long time.

Soil air receives oxygen from the atmosphere: its amount in the soil is 1-2% less than in atmospheric air. Oxygen is consumed in the soil by animals, microorganisms, and plant roots. They all highlight carbon dioxide. There is 10-15 times more of it in soil air than in the atmosphere. Free gas exchange between soil and atmospheric air can occur only if the holes between solid particles are not completely filled with water. After heavy rains or in the spring, after the snow melts, the soil is saturated with water. There is not enough air in the soil, and under the threat of death, many animals strive to leave the soil. This explains the appearance of earthworms on the surface after heavy rains.

Among soil animals there are also predators and those that feed on parts of living plants, mainly roots. There are also consumers of decomposing plant and animal residues in the soil - perhaps bacteria also play a significant role in their nutrition.

Soil animals find their food either in the soil itself or on its surface. The life activity of many of them is very useful. The activity of earthworms is especially useful, as they drag a huge amount of plant debris into their burrows: this promotes the formation of humus and returns substances extracted from it by plant roots to the soil.

In forest soils, invertebrates, especially earthworms, process more than half of all leaf litter. Over the course of a year, on each hectare, they throw out to the surface up to 25-30 tons of soil they have processed, turned into good, structural soil. If you distribute this soil evenly over the entire surface of a hectare, you will get a layer of 0.5-0.8 cm. Therefore, it is not for nothing that earthworms are considered the most important soil builders.

Not only earthworms “work” in the soil, but also their closest relatives - smaller whitish annelids (enchytraeids, or pot worms), as well as some types of microscopic roundworms (nematodes), small mites, various insects, especially their larvae, and finally woodlice, millipedes and even snails.

The purely mechanical work of many animals living in it also affects the soil. They make passages in the soil, mix and loosen it, and dig holes. All this increases the number of voids in the soil and facilitates the penetration of air and water into its depths.

This “work” involves not only relatively small invertebrate animals, but also many mammals - moles, shrews, marmots, gophers, jerboas, field and forest mice, hamsters, voles, and mole rats. The relatively large passages of some of these animals penetrate the soil to a depth of 1 to 4 m.

The passages of large earthworms go even deeper: in most worms they reach 1.5-2 m, and in one southern worm even up to 8 m. These passages, especially in denser soils, are constantly used by plant roots that penetrate deeper into them.

In some places, for example in the steppe zone, a large number of passages and holes are dug in the soil by dung beetles, mole crickets, crickets, tarantula spiders, ants, and in the tropics - termites.

Many soil animals feed on roots, tubers, and plant bulbs. Those that attack crop plants or forest plantations, are considered pests, for example the cockchafer. Its larva lives in the soil for about four years and pupates there. In the first year of life, it feeds mainly on the roots of herbaceous plants. But, as it grows, the larva begins to feed on the roots of trees, especially young pines, and causes great harm to the forest or forest plantations.

The larvae of click beetles, darkling beetles, weevils, pollen eaters, caterpillars of some butterflies, such as cutworms, the larvae of many flies, cicadas and, finally, root aphids, such as phylloxera, also feed on the roots of various plants, greatly harming them.

A large number of insects that damage the above-ground parts of plants - stems, leaves, flowers, fruits - lay eggs in the soil; Here, the larvae emerging from the eggs hide during the drought, overwinter, and pupate.

Soil pests include some species of mites and centipedes, naked slugs and extremely numerous microscopic roundworms - nematodes. Nematodes penetrate from the soil into the roots of plants and disrupt their normal functioning.

There are many predators living in the soil. “Peaceful” moles and shrews eat huge amounts of earthworms, snails and insect larvae; they even attack frogs, lizards and mice. They eat almost continuously. For example, a shrew eats an amount of living creatures per day equal to its own weight!

There are predators among almost all groups of invertebrates living in the soil. Large ciliates feed not only on bacteria, but also on protozoa, such as flagellates. The ciliates themselves serve as prey for some roundworms. Predatory mites attack other mites and tiny insects. Thin, long, pale-colored geophilic centipedes living in cracks in the soil, as well as larger dark-colored drupes and centipedes that live under stones, in stumps, in the forest floor, are also predators. They feed on insects and their larvae, worms and other small animals. Predators include spiders and related haymakers (“mow-mow-leg”). Many of them live on the soil surface, in litter, or under objects lying on the ground.

Many predatory insects live in the soil: ground beetles and their larvae, which play a significant role in exterminating pest insects, many ants, especially larger species, which exterminate a large number of harmful caterpillars, and, finally, the famous antlions, so named because their larvae hunt for ants. The antlion larva has strong, sharp jaws and is about 1 cm long. The larva digs in dry sandy soil, usually at the edge of the forest. pine forest, a funnel-shaped hole and buries itself in the sand at its bottom, sticking out only its wide-open jaws. Small insects, most often ants, that fall on the edge of the funnel roll down. The antlion larva grabs them and sucks them out.

In some places, a predatory...fungus is found in the soil! The mycelium of this fungus, which has a tricky name - didymozoophage, forms special trapping rings. Small soil worms - nematodes - get into them. With the help of special enzymes, the fungus dissolves the rather durable shell of the worm, grows inside its body and eats it out completely.

In the process of adaptation to living conditions in the soil, its inhabitants developed a number of features in the shape and structure of the body, in physiological processes, reproduction and development, in the ability to tolerate unfavorable conditions and in behavior. Although each type of animal has characteristics unique to it, in the organization of various soil animals there are also common features, characteristic of entire groups, since the living conditions in the soil are basically the same for all its inhabitants.

Earthworms, nematodes, most centipedes, and the larvae of many beetles and flies have a highly elongated flexible body, allowing them to easily move through winding narrow passages and cracks in the soil. Bristles in earthworms and other annelids, hairs and claws in arthropods allow them to significantly accelerate their movements in the soil and stay firmly in burrows, clinging to the walls of passages. Look how slowly a worm crawls along the surface of the earth and with what speed, essentially instantly, it hides in its hole. When making new passages, many soil animals alternately lengthen and shorten their bodies. In this case, cavity fluid is periodically pumped into the front end of the animal. He. strongly swells and pushes away soil particles. Other animals make their way by digging the ground with their front legs, which have turned into special digging organs.

The color of animals that constantly live in the soil is usually pale - grayish, yellowish, whitish. Their eyes, as a rule, are poorly developed or not at all, but their organs of smell and touch are very finely developed.

Scientists believe that life originated in the primordial ocean and only much later spread from here to land (see article ""). It is very possible that for some terrestrial animals the soil was a transitional environment from life in water to life on land, since soil is a habitat intermediate in its properties between water and air.

There was a time when only aquatic animals existed on our planet. After many millions of years, when land had already appeared, some of them fell ashore more often than others. Here, to escape drying out, they buried themselves in the ground and gradually adapted to permanent life in primary soil. Millions more years passed. The descendants of some soil animals, having developed adaptations to protect themselves from drying out, finally had the opportunity to reach the surface of the earth. But they probably couldn’t stay here for long at first. And they must have only come out at night. Until now, the soil provides shelter not only for “its own” soil animals that live in it constantly, but also for many that come to it only temporarily from reservoirs or from the surface of the earth to lay eggs, pupate, and go through a certain stage of development , escape from heat or cold.

The animal world of the soil is very rich. It includes about three hundred species of protozoa, more than a thousand species of roundworms and annelids, tens of thousands of species of arthropods, hundreds of mollusks and a number of vertebrate species.

Among them there are both useful and harmful. But the majority of soil animals are still listed under the “indifferent” heading. It is possible that this is the result of our ignorance. Studying them is the next task of science.

General characteristics.

Soil is a product of the vital activity of organisms, including microorganisms, both modern and belonging to the “former biospheres”. Soil is the most important component of any terrestrial ecological system, on the basis of which the development of plant communities occurs, which in turn form the basis food chains all other organisms that form the Earth’s ecological systems, its biosphere. People are no exception here: the well-being of any human society is determined by the availability and condition of land resources and soil fertility.

Meanwhile, for historical time Up to 20 million km2 of agricultural land was lost on our planet. For each inhabitant of the Earth today there is an average of only 0.35-0.37 hectares, whereas in the 70s this value was 0.45-0.50 hectares. If current situation will not change, then in a century, at such a rate of losses, total area land suitable for agriculture will decrease from 3.2 to 1 billion hectares.

V.V. Dokuchaev identified 5 main soil-forming factors:

· climate;

· parent rock (geological basis);

· topography (relief);

· alive organisms;

Currently, another factor in soil formation can be called human activity.

Soil formation begins with primary succession, manifested in physical and chemical weathering, leading to loosening from the surface of the parent soils. rocks, such as basalts, gneisses, granites, limestones, sandstones, shales. This weathering layer is gradually populated by microorganisms and lichens, which transform the substrate and enrich it with organic substances. As a result of the activity of lichens, essential plant nutrition elements such as phosphorus, calcium, potassium and others accumulate in the primary soil. Plants can now settle in this primary soil and form plant communities, defining the face of biogeocenosis.

Gradually, deeper layers of the earth are involved in the process of soil formation. Therefore, most soils have a more or less pronounced layered profile, divided into soil horizons. A complex of soil organisms settles in the soil - edaphone : bacteria, fungi, insects, worms and burrowing animals. Edaphon and plants participate in the formation of soil detritus, which detritivores - worms and insect larvae - pass through their bodies.

For example, earthworms process about 50 tons of soil per hectare of land per year.

When plant detritus decomposes, humic substances are formed - weak organic humic and fulvic acids - the basis of soil humus. Its content ensures the structure of the soil and the availability of mineral nutrients to plants. The thickness of the humus-rich layer determines the fertility of the soil.

Soil composition includes 4 important structural components:

mineral base (50-60% general composition soil);

· organic matter(to 10%);

· air (15-20%);

· water (25-35%).

Mineral base- an inorganic component formed from the parent rock as a result of its weathering. Mineral fragments vary in size (from boulders to grains of sand and tiny particles clay). This is the skeletal material of the soil. It is divided into colloidal particles (less than 1 micron), fine soil (less than 2 mm) and large fragments. The mechanical and chemical properties of soil are determined by small particles.

The structure of the soil is determined by the relative content of sand and clay in it. The most favorable soil for plant growth is one containing equal amounts of sand and clay.

In soil, as a rule, there are 3 main horizons, differing in mechanical and chemical properties:

· Upper humus-accumulative horizon (A), in which organic matter accumulates and is transformed and from which some of the compounds are carried down by washing waters.

· Elution or illuvial horizon (B), where the substances washed from above settle and are transformed.

· Mother breed or horizon (C), the material that is converted into soil.

Within each layer, more subdivided horizons are distinguished, differing in their properties.

The main properties of soil are: ecological environment are its physical structure, mechanical and chemical composition, acidity, redox conditions, organic matter content, aeration, moisture capacity and humidity. Various combinations of these properties create many varieties of soils. On Earth, the leading position in terms of prevalence is occupied by five typological groups of soils:

1. soil humid tropics and subtropics, mainly red soils And zheltozems characterized by wealth mineral composition and high mobility of organic matter;
2. fertile soils of savannas and steppes - chernozems, chestnut And brown soils with a thick humus layer;
3. poor and extremely unstable soils of deserts and semi-deserts belonging to various climatic zones;
4. relatively poor soils of temperate forests - podzolic, sod-podzolic, brown And gray forest soils ;
5. frozen soils, usually thin, podzolic, swamp , gley , depleted in mineral salts with a poorly developed humus layer.

Along the river banks there are floodplain soils;

Saline soils are a separate group: salt marshes, salt licks, and etc. which account for 25% of soils.

Salt marshes – soils that are constantly heavily moistened with salt water up to the surface, for example, around bitter-salty lakes. In summer, the surface of the salt marshes dries out, becoming covered with a crust of salt.

Solontsy – the surface is not salted, upper layer leached, structureless. The lower horizons are compacted, saturated with sodium ions, and when dry they crack into pillars and blocks. Water mode unstable - in spring - stagnation of moisture, in summer - severe drying out.

Salt marshes

Solanchak-like solonetzes

Alkaline soils (lightly salted)

Soil organic matter.

Each soil type corresponds to a specific plant, animal world and a collection of bacteria – edafon. Dying or dying organisms accumulate on the surface and within the soil, forming soil organic matter called humus . The process of humification begins with the destruction and grinding of organic matter by vertebrates, and then is transformed by fungi and bacteria. Such animals include phytophages feeding on the tissues of living plants, saprophages consuming dead plant matter, necrophages feeding on animal carcasses, coprophagous , destroying animal excrement. They all make up complex system, called saprophilic animal complex .

Humus varies in type, shape and nature of its constituent elements, which are divided into humic And non-humic substances. Non-humic substances are formed from compounds found in plant and animal tissues, for example, proteins and carbohydrates. When these substances decompose, carbon dioxide, water, and ammonia are released. The energy generated is used by soil organisms. In this case, complete mineralization of nutrients occurs. Humic substances as a result of the vital activity of microorganisms are processed into new, usually high-molecular compounds - humic acids or fulvic acids .

Humus is divided into nutritious, which is easily processed and serves as a source of nutrition for microorganisms, and stable, which performs physical and chemical functions, controlling the balance nutrient, the amount of water and air in the soil. Humus tightly glues the mineral particles of the soil, improving its structure. The structure of soils also depends on the amount of calcium compounds. The following soil structures are distinguished:

· mealy,

· powdery,

· grainy,

· nutty,

· lumpy,

· clayey.

The dark color of humus contributes to better heating of the soil, and its high moisture capacity contributes to the retention of water by the soil.

The main property of soil is its fertility, i.e. the ability to provide plants with water, mineral salts, and air. The thickness of the humus layer determines the fertility of the soil.

Humidity and aeration.

Soil water is divided into:

· gravitational

· hygroscopic,

· capillary,

· vaporous

Gravitational water - mobile, is the main type of mobile water, fills wide gaps between soil particles, seeps down under the influence of gravity until it reaches groundwater. Plants easily absorb it.

Hygroscopic water in the soil is retained by hydrogen bonds around individual colloidal particles in the form of a thin, strong bonded film. It is released only at a temperature of 105 - 110 ° C and is practically inaccessible to plants. The amount of hygroscopic water depends on the content of colloidal particles in the soil. In clay soils it is up to 15%, in sandy soils – 5%.

As the amount of hygroscopic water accumulates, it turns into capillary water, which is held in the soil by surface tension forces. Capillary water easily rises to the surface through pores from groundwater, easily evaporates, and is freely absorbed by plants.

Vaporous moisture occupies all water-free pores.

There is a constant exchange of soil, ground and surface waters, changing its intensity and direction depending on the climate and seasons.

All pores free from moisture are filled with air. On light (sandy) soils, aeration is better than on heavy (clayey) soils. Air and humidity conditions are related to the amount of precipitation.

Environmental groups soil organisms.

On average, the soil contains 2-3 kg/m2 of living plants and animals, or 20-30 t/ha. At the same time, in temperate zone plant roots make up 15 t/ha, insects 1t, earthworms – 500kg, nematodes – 50kg, crustaceans – 40kg, snails, slugs – 20kg, snakes, rodents – 20gk, bacteria – 3t, fungi – 3t, actinomycetes – 1.5t, protozoa – 100 kg, algae – 100 kg.

The heterogeneity of the soil leads to the fact that different organisms she acts as different environment. According to the degree of connection with the soil as a habitat animals divided into 3 groups:

· Geobionts – animals that constantly live in the soil (earthworms, primarily wingless insects).

· Geophylls – animals, part of the cycle of which necessarily takes place in the soil (most insects: locusts, a number of beetles, centipede mosquitoes).

· Geoxenes – animals that sometimes visit the soil for temporary shelter or refuge (cockroaches, many hemipterans, coleopterans, rodents and other mammals).

Depending on the size, soil inhabitants can be divided into the following groups.

· Microbiotype, microbiota – soil microorganisms, the main link in the detritus chain, an intermediate link between plant residues and soil animals. These are green, blue-green algae, bacteria, fungi, and protozoa. The soil for them is a system of micro-reservoirs. They live in soil pores. Able to tolerate soil freezing.

· Macrobiotype, macrobiota – large soil animals, up to 20 mm in size (insect larvae, millipedes, earthworms, etc.). For them, the soil is a dense medium that provides strong mechanical resistance when moving. They move in the soil, expanding natural wells by moving apart soil particles or swarming new tunnels. In this regard, they have developed adaptations for digging. There are often specialized respiratory organs. They also breathe through the covers of the body. In winter and during dry periods they move to deep soil layers.

· Megabiotype, megabiota – large shrews, mainly mammals. Many of them spend their entire lives in the soil (golden moles, mole moles, zokors, moles of Eurasia, marsupial moles of Australia, mole rats, etc.). They lay a system of holes and passages in the soil. They have underdeveloped eyes, a compact, ridged body with a short neck, short thick fur, strong compact limbs, burrowing limbs, and strong claws.

· Burrow inhabitants - badgers, marmots, gophers, jerboas, etc. They feed on the surface, reproduce, hibernate, rest, sleep, and escape from danger in soil burrows. The structure is typical for terrestrial animals, but they have burrowing adaptations - strong claws, strong muscles on the forelimbs, a narrow head, small ears.

· Psammophiles – inhabitants of shifting sands. They have peculiar limbs, often in the shape of “skis”, covered with long hairs and horny outgrowths (thin-toed ground squirrel, comb-toed jerboa).

· Gallophiles – inhabitants of saline soils. They have adaptations to protect against excess salts: dense covers, devices for removing salts from the body (larvae of desert darkling beetles).

Plants are divided into groups depending on their requirements for soil fertility.

· Eutotrophic or eutrophic - grow on fertile soils.

· Mesotrophic – less demanding on soil fertility.

· Oligotrophic - contented a small amount nutrients.

Depending on the requirements of plants for individual soil microelements, the following groups are distinguished.

· Nitrophils – demanding of the presence of nitrogen in the soil, they settle where there are additional sources of nitrogen - clearing plants (raspberries, hops, bindweed), garbage plants (nettle, umbrella plants), pasture plants.

· Calciophiles – demanding of the presence of calcium in the soil, they settle on carbonate soils (lady’s slipper, Siberian larch, beech, ash).

· Calciphobes – plants that avoid soils with a high calcium content (sphagnum mosses, bog mosses, heather mosses, warty birch, chestnut).

Depending on the soil pH requirements, all plants are divided into 3 groups.

· Acidophilus – plants that prefer acidic soils (heather, white sorrel, sorrel, small sorrel).

· Basiphylla – plants that prefer alkaline soils (coltsfoot, field mustard).

· Neutrophils – plants that prefer neutral soils (meadow foxtail, meadow fescue).

Plants growing in saline soils are called halophytes (European saltwort, knobby sarsazan), and plants that cannot withstand excessive salinity - glycophytes . Halophytes have high osmotic pressure, which allows them to use soil solutions, and are able to release excess salts through their leaves or accumulate them in their bodies.

Plants adapted to shifting sand are called psammophytes . They are capable of forming adventitious roots when covered with sand; adventitious buds form on the roots when they are exposed; they often have high speed shoot growth, flying seeds, durable covers, have air chambers, parachutes, propellers - devices for not being covered with sand. Sometimes a whole plant can tear itself away from the ground, dry out, and, along with its seeds, be transported by the wind to another place. The seedlings germinate quickly, competing with the dune. There are adaptations to endure drought - sheaths on the roots, suberization of roots, strong development of lateral roots, leafless shoots, xeromorphic foliage.

Plants that grow in peat bogs are called oxylophytes . They are adapted to high soil acidity, high moisture, and anaerobic conditions (ledum, sundew, cranberry).

Plants that live on stones, cliffs, and scree are classified as lithophytes. As a rule, these are the first settlers on rocky surfaces: autotrophic algae, crustose lichens, leaf lichens, mosses, lithophytes from higher plants. They are called crevice plants - chasmophytes . For example, saxifrage, juniper, pine.

All around us: on the ground, in the grass, in the trees, in the air - life is in full swing everywhere. Even a resident of a big city who has never gone deep into the forest often sees birds, dragonflies, butterflies, flies, spiders and many other animals around him. The inhabitants of reservoirs are also well known to everyone. Everyone, at least occasionally, has seen schools of fish near the shore, water beetles or snails.
But there is a world hidden from us, inaccessible to direct observation - a peculiar world of soil animals.
There is eternal darkness there; you cannot penetrate there without destroying the natural structure of the soil. And only isolated, accidentally noticed signs show that beneath the surface of the soil among the roots of plants there is a rich and diverse world of animals. This is sometimes evidenced by mounds above mole holes, holes in gopher holes in the steppe or sand swallow holes in a cliff above the river, piles of earth on the path thrown out by earthworms, and the earthworms themselves crawling out after the rain, as well as masses unexpectedly appearing literally from underground winged ants or fat larvae of cockchafers that are caught when digging up the ground.
Soil is usually called the surface layer of the earth's crust on land, formed during the weathering of bedrock under the influence of water, wind, temperature fluctuations and the activity of plants, animals and humans. The most important property of soil, which distinguishes it from infertile parent rock, is fertility, i.e., the ability to produce a crop of plants.

As a habitat for animals, soil is very different from water and air. Try waving your hand in the air - you will notice almost no resistance. Do the same in water - you will feel significant resistance from the environment. And if you put your hand in a hole and cover it with earth, it will be difficult to pull it back out. It is clear that animals can move relatively quickly in the soil only in natural voids, cracks or previously dug passages. If there is nothing of this in the way, then the animal can advance only by breaking through a passage and raking the earth back or swallowing the earth and passing it through the intestines. The speed of movement will, of course, be insignificant.
Every animal needs to breathe to live. The conditions for breathing in soil are different than in water or air. Soil consists of solid particles, water and air. Solid particles in the form of small lumps occupy slightly more than half of its volume; the rest falls on the gaps - pores, which can be filled with air (in dry soil) or water (in soil saturated with moisture). As a rule, water covers all soil particles with a thin film; the rest of the space between them is occupied by air saturated with water vapor.
Thanks to this structure of the soil, numerous animals live in it and breathe through their skin. If you take them out of the ground, they quickly die from drying out. Moreover, hundreds of species of real freshwater animals live in the soil, inhabiting rivers, ponds and swamps. True, these are all microscopic creatures - lower worms and single-celled protozoa. They move and float in a film of water covering soil particles. If the soil dries out, these animals secrete a protective shell and seem to fall asleep.

Soil air receives oxygen from the atmosphere: its amount in the soil is 1-2% less than in atmospheric air. Oxygen is consumed in the soil by animals, microorganisms, and plant roots. They all emit carbon dioxide. There is 10-15 times more of it in soil air than in the atmosphere. Free gas exchange between soil and atmospheric air occurs only if the pores between the solid particles are not completely filled with water. After heavy rains or in the spring, after the snow melts, the soil is saturated with water. There is not enough air in the soil, and under the threat of death, many animals leave it. This explains the appearance of earthworms on the surface after heavy rains.
Among soil animals there are also predators and those that feed on parts of living plants, mainly roots. There are also consumers of decomposing plant and animal residues in the soil - perhaps bacteria also play a significant role in their nutrition.
Soil animals find their food either in the soil itself or on its surface.
The life activity of many of them is very useful. The activity of earthworms is especially useful. They drag a huge amount of plant debris into their burrows, which contributes to the formation of humus and returns substances extracted from it by plant roots to the soil.
In forest soils, invertebrates, especially earthworms, process more than half of all leaf litter. Over the course of a year, on each hectare, they throw out to the surface up to 25-30 tons of land they have processed, turned into good, structural soil. If you distribute this soil evenly over the entire surface of a hectare, you will get a layer of 0.5-0.8 cm. Therefore, it is not for nothing that earthworms are considered the most important soil builders. Not only earthworms “work” in the soil, but also their closest relatives - smaller whitish annelids (enchytraeids, or pot worms), as well as some types of microscopic roundworms (nematodes), small mites, various insects, especially their larvae, and finally woodlice, millipedes and even snails.

Medvedka

The purely mechanical work of many animals living in it also affects the soil. They make passages, mix and loosen the soil, and dig holes. All this increases the number of voids in the soil and facilitates the penetration of air and water into its depths.
This “work” involves not only relatively small invertebrate animals, but also many mammals - moles, shrews, marmots, gophers, jerboas, field and forest mice, hamsters, voles, and mole rats. The relatively large passages of some of these animals go deep from 1 to 4 m.
The passages of large earthworms go even deeper: in most of them they reach 1.5-2 m, and in one southern worm even 8 m. These passages, especially in denser soils, are constantly used by plant roots penetrating into the depths. In some places, for example in the steppe zone, a large number of passages and holes are dug in the soil by dung beetles, mole crickets, crickets, tarantula spiders, ants, and in the tropics - termites.
Many soil animals feed on roots, tubers, and plant bulbs. Those that attack cultivated plants or forest plantations are considered pests, for example the cockchafer. Its larva lives in the soil for about four years and pupates there. In the first year of life, it feeds mainly on the roots of herbaceous plants. But, as it grows, the larva begins to feed on the roots of trees, especially young pines, and causes great harm to the forest or forest plantations.

Mole paws are well adapted for life in the soil.

The larvae of click beetles, darkling beetles, weevils, pollen eaters, caterpillars of some butterflies, such as cutworms, the larvae of many flies, cicadas and, finally, root aphids, such as phylloxera, also feed on the roots of various plants, greatly harming them.
A large number of insects that damage the above-ground parts of plants - stems, leaves, flowers, fruits, lay eggs in the soil; Here, the larvae that emerge from the eggs hide during drought, overwinter, and pupate. Soil pests include some species of mites and centipedes, naked slugs and extremely numerous microscopic roundworms - nematodes. Nematodes penetrate from the soil into the roots of plants and disrupt their normal functioning. There are many predators living in the soil. “Peaceful” moles and shrews eat huge amounts of earthworms, snails and insect larvae; they even attack frogs, lizards and mice. These animals eat almost continuously. For example, a shrew eats an amount of living creatures per day equal to its own weight!
There are predators among almost all groups of invertebrates living in the soil. Large ciliates feed not only on bacteria, but also on protozoa, such as flagellates. The ciliates themselves serve as prey for some roundworms. Predatory mites attack other mites and small insects. Thin, long, pale-colored geophilic centipedes that live in soil cracks, as well as larger dark-colored drupes and centipedes that stay under stones and in stumps, are also predators. They feed on insects and their larvae, worms and other small animals. Predators include spiders and related haymakers (“mow-mow-leg”). Many of them live on the soil surface, in the litter, or under objects lying on the ground.

Antlion larva.

Long arthropods that move on many legs are often found in the ground. In most cases they are not harmful to plants.

Centipedes scare everyone with their menacing appearance. However, they eat plants extremely rarely, and even then mainly in closed ground. Basically, they hunt their relatives - insects.

Thin are evil

If, while digging the beds, you see a long larva swarming in the soil, similar to a worm, but with a hard body, know: this is one of the dangerous pests.

Wireworm (larva of click beetle). Yellow (brown or dark brown) creatures up to 15-17 mm long, living in the soil to a depth of 10-12 cm. Wireworms got their name due to the fact that their bodies are extremely hard and tough.

Wireworm. Photo: Nina Belyavskaya

The larvae feed on plant roots, seeds, seedlings, and seedlings and can cause great damage.

Prevention. In small areas - watering with a solution of potassium permanganate (2-5 g per 10 liters of water). Sowing seeds not lower than the recommended depth with the simultaneous application of mineral fertilizers. Keeping the soil free from weeds. Loosening to a depth of 10-12 cm. Timely collection of mown grass. Early autumn digging of the soil (until mid-September).

Biological protection. Laying in the spring before sowing pieces raw potatoes, carrots or beets into the soil to a depth of 5-15 cm (with a mark of their location). After 3-4 days, destroy the baits with larvae.

Chemical protection: see table. Shading traps made from freshly weeded weeds treated with any of the approved contact insecticides help against adult click beetles.

Pseudowire (darkling beetle larva). It looks like brother wireworm: only its first pair of legs is noticeably larger than the next ones, and its head is convex on top.

False wireworm. Photo: Nina Belyavskaya

Prevention and protection measures. Adding Vallar and Terradox, Contador maxi to the soil before planting. Use of shading poisoned baits.

Fat - different

Fleshy, light-colored insect larvae rolled into half rings are found in the soil. They can be either harmful or relatively harmless, and the pest can be identified... by its legs!

Dangerous

Adult beetleworm larvae are quite large (depending on the species, from 1.5 to 7.5 cm in length), fat, curved like the letter “C,” yellowish-white with translucent intestines. Try to remember a good one identifying mark Khrushchev larvae: the back pair of their legs is the longest.

Khrushchev larva. Photo: Nina Belyavskaya

Prevention. Weed control. Some of the beetle larvae die when the soil is compacted in the spring.

Fight without harm. Collection and destruction of larvae during soil cultivation. Daily shaking off cockchafers onto shields or gauze cloths and their subsequent destruction.

They do harm, but rarely

Bronze larvae are often mistaken for Khrushchev larvae, which is not surprising, since they are close relatives. True, the larvae of bronzes have all pairs of legs of the same length. Bronze beetles can cause harm in rare cases - sometimes these beautiful bronze beetles eat plant flowers, and their larvae cause bald spots on the lawn.

Harmless

Larvae of pill beetles and dung beetles. Photo: Nina Belyavskaya

When digging an area, you can find greenish-brown or dirty white larvae with a clearly visible head and a body curved in the shape of the letter “C”, very similar to Khrushchev larvae, but with long front legs (Khrushchi have the longest hind legs ). These are the larvae of pill beetles and dung beetles. They do not harm plants!

Chemicals against pests

Pest	List of drugs	Mode of application
Wireworm	Pochin, Zemlin, Vallar, Terradox, Provotox, Biotlin, Bison, Imidor, Iskra, Kalash, Klubneshield, Commander, Corado, Prestige, Prestigator, Respect, Tanrek	Application to the soil before planting
Khrushchev	Vallar, Terradox	Dipping the roots of seedlings (saplings) into insecticidal soil mash before planting and re-applying the drug after 25-30 days to the surface of the earth with embedding to a depth of 5-10 cm.

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