Environmental Characteristics of the Mining Area of Ni–Cu–Fe Paleoproterozoic PGE Monchepluton Intrusion (NE Scandinavia)

: The problem of dump recultivation associated with sulﬁde ore mining is always a challenge for ecologists. A special case is the Arctic, where the speciﬁc climate and short vegetative period mean that any traces of such activities can persist for many years. The Monchepluton massif is a Paleoproterozoic, layered Platinum Group Element (PGE) intrusion, which is located in NE Scandinavia, beyond the Arctic Circle. This intrusion is mainly composed of ultramaﬁc and alkaline rocks, represented by dunites, harzburgites, orthopyroxenites, norites, and gabbronorites. In these rocks, there is mineralization of the oxide ores Cr, Fe, and Ti, as well as the sulﬁde ores Cu, Ni, Fe, and PGE. The massifs of this intrusion were mined in the 20th century. The traces of intensive mining in the area are still visible today. The purpose of this study was to demonstrate the state of the environment and propose its rehabilitation. The authors carried out an inventory of the mining facilities and studies of the area’s rocks, soils, plants, and waters. The results of these studies unequivocally show that the current condition of the site indicates the conditions for an ecological disaster. The most important polluting factor is the presence of metallurgical plants, which are responsible for acid rain and soil pollution. Another threat is uncontrolled mine water outﬂows. Due to the speciﬁc climatic conditions and the vegetation found in the area, the process of rehabilitating the area may be costly and lengthy.


Introduction
In NE Scandinavia, there are magmatic and metamorphic rocks that form the Fennoscandia craton [1][2][3][4][5]. Among these rocks are the Kola Series and the Belamorian Series [6], between which is the collisional series (the Lapland Granulite Belt) and a series of Paleoproterozoic PGE-Layered Intrusions, forming numerous occurrences [4,5,7,8]. They were formed during the breakup of the Kenorland Supercontinent [9][10][11][12][13][14][15][16], as a result of the impact of the long-lived hot spot and four magmatism activities [17,18]. Located in NE Scandinavia, the Monchepluton intrusion is one of the oldest in the region and has an age of 2500 million years [19][20][21][22][23]. It constitutes a series of small hills reaching up to 618 m above sea level ( Figure 1). The area was glaciated during the Pleistocene period, which resulted in the weathering of the summit parts and their strong smoothing [24]. In the summit parts, there is a stone run, sheep rocks, and rock blocks with a spur character, often with visible signs of weathering [24]. Small ponds and swampy zones are also visible. Below are sharpened slopes with numerous rock walls, and in the valley bottoms there are thick deposits of sands, clays, and gravels of a glacial origin [25]. Small glacial cirques are The Monchepluton intrusion, due to its location, is an area that was mined in the 20th century due to the presence of Cr-Ti-Fe oxide ores and Ni-Cu-Fe sulfides [35][36][37][38], along with the enrichment of PGE mineralization [39][40][41][42][43]. Currently, mining operations have stopped there, and the area is being developed for tourism [44][45][46][47]. However, due to the location of the massif behind the Arctic Circle and the numerous quarries, adits, and shafts, the area poses a threat to nature due to the lack of reclamation processes.
The purpose of this study is to characterize the state of the environment in the Monchepluton area and to identify possible avenues for the reclamation of the area.

Study Area Localization
The Monchepluton intrusion is located in NE Scandinavia and is surrounded to the north by Archean iron quartzites belonging to the Banded Iron Formation [2,3], to the west by the Monchetundra intrusion (age 2491 million years) [1,4,5], to the south by the Imandra intrusion (age 2410 million years) [1,4], and to the east by the Khibiny alkaline rock intrusion of a Paleozoic age [48] (Figure 2). The Monchepluton intrusion has an area of 55 km 2 [4,5] and consists of two wings: the NKT (Nittis, Kumuzhia, Traviannaya, and several smaller ones including the Dunite Block) and SNP (formed by the massifs of Sopcha, Nyud, Poaz, and Vurechuaivench, located slightly south of them) ranges. The NKT range extends southward, and the SNP band extends latitudinally ( Figure 2). The NKT range is built mainly of ultramafic rocks. The SNP band is mainly made up of alkaline rocks. All the ranges have sulfide mineralization, zones of so-called Critical Horizons [4,8], and are composed of intermixed ultramafic rocks, mafic rocks, and breccias of supracrustal rocks; additionally, younger mineral veins formations (mainly dolerite and younger prehnitecarbonatite veins), breccias, and mylonite are also present in the fault zones [3,[36][37][38]. The Monchepluton intrusion, due to its location, is an area that was mined in the 20th century due to the presence of Cr-Ti-Fe oxide ores and Ni-Cu-Fe sulfides [35][36][37][38], along with the enrichment of PGE mineralization [39][40][41][42][43]. Currently, mining operations have stopped there, and the area is being developed for tourism [44][45][46][47]. However, due to the location of the massif behind the Arctic Circle and the numerous quarries, adits, and shafts, the area poses a threat to nature due to the lack of reclamation processes.
The purpose of this study is to characterize the state of the environment in the Monchepluton area and to identify possible avenues for the reclamation of the area.

Study Area Localization
The Monchepluton intrusion is located in NE Scandinavia and is surrounded to the north by Archean iron quartzites belonging to the Banded Iron Formation [2,3], to the west by the Monchetundra intrusion (age 2491 million years) [1,4,5], to the south by the Imandra intrusion (age 2410 million years) [1,4], and to the east by the Khibiny alkaline rock intrusion of a Paleozoic age [48] (Figure 2). The Monchepluton intrusion has an area of 55 km 2 [4,5] and consists of two wings: the NKT (Nittis, Kumuzhia, Traviannaya, and several smaller ones including the Dunite Block) and SNP (formed by the massifs of Sopcha, Nyud, Poaz, and Vurechuaivench, located slightly south of them) ranges. The NKT range extends southward, and the SNP band extends latitudinally ( Figure 2). The NKT range is built mainly of ultramafic rocks. The SNP band is mainly made up of alkaline rocks. All the ranges have sulfide mineralization, zones of so-called Critical Horizons [4,8], and are composed of intermixed ultramafic rocks, mafic rocks, and breccias of supracrustal rocks; additionally, younger mineral veins formations (mainly dolerite and younger prehnitecarbonatite veins), breccias, and mylonite are also present in the fault zones [3,[36][37][38].

Characteristics of the Carried-Out Mining Operational Work
The mining activity in the area in question began in the first half of the 20th century after the re-discovery of sulfide Cu-Ni-Fe mineralization. At that time, intensive field work was carried out, combined with an exploration of deposits and an inventory of the geological structure of the area. This work was carried out in the 1930s by A.E. Fersman [4]. Then, numerous exploration adits and shafts were built. The work accelerated in the 1940s as a result of the war effort and the country's needs for reconstruction after the war. That was also when a mine was built in the Nittis, Sopcha, and Traviannaya areas. There were also large quarries established in the northern slopes of Sopcha and Nyud [4,5]. There were processing plants in the northern slopes of Nittis and a non-ferrous metal smelter that operated in Monchegorsk (north of Sopcha). At the time, the Monchepluton area was also home to a development of small wooden houses, which served as housing for seconded employees of the mine plants. It is possible that GULAG (General Directorate of Correctional Labor Camps and Colonies in the Soviet Union) prisoners were also used for work, as was the case in Khibiny and elsewhere. Intensive mining operations were carried out until the 1970s. In the late 20th century, chromite deposits were also discovered in the Dunite Block massif area, where a small quarry was also located. During the 1990s, these processes were halted, and the mining equipment was devastated. The buildings left unattended began deteriorating. The same was also true of the line built for the chairlift to Nittis. At present, the Monchegorsk non-ferrous metals smelter (north of Sopcha) and the chairlift on the Nyud slope are in operation. Access to the mining facilities is free, but many adits have collapsed and the buildings are ruined in many places. A television (TV) relay station also operates in the Poaz Peak area. As a result of a

Characteristics of the Carried-Out Mining Operational Work
The mining activity in the area in question began in the first half of the 20th century after the re-discovery of sulfide Cu-Ni-Fe mineralization. At that time, intensive field work was carried out, combined with an exploration of deposits and an inventory of the geological structure of the area. This work was carried out in the 1930s by A.E. Fersman [4]. Then, numerous exploration adits and shafts were built. The work accelerated in the 1940s as a result of the war effort and the country's needs for reconstruction after the war. That was also when a mine was built in the Nittis, Sopcha, and Traviannaya areas. There were also large quarries established in the northern slopes of Sopcha and Nyud [4,5]. There were processing plants in the northern slopes of Nittis and a non-ferrous metal smelter that operated in Monchegorsk (north of Sopcha). At the time, the Monchepluton area was also home to a development of small wooden houses, which served as housing for seconded employees of the mine plants. It is possible that GULAG (General Directorate of Correctional Labor Camps and Colonies in the Soviet Union) prisoners were also used for work, as was the case in Khibiny and elsewhere. Intensive mining operations were carried out until the 1970s. In the late 20th century, chromite deposits were also discovered in the Dunite Block massif area, where a small quarry was also located. During the 1990s, these processes were halted, and the mining equipment was devastated. The buildings left unattended began deteriorating. The same was also true of the line built for the chairlift to Nittis. At present, the Monchegorsk non-ferrous metals smelter (north of Sopcha) and the chairlift on the Nyud slope are in operation. Access to the mining facilities is free, but many adits have collapsed and the buildings are ruined in many places. A television (TV) relay station also operates in the Poaz Peak area. As a result of a community initiative, biking, climbing, and other trails are being created in the Nittis and Nyud areas.

Materials and Methods
The authors conducted detailed research in the Monchegorsk region (included Monchepluton) from 2008 to 2020. The study area focused on the NKT and SNP massifs. In particular, these are the areas of adits in the southwestern part of Traviannaya and in the eastern part of Kumuzhia, processing plants and other facilities in the Nittis and Sopcha areas, stone quarries and adits in the Nyud area, and facilities located in the Poaz area. During the fieldwork, the focus was on inventorying mining facilities, geological variability, determining the degree of the devastation of the environment by the earthworks, and where deep excavations were carried out. Collected rocks, along with lichens, were described in the field, where tomographic documentation was also conducted, and the location was determined using GPS. Thin, polished, and exposed plate preparations were made from selected rock samples as well as scrapings. The rock samples were pulverized and solubilized to determine their chemical composition. Plants were grouped and dried. Rock and plant samples were examined using a Leica DM2500P optical microscope in transmitted and reflected light and then tests were performed using a Hitachi SU6600 scanning electron microscope with an EDS (Energy Dispersive Spectroscopy) attachment [49][50][51][52][53][54]. The EDS analysis was performed on the "low-vacuum" setting, without sputtering with a conductive metal. The electron gun was set at 15 kV with an exposure time of 60 s. The scanning beam had a diameter of 2 µm. Geochemical investigations of rocks, soils, and plants were accomplished using ICP-OES (Inductively Coupled Plasma-Optical Emission Spectrometry) by Varian [55][56][57][58][59]. Selected samples were solubilized using a MARS microwave melter and then placed in an argon atmosphere; afterwards, they were fed to the ICP of Varian, where elemental composition analysis took place. Rocks samples were compared with the chondrite standard (as a reference material) [60]. The soil and plants analyses were performed using Loam Soil (7004) and San Joaqain Soil (0709) as reference materials. These studies were performed under the supervision of Dr. Lesia Lata. Water reaction and its electrolytic conductivity were measured using the meter WTW InoLab 1 firm compatible with the pH electrode Hanna Instrument and the conductometric electrode TetraC WTW. Bicarbonate content was determined by titration method with hydrochloric acid in the presence of bromocresol green. Concentrations of anions and cations were determined by ion chromatography (Metrohm MIC 3). Anions (sulphates, chlorides, and nitrates) were separated using the Metrosep A Supp 5-250 column. Cations (calcium, magnesium, sodium, potassium, strontium, and ammonium) were separated using the Metrosep C 2-150 column. In the analytic process, the following procedures and materials were employed: calibration by solutions Merck Anion multi-element standard I, Anion multi-element standard II, Cation multi-element standard VII, and analytical reference material Environment Canada MISSIPPI-14. Recovery of certified reference materials was in a range of 92-113% [61][62][63][64]. The EDS and ICP-MS (Inductively Coupled Plasma Mass Spectrometry) analyses of soils and rocks were carried out at the Department of Geology, Soil Science and Geoinformation; the water analyses were carried out at the Department of Hydrology and Climatology, Maria Curie-Skłodowska University, Lublin. The results of this research are described below.

Geology of the Monchepluton
Among the rocks found in Monchepluton are the ultra-basic types: dunites, chromitites, harzburgites, and orthopyroxenites [3,4]. The basic rocks are represented mainly by norites and gabbronorites and meta-anorthosite [3,4]. These rocks are accompanied by oxide and sulfide mineralization. Dunites and chromitites are exposed in the Dunite Block and in smaller amounts as inserts and lenses in Harzburgites in Traviannaya, Kumuzhia, and the northern slopes of Nittis. Dunites are gray-colored rocks with a coarse-crystalline structure and a clumped, disorderly texture. The olivines in these rocks form large crystals in contact with each other. Sometimes small crystals of chromite are also visible in the background of these minerals. Between the olivine crystals in the rock, there are a few, singular orthopyroxene crystals. In some zones of the rock, reaction crown zones composed of serpentine and talc minerals are visible ( Figure 3A). Chromitites are steel-gray colored rocks, usually forming layers, between dunites. They are rocks with a coarse crystalline structure and a compact, disorderly texture. Alongside these minerals, talc crystals are also visible ( Figure 3B). Small crystals of magnetite (mainly in zones close to serpentinization of olivine) and small sulfides (millerite) are also sometimes visible at these scales. Chemical studies of the rock samples in question have been published in another paper (Huber 2021). The chemical composition of the selected samples is presented below ( Table 1). The results of the analysis indicate a significant proportion of heavy metals, in particular, iron, titanium, copper, and nickel, and admixtures of zinc and lead. The content of these metals is mainly concentrated in sulfides, which are found in a dispersed form in Harzburgites are exposed mainly in the Traviannaya massif, Kumuzhia, and the northern slopes of Nittis, and as inserts and lenses in the Sopcha orthopyroxenites and the Critical Horizon area of Nyud. These rocks are black-colored, weathered in rusty-brown hues with a coarse-crystalline texture and a compact, disorderly texture. Visible in these rocks are olivines, often heavily fractured and serpentinized. Orthopyroxenes are visible next to these minerals. Small crystals of clinopyroxene, talc, and carbonates are also found. The sulfides present in these rocks are pyrrhotite, pentlandite, and chalcopyrite. In some zones, the sulfides are accompanied by PGE mineralization, represented by tellurides and bismuths of platinum and palladium. Orthopyroxenites are exposed in the Nittis and Sopcha massifs. These rocks are gray in color, coarse crystalline in structure, and have a compact, disorderly texture. Orthopyroxenes are visible in the rock, which is mainly represented by bronzite. Sometimes, fine aggregates of talc and chromite inclusions are found in pyroxenes.
Norites and olivine norites are found in the Nyud massif. These are gray-colored rocks with a coarse crystalline texture and a compact, unstructured, ophitic texture. In this rock, orthopyroxenes form large crystals, sometimes approximated with each other. Pyroxenes are found against a background of plagioclase, creating an ophitic texture in the rock. Small crystals of sulfides, represented mainly by pentlandite, pyroxene, and chalcopyrite with associated PGE mineralization, can sometimes be seen in the rock.
Gabbronorite and gabbro are exposed in the Nyud and Poaz massifs. They are steelgray-colored rocks, sometimes weathered in a rusty manner with a coarse-crystalline structure. Orthopyroxene and clinopyroxene are also visible. Next to them are plagioclases, which are numerous in the rock, forming an ophitic texture. There are small crystals of chromite in the pyroxenes. Scattered small crystals of sulfides and PGE mineralization can also be seen in the rock, as in norite.
The meta-anorthosites exposed in the Vurechuaivench massif are gray-colored rocks, with secondary gneissic structures sometimes visible. In this rock there are plagioclases, forming large anhedral crystals, which contact each other. Alongside these minerals, relics of clinopyroxene (diopside) can be seen, most often overgrown with common hornblende. These rocks also contain aggregates of phlogopite and accessory small addition of quartz crystals, featuring relict ilmenite with rutile and titanite. Sulfide mineralization containing PGE phases is also found in these rocks in less altered zones.
Chemical studies of the rock samples in question have been published in another paper (Huber 2021). The chemical composition of the selected samples is presented below ( Table 1). The results of the analysis indicate a significant proportion of heavy metals, in particular, iron, titanium, copper, and nickel, and admixtures of zinc and lead. The content of these metals is mainly concentrated in sulfides, which are found in a dispersed form in the rocks in question.  327  295  476  135  412  145  333  693  913  V  466  103  181  115  110  62  35  109  81  134  147  Zn  320  212  124  88  120  112  121  58  60  157  1678  74  76  Cd  118  Te  64  Yb  318  229  244  222  328  197  216  Pb  29  53  24 Mining 2022, 2 690

Results
The Monchepluton massif in question is an area that was mined in the 20th century. In addition, most of the infrastructure-including the tourist infrastructure-that was built there in the past is now devastated and deteriorating. Given the climatic and environmental conditions, the effects of these activities will be clear for a long time to come. The following describes the characteristics of the mining work carried out in Monchepluton and discusses the characteristics of the soils and vegetation therein.

Characteristics and Present Stage of Recultivation Process
The Monchepluton area was intensively mined in the first half of the 20th century. Numerous traces of mining work date from that time. Mining shafts are visible in the Nittis and Sopcha areas. In the NKT and Nyud massifs, adits, which are partially collapsed, are preserved in varying conditions. Quarries are also visible in these massifs (especially in the N slopes of Sopcha and Nyud) and on the slopes of Nittis, where sulfide veins were explored. In the aforementioned NKT and Nyud massifs, there are numerous heaps of rocks containing ores. In addition, in all of the Monchepluton massifs, earthworks of various scales were carried out, leading to the exposure of rocks and sampling. In the Nittis and Kumuzhia areas, there are ruins of processing plants. Precipitates of copper carbonate and sulfate are often visible in the areas of former adits. Streams flowing from the sites of former adits also often have a color indicative of the metal oxides and hydroxides found in the deposit. In addition, in the area of the northern slopes of Sopcha, a non-ferrous metal smelter still exists, which currently processes ore from Norilsk ( Figure 4). The slag is dumped on a heap that enters the lake, strongly acidifying it, which is visible from a distance by the turquoise-greenish color of the water. The Nittis, Nyud, and Poaz massifs are also home to infrastructure features such as ski lifts and a TV station. In the Nittis area, the ski lift is closed and all its infrastructure is in the undergrowth, while parts of the lift (ropes and fragments of instrumentation) are scattered along the slope. The biggest threat to the environment comprises former adits from which streams leak and heaps of sulfide-containing ore. In addition, a major burden on the ecosystem is the smelter, which releases aerosols and causes acid rain in the area, thereby contributing to the death of forests.

Results' Analysis of Soils and Water Samples
In the massif in question, the initial soils are mostly formed as a result of the mechanical fragmentation of the rocks in the mountain slopes due to the action of frost [25,65]. There are also slag admixtures in the mining area, which were formed as a result of various engineering works, forming difficult, complex vitrified compounds [66][67][68]. Typically, soils in these areas have psammitic and psephitic fractions with varying degrees of clasts, being composed mainly of bedrock minerals possibly enriched with post-glacial material. Stone runes are visible in the summit areas ( Figure 5).
In the saddle zones, which locally drain due to the action of nivation, there are small ponds and, in their vicinity, there are soils formed by the accumulation of silty material. Among these formations, small soils containing fine aleuritic and pelitic facies retained by snow patches were encountered. Some warmer places form raised bogs. The slopes are dominated by rockfalls, landslides, colluviums, debris flows, and illuviums, especially in gullies, where the transport of rock crumbs occurs due to the action of rainwater. In slope break zones, which occur on rock shelves where crumb material can take hold, pioneer vegetation enters the rock, as well as taller vegetation, especially on slopes with southern exposure. In the valley bottoms, there are numerous accumulations of glacial, fluvioglacial, and fluvial characters. These include numerous moraines along with sands, interlocking with colluviums descending from gullies and stagnant forms. They usually produce podzolic soils with a poorly developed humus layer. The humus layer in the soils in question is usually severely reduced. Various types of boulders are visible throughout the massif, formed as a result of the disintegration of rocks on the slopes and occurring as erratics.
Mining 2022, 2, FOR PEER REVIEW 8 of sulfide-containing ore. In addition, a major burden on the ecosystem is the smelter, which releases aerosols and causes acid rain in the area, thereby contributing to the death of forests. exposure. In the valley bottoms, there are numerous accumulations of glacial, fluvioglacial, and fluvial characters. These include numerous moraines along with sands, interlocking with colluviums descending from gullies and stagnant forms. They usually produce podzolic soils with a poorly developed humus layer. The humus layer in the soils in question is usually severely reduced. Various types of boulders are visible throughout the massif, formed as a result of the disintegration of rocks on the slopes and occurring as erratics. The soil samples that were examined ( Figure 2) showed significant proportions of lead, cadmium, copper, chromium, and zinc ( Table 2). These are heavy metals, which in these soils come from the decomposition of mainly admixed ores, which are found in the bedrock. Their presence in the soils taken in the area of valleys with fluvioglacial deposits indicates pollution from anthropogenic activities resulting from mining and processing operations [53][54][55][56][57]. The studies in the micro-area found that sample 01S is rich in plagioclase and possesses a small admixture of clay minerals and sulfates. In sample 02S, in addition to plagioclase and clay minerals, an admixture of nickel and titanium was also found. The content of these metals far exceeds the standards, indicating that this environment is highly polluted with metals [67][68][69][70][71][72][73][74][75]. The reference values of these metals in the soils, water, and plants in the UE are described in the UE Report [76] and other publications [77]. The soil samples that were examined (Figure 2) showed significant proportions of lead, cadmium, copper, chromium, and zinc ( Table 2). These are heavy metals, which in these soils come from the decomposition of mainly admixed ores, which are found in the bedrock. Their presence in the soils taken in the area of valleys with fluvioglacial deposits indicates pollution from anthropogenic activities resulting from mining and processing operations [53][54][55][56][57]. The studies in the micro-area found that sample 01S is rich in plagioclase and possesses a small admixture of clay minerals and sulfates. In sample 02S, in addition to plagioclase and clay minerals, an admixture of nickel and titanium was also found. The content of these metals far exceeds the standards, indicating that this environment is highly polluted with metals [67][68][69][70][71][72][73][74][75]. The reference values of these metals in the soils, water, and plants in the UE are described in the UE Report [76] and other publications [77]. Three water samples from the massif were also examined for comparison. The first was collected near the mine water outflow in the area of the so-called Adit 5.1 in the Traviannaya massif; the second came from Lake Sopcheyavr, located in the central part of the intrusion; and the third from Lake Imandra in the Monchepluton area ( Figure 2, Table 3). The relatively high pH may indicate that from the adit to the water intake site (at its outflow), these waters may have been enriched in carbonate components of Anthropogenic or Holocene origins. The analyses of the water samples from the Monchepluton area were conducted to solve the problem of the influence of anthropogenic factors in the study area [27,29,30,[67][68][69][70][71][72][73][74][75]. The samples were collected from surface waters during the summer (13 July). The ions studied indicate calcium and magnesium content with a significant proportion of sulfate, indicating the influence of sulfide ores on the chemical composition of the waters. The sampling location was determined based on observations of possible exposure to pollutants. This was hypothesized to originate from melting snow, with water flowing from stagnant water and a water supply intake. The content of these components suggests the occurrence of anthropogenic pollution.

Result of the Analysis of the Plant Samples
The Monchepluton hills are small, flattened hills, with a character of separate isolated mountain ranges cut by wide valleys with numerous fleshy postglacial deposits. In the bottoms of these valleys, it is likely that taiga once grew, although due to human activity and the heavy pollution of the area today they are rather desolate wastelands not infrequently populated with stumps of dried trees and presenting numerous rusty patches on the surface of rocks. In the shaded zones of the massif (from the metallurgical combine), one can see a secondary succession of plants with visible small trees such as birch, pine, spruce, and juniper ( Figure 6). The forestation of the farthest massif appears to be in a much better condition: in Vurechuaivench, a lush pine-spruce forest occurs in the valleys, transitioning higher into a forest-tundra with dwarf pine, spruce, birch, and rowan trees. Higher up, dwarf birch, veined willow, and the tundra floor appear. The mosses and lichens that occur in this area form accumulations throughout the area's profile, and in the summit areas, they overgrow in areas where little if any relict soil has formed, while the lichens are usually directly adhered to rocks. These lichens often form quite extensive, characteristic mats covering almost the entire visible surface of the rock (Figure 7). Microscopically magnified preparations show numerous impurities, sometimes contributing to the discoloration of these organisms. Numerous structures of a taxonomic nature (protuberances, discoloration, etc.) are also visible. The mosses and lichens examined are mainly Rhizocarpon and Cladonia sp., which occur mainly on the surface of rocks [31][32][33]. These lichens often form quite extensive, characteristic mats covering almost the entire visible surface of the rock (Figure 7). Microscopically magnified preparations show numerous impurities, sometimes contributing to the discoloration of these organisms. Numerous structures of a taxonomic nature (protuberances, discoloration, etc.) are also visible. The mosses and lichens examined are mainly Rhizocarpon and Cladonia sp., which occur mainly on the surface of rocks [31][32][33].
Analyses of four lichen samples were performed ( Figure 2). The samples are relatively geochemically diverse. Analyzing the following data (Table 4), it can be concluded that in the examined lichens, sometimes quite significant amounts of Ti and Fe, as well as Cu, Ni, Zn, Pb, and Cr, were found, significantly exceeding the background standards.
These lichens often form quite extensive, characteristic mats covering almost the entire visible surface of the rock (Figure 7). Microscopically magnified preparations show numerous impurities, sometimes contributing to the discoloration of these organisms. Numerous structures of a taxonomic nature (protuberances, discoloration, etc.) are also visible. The mosses and lichens examined are mainly Rhizocarpon and Cladonia sp., which occur mainly on the surface of rocks [31][32][33]. Analyses of four lichen samples were performed ( Figure 2). The samples are relatively geochemically diverse. Analyzing the following data (Table 4), it can be concluded that in the examined lichens, sometimes quite significant amounts of Ti and Fe, as well as Cu, Ni, Zn, Pb, and Cr, were found, significantly exceeding the background standards.   The cadmium content in one sample reaches 2 ppm, while the concentration of lead in these samples is more than 100 ppm. Elevated copper, chromium, and nickel contents of sometimes as much as 40-50 ppm were also found in these samples. The manganese content in the two samples is more than 100 ppm and the proportion of titanium can be determined in weight percentages, as in iron. Elevated contents of heavy metals, especially Cr, Ni, Cu, Cd, and Pb, are associated with the weathering zone of sulfides found in the heaps of the sites in question. These values correspond to the measured content of these metals in the soils (see Table 2). It seems that these elements can accumulate in the plants in question.

Discussion
The surveyed area requires a great deal of serious work to be rehabilitated. This contributes to some plant successions in previously devastated areas. Some shafts are still permeable. Their historical value may still be of interest; hence, it may be worth preserving them (so that a museum can be organized there in the future), but they need to be protected from water entering the mine. A major challenge remains regarding the soil. Its self-cleaning process will probably take many years. Another problem is the ruined infrastructure, which will have to be removed, as it poses a danger to both animals and people. Some of the buildings could be used for tourism purposes, but this would require a considerable amount of money for their renovation [45,47,[78][79][80][81][82][83][84][85][86][87][88][89][90]. Left to themselves, they will continue deteriorating. The minimum protection would be to clean the site of the remains of the infrastructure (cables, wires, steel cables, etc.). Securing former surfacemining operations seems to be a separate problem. Quarries could be adequately protected against natural wall-fall processes. With a relatively small financial outlay, they could be adapted for artistic purposes. Such a need is evidenced by the fact that in these mountains there are now numerous trails marked out independently by individuals (marked with paint, old tires, and ribbon trails, shown in Figure 8). In the massifs farthest from the city, wildlife appears, as evidenced by the tracks of bears and other animals visible in the field. Due to climatic conditions and the short vegetative period, the biological reclamation of the area will take many years. natural wall-fall processes. With a relatively small financial outlay, they could be adapted for artistic purposes. Such a need is evidenced by the fact that in these mountains there are now numerous trails marked out independently by individuals (marked with paint, old tires, and ribbon trails, shown in Figure 8). In the massifs farthest from the city, wildlife appears, as evidenced by the tracks of bears and other animals visible in the field. Due to climatic conditions and the short vegetative period, the biological reclamation of the area will take many years.

Conclusions
The Monchepluton area is a series of massifs containing alkaline and ultramafic rocks with Cr-Ti-Fe oxide mineralization and PGE-doped Cu-Ni-Fe sulfide mineralization. They were heavily mined in the 20th century, resulting in numerous mining operations that are still discernable on the ground today. Unprotected shafts, adits, and heaps as well as smoky non-ferrous metal-smelting plants caused an ecological disaster. The composition of the plants indicates elevated levels of heavy metals such as Pb, Ni, and Cu.

Conclusions
The Monchepluton area is a series of massifs containing alkaline and ultramafic rocks with Cr-Ti-Fe oxide mineralization and PGE-doped Cu-Ni-Fe sulfide mineralization. They were heavily mined in the 20th century, resulting in numerous mining operations that are still discernable on the ground today. Unprotected shafts, adits, and heaps as well as smoky non-ferrous metal-smelting plants caused an ecological disaster. The composition of the plants indicates elevated levels of heavy metals such as Pb, Ni, and Cu. Hydrological relations have also been disturbed, and due to the lack of proper protection works, they pose a constant threat. Some mitigation of the negative impact on nature was achieved via the installation of filters on the chimneys of the nonferrous metal smelter. However, further reclamation may be very costly. The most pressing problem seems to be securing the ruins, which pose a threat to humans and animals, as well as cleaning the area. The next step is to secure water relations. The accumulated contamination in the soil and plants will require many more years of work.