Assessment of the Possibility of using Sosnowsky's Hogweed for
Wastewater Treatment in the Arctic
Maria Yurievna Menshakova
1
, Anastasia Verigina
1
and Aiset Shaamanovna Abdulkhazhieva
2
1
Murmansk Arctic State University, Murmansk, Russia
2
Kadyrov Chechen State University, Grozny, Russia
Keywords: Bioplateau, wastewater treatment, invasive species, biogenic elements.
Abstract: The study is devoted to the problem of identifying the most effective plant species for biological wastewater
treatment at high latitudes. For the experiment, Sosnowsky's hogweed was selected, characterized by a high
growth rate and resistance to low temperatures. The ability of Sosnowsky's hogweed to absorb ammonium
ions, nitrate, nitrite, phosphate and chloride ions has been studied. The assessment was carried out in
vegetation vessels with a volume of 5 and 10 liters with sand, filled with sewage water. Wastewater from the
airport in the village of Murmashi was used for the study. It is shown that this species absorbs biogenic
elements from water quite intensively. Nitrogen compounds are most intensively absorbed. It was also found
that the most effective extraction of toxic ions occurs in vessels with a volume of 5 liters, which suggests that
planting plants of this species on a bioplateau can be carried out quite densely.
1 INTRODUCTION
Physical (mechanical), chemical and biological
methods of purification and their combinations are
widely used for wastewater treatment. The choice of
a particular method is due to a number of factors: the
volume of discharge, the composition of pollutants
and the toxicity of waters, the features of the
landscape, the proximity of the water intake.
Economic aspects are also of great importance,
namely, the cost of treatment (Borisova, 2011).
In the process of physical treatment, it is possible
to separate coarse particles, sand, fats and petroleum
products. Chemical purification involves
neutralization (using lime, ammonia or mineral
acids), oxidation (for effluents containing highly
toxic organic compounds) and precipitation (with the
formation of insoluble hydroxides) (Voronov, 2007).
Chemical cleaning often leads to secondary
contamination of the treated waters. Physical and
chemical methods include flotation (passing air
through wastewater separating fine particles),
coagulation (converting dissolved particles into
insoluble form in the form of large flakes separated
by physical methods) and adsorption (binding of
polluting particles to the surface of sorbents)
(Borisova, 2011).
Removal of compounds of biogenic elements
(nitrogen, phosphorus, sulfur) is most advisable to be
carried out by biological methods, since this approach
does not cause secondary contamination with
reagents. Among biological methods, there are
artificial (feasible in special structures aerotanks
and methane tanks) and natural (carried out in natural
depressions of the landscape) – lagoons, bioplateaus,
irrigation fields. Artificial methods are widely used,
and the resulting solid residue has previously been
used as fertilizers. Currently, the possibilities of using
this type of waste are sharply limited, since many
highly toxic substances are found in its composition,
such as pesticides, heavy metals, dioxins (Voronov,
2007).
One of the promising natural methods is
bioplateau, where purification is carried out with the
use of higher aquatic vegetation. For a number of
species, high efficiency in the purification of both
sanitary and industrial waters is shown. The most
promising in this regard are such species as the water
hyacinth (Eichcornia crassipes) (Chen 1992; Chen,
1992a; Fox, 2008), Lemna minor, Pistia floating
(Borzenkov, 2010), Elodea canadensis (Bondareva,
2008; Dunbabin,1992; Ding Yanhua, 1992).
For many sparsely populated territories (workers'
settlements, military units, agricultural enterprises),
the use of traditional types of wastewater treatment is
338
Menshakova, M., Verigina, A. and Abdulkhazhieva, A.
Assessment of the Possibility of using Sosnowsky’s Hogweed for Wastewater Treatment in the Arctic.
DOI: 10.5220/0011571500003524
In Proceedings of the 1st International Conference on Methods, Models, Technologies for Sustainable Development (MMTGE 2022) - Agroclimatic Projects and Carbon Neutrality, pages
338-341
ISBN: 978-989-758-608-8
Copyright
c
2023 by SCITEPRESS Science and Technology Publications, Lda. Under CC license (CC BY-NC-ND 4.0)
extremely expensive, since the construction of
sewage treatment plants, even for small volumes of
discharge, is estimated at tens of millions of rubles,
and the construction of bioplateaus and lagoons does
not require large expenditures (Direnko, 2006).
2 MATERIALS AND METHODS
The studies were carried out on the wastewater of the
Murmashi airport, located in the Murmansk region.
The airport is located at a considerable distance from
the village of Murmashi and cannot be connected to a
centralized wastewater disposal and wastewater
treatment system. The effluents are dominated by
ions of biogenic elements.
Young balsam plants having 1 pair of true leaves
were planted in washed coarse sand in vegetative
vessels with a volume of 2, 5 and 10 liters and filled
with sewage water to the mark. The plants were
vegetated for a week under a canopy made of
polyethylene film to prevent dilution of water in the
vessels with rainwater. To account for the
evaporation of water by leaves after exposure, the
water in the vessel was topped up to the mark with
distilled water, after which water was used in the
vessel for analysis.
The ion content was determined
spectrophotometrically:
The content of ammonium ions was determined
using a Nessler reagent, the selective absorption of
infrared radiation of the solution was measured at a
wavelength equal to 425 nm in cuvettes, the
absorption wavelength of the layer of which is 1 or 5
cm.
The phosphorus content was determined using
ammonium molybdate at a wavelength of 690 nm
The content of nitrate ions was determined using
salicylic acid at a wavelength of 690 nm in cuvettes
with a thickness of 20mm, and nitrite ions using
sulfanylic acid at a wavelength of 520 nm.
The content of chloride ions was determined
titrimetrically using a silver nitrate solution
Sosnowsky's hogweed (Heracleum sosnowsky) is
a representative of the genus Hogweed Heracleum
of the Apiaceae (Umbelliferae) family –a south-
temperate Caucasian species adventitious for the
north, which escaped from cultivation and is now
found in a wide variety of plant communities,
currently not only Sosnowsky's hogweed lives in the
Murmansk region, but also various interspecific
hybrids (Menshakova, 2011), showing weak
phytotoxicity and allelopathic activity (Menshakova,
2013).
3 RESULTS AND DISCUSSION
The results of the experiment on the efficiency of
absorption of anions from wastewater by
Sosnowsky's hogweed are presented in Tables 1 and
2. Just as in the experiment with Impatiens roylei in
all variants of the experiment, in vegetative vessels of
various volumes, a decrease in the concentration of
chlorides, phosphates, ammonium nitrogen, nitrates
and nitrites is observed in an aqueous solution. The
greatest absorption by the roots of the plant occurred
in vessels with the smallest volume (except
ammonium). The concentration of chloride anions in
vessels with a volume of 10 liters decreased by 2
times, while in vessels with a volume of 5 liters by
almost 9 times. The content of phosphates in water in
the variant of the experiment with vegetative vessels
with a volume of 10 liters decreased slightly,
interestingly, the concentration in vessels with a
volume of 5 liters increased slightly. Also of
particular interest are the concentrations of nitrates in
vessels of 10 liters and 5 liters, which decreased by 3
times.
Nitrite anions were most actively absorbed.
Table 1: Concentration of anions in an aqueous solution in the experiment with Sosnowsky's hogweed before and after the
experiment (first sampling).
Volume
vessel, l
Average chloride
concentration,
mg/l
3
Average
phosphate
concentration,
mg/l
3
Average
ammonium
nitrogen
concentration,
mg/l
3
Average nitrate
concentration,
mg/l
3
Average nitrite
concentration,
mg/l
3
10 47.96 0.172 1.06 5.2866 0.036
5 8.19 0.195 0.67 5.785 0.0112
Concentration of
anions before the
experiment
73.40 0.186 14.86 16.155 0.458
Assessment of the Possibility of using Sosnowsky’s Hogweed for Wastewater Treatment in the Arctic
339
Table 2: Concentration of anions in an aqueous solution in the experiment with Sosnowsky's hogweed before and after the
experiment (second sampling).
Volume
vessel, l
Average chloride
concentration,
mg/l
3
Average
phosphate
concentration,
mg/l
3
Average
ammonium
nitrogen
concentration,
mg/l
3
Average nitrate
concentration,
mg/l
3
Average nitrite
concentration,
mg/l
3
10 16.37 0.154 0.284 5.083 0.0147
5 11.73 0.082 0.147 1.136 0.004
Concentration of
anions before the
experiment
75.15 0.088 10.25 25.98 0.687
Concentrations in vessels with a volume of 5 liters
decreased by 41 times, while in vessels with a volume
of 10 liters by 11 times.
Analyzing the data, it can be concluded that
Sosnowsky's hogweed in the vegetative period most
actively absorbs nitrate and ammonium ions.
Interestingly, the concentration of phosphate ions in
vessels with a volume of 5 liters increased, while
vessels with a volume of 10 liters decreased
During repeated sampling, the content of chloride
anions, ammonium ions, nitrates and nitrite ions in
the aqueous solution turned out to be less than during
the primary sampling, in all variants of the
experiment. The content of chloride anions turned out
to be lower in the secondary sampling from vessels
with a volume of 5 liters. The concentrations of
phosphate anions in vessels with a volume of 10 liters
were lower in the first experiment, but the
concentration in a vessel with a volume of 5 liters
became lower in the secondary sampling (Table 2).
From the data in Tables 1 and 2, it can be seen that
the roots of the plant absorbed anions, and it can also
be concluded that during the growing season,
Sosnowsky's hogweed most actively absorbs
ammonium and nitrate ions. Interestingly, in a vessel
with a volume of 10 liters, the hogweed began to give
off phosphate ions, which caused an increase in the
concentration of these ions.
It can be concluded that hogweed exhibits the
ability to absorb most actively in vessels with the
smallest volume.
4 CONCLUSION
1. As a result of the study, it can be concluded that
Sosnowsky's hogweed has a pronounced ability
to absorb toxic anions.
2. The roots of the Sosnowsky's hogweed most
actively absorb during the flowering period:
nitrate-, nitrite-ions and ammonium ions,
chloride ions, except for vessels with a volume
of 10 liters, phosphate ions, except for vessels
with a volume of 5 liters.
3. The root system of the Sosnowsky's hogweed
most actively absorbs toxic ions in vessels with
the smallest volume.
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