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Author(s): Petra Lindholm-Lehto 
Title: Water quality monitoring in recirculating aquaculture systems 
Year: 2023 
Version: Published version 
Copyright:   The Author(s) 2023 
Rights: CC BY 4.0 
Rights url: http://creativecommons.org/licenses/by/4.0/ 
 
Please cite the original version: 
Lindholm-Lehto, P. (2023) Water quality monitoring in recirculating aquaculture systems. 
Aquaculture, Fish and Fisheries, 00, 1– 19. https://doi.org/10.1002/aff2.102 
Received: 17 November 2022 Revised: 12 January 2023 Accepted: 5 February 2023
DOI: 10.1002/aff2.102
R E V I EW
Water qualitymonitoring in recirculating aquaculture systems
Petra Lindholm-Lehto
Natural Resources Institute Finland (Luke),
Aquatic Production Systems, Jyväskylä,
Finland
Correspondence
Petra Lindholm-Lehto, Natural Resources
Institute Finland (Luke), Aquatic Production
Systems, Survontie 9A, FI-40500 Jyväskylä,
Finland.
Email: petra.lindholm-lehto@luke.fi
Funding information
NordForsk: Sustainable
Aquaculture–Research and Innovation
Projects, Grant/Award Number: No.102714
Abstract
Good water quality in recirculating aquaculture systems (RAS) is crucial for ensuring
the successful growth and survival of reared species. So far, there are no regulations for
which parameters should be measured in RAS, and each farmer decides which param-
eters to follow. Traditionally, water quality parameters have been measured at certain
intervals with handheld sensors and laboratory analyses, which can be labour inten-
sive. Currently, a variety of sensors and monitoring equipment is available, even for
the real-time monitoring of water quality parameters. Internet of Things-based sys-
tems and artificial intelligence can be applied for themonitoring purposeswhich allows
real-time measurements and warnings of critical situations. However, many of the
modern systems need competent users and require regular maintenance and calibra-
tion. Changes inwater quality also induces changes in fish behaviour, such as swimming
activity, depth, acceleration and water quality can be assessed also based on these
changes. In this review, water quality parameters, variety of sensors and monitoring
technologies have been summarised to provide an overview of the current monitoring
systems for water quality. Additionally, analytical methods for more advanced analy-
ses have also been briefly summarised. Although there are several advanced options
available for monitoring the basic water quality parameters, real-time measurements
of more advanced parameters still required require further development.
KEYWORDS
aquaculture, fish behaviour, Internet of Things (IoT), monitoring equipment, recirculating aqua-
culture systems (RAS), water quality
1 INTRODUCTION
Recirculating aquaculture systems (RAS) are land-based intensive
aquaculture systems where water is re-used typically via mechanical
and biological treatment to reduce the consumption of water and yet
maintain adequate water quality (Martins et al., 2010). RAS utilises
modern knowledge of biology, environmental sciences, mechanical
engineering and information technology (Xiao et al., 2019). Circulating
water is reused multiple times, and only a small proportion is replaced
with clean water (Chun et al., 2018). Currently, variety of freshwater
This is an open access article under the terms of the Creative Commons Attribution License, which permits use, distribution and reproduction in any medium, provided
the original work is properly cited.
© 2023 The Authors. Aquaculture, Fish and Fisheries published by JohnWiley & Sons Ltd.
and marine species from hatchery to grow-out is reared in RAS. RAS
have been used for several decades for fish production, although only a
few very large (production over 10 million kg per year) systems are in
operation (Molleda, 2007).
The idea of RAS originates from Japanese biological purification in
the 1960s (Wu et al., 2008; Lin, 2011; Xiao et al., 2019). Since the
1990s, biological engineering, automation control, bottom discharge
and controls of dissolved oxygen (DO) and temperature have been
employed. Currently, the development of RAS focuses on improving
of water purification technology and equipment, sustainability and the
Aqua. Fish & Fisheries. 2023;1–19. wileyonlinelibrary.com/journal/aff2 1
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2 LINDHOLM-LEHTO
level of wastewater discharge (Becke et al., 2019). However, since RAS
are often energy and cost intensive, and suggestions have been made
to improve their economy.
Water quality can be divided into categories which include phys-
ical parameters, organic contaminants, biological contaminants and
pathogens (Su et al., 2020). Physical parameters depend on climate
and the surrounding conditions. Water quality control is a key aspect
in any aquaculture management, but especially in RAS, where the
water is circulated in the system. The main parameters for quality
monitoring include pH, temperature, oxidation–reduction potential
(ORP/Redox), turbidity, salinity and DO. In the ideal range, water qual-
ity can enhance the fish growth rate and reduce the occurrence of fish
diseases (Stigebrandt et al., 2004; Tolentino et al., 2021). Technolo-
gies suitable for rapid, real-time and automated monitoring and data
storing are therefore greatly needed.
Water quality in RAS is affected by feed loading and composition
(Blancheton et al., 2013; vonAhnen et al., 2015). Dissolved compounds
and particulate matter can be difficult to remove from the system
and they can act as substrate material for bacterial growth. Some of
thesebacterial species can induceoff-flavours in the system (Lindholm-
Lehto et al., 2019; Suurnäkki et al., 2020). A high abundance of bacteria
can also affect the fish, acting as pathogens or competing for oxygen
(Michaud et al., 2014).
In RAS, water quality parameters are kept stable to ensure suit-
able conditions for the fish (Rojas-Tirado et al., 2018). It is therefore
important to understand and control factors that change the water
quality. Water quality needs to be monitored closely to maintain opti-
mal growth conditions in RAS (Naughton et al., 2020). In RAS, fish are
often reared in high densities, causing a build-up of organic material
and nutrients (Bentzon-Tilia et al., 2016). These factors need to be con-
trolled and monitored, but the available tools are often complex or
include a considerable lag between sampling and the results (Rojas-
Tirado, 2018). There are no regulations concerning which parameters
to measure and each farmer has their own view of and possibilities for
water quality measurements. Additionally, there are no guidelines for
acceptable ranges and fluctuations.
Previous articles have comprehensively studied and discussed
fish health, stress levels, diseases (Venugopal, 2002; Endo & Wu,
2019), pathogens (Adams & Thompson, 2011) and exposure to envi-
ronmental contaminants such as polycyclic aromatic hydrocarbons
(Srogi, 2007) and cyanotoxins (Vogiazi et al., 2019). Additionally,
analytical technologies and biosensors used in aquaculture have
recently also been reviewed (Hu et al., 2020; Su et al., 2020). How-
ever, a comprehensive study of current sensors, monitoring equip-
ment and the typically monitored water quality variables has been
missing.
In this study, it was hypothesised that only the very basic water
quality parameters are typically monitored in commercial RAS, possi-
blywith very traditionalmonitoringmethods.However, in recent years,
new possibilities are available due to many technical innovations. This
reviewaims at (1) combining new technologies available formonitoring
of water quality by using the most modern information technologies,
(2) listing the technology-based possibilities in prediction of detrimen-
tal occurrences in water quality and (3) presenting which parameters
can be measured by the modern online-measurement tools and which
still needmore advanced laboratory analyses. All this might encourage
adopting newmeasurement equipment formonitoring ofwater quality
at commercial aquaculture facilities.
2 WATER QUALITY PARAMETERS
In aquaculture, several parameters need to be monitored and mea-
sured to understand the aquatic conditions (Tziortzioti et al., 2019).
These include pH, temperature, DO, salinity and turbidity (Mwegoha
et al., 2010). DO is themost crucial parameter for aquatic species. Oxy-
gen is not readily soluble in water, and its ability to dissolve decreases
rapidly as the temperature and salinity increase (Timmons et al., 2018;
Chumkiew et al., 2019).
The fluctuation of physical parameters directly affects the health,
growth and feed utilisation of the raised species. For example, DO
affects feed consumption, feeding efficiency, metabolism and growth
in fish (Buentello et al., 2000; Zhang et al., 2011). Fish use oxygen to
convert feed to biomass and depending on the species, varies from
5 mg L−1 (warm water species) to 7 mg L−1 (cold water species) (Pil-
lay & Kutty, 2005). However, some species (silver catfish, Rhamdia
quelen) can tolerate DO levels below 3 mg L−1 but DO levels below
5 mg L−1 affect their behaviour, survival and growth (Braun et al.,
2006). For salmonids, oxygen saturation should be at least at 70–80%
(above 6mg L−1). Fluctuations or suboptimal temperatures affect feed
use (lower FCR at temperatures above optimal, Timmons et al., 2018)
and induce stress which can lead to disease outbreaks. Additionally,
organic material consumes oxygen (biological oxygen demand, BOD)
via bacterial degradation.
Water conductivity is related to the ionic content ofwater and salin-
ity, but it alsodependson temperatureandpressure (for a1◦C increase,
conductivity increases by 2–4%) due to increased ion mobility and
solubility (Tziortzioti et al., 2019). Hydrogen ion concentration and rel-
ative acidity are measured as pH. Aquatic species generally require
a neutral pH, but for example, the optimum pH for chichlids (Cich-
lidae; Takahashi-Kariyazono et al., 2017) and for tilapia (Oreochromis
sp.; Milud et al., 2013) can be in mildly basic conditions. A biofilter
achieves its best performance in mildly basic conditions. The pH can
be affected by, for example, bacteria, CO2 content and chemicals in
the system.Water with a low pH can be harmful to aquatic species but
can also corrode pipes or release lead, cadmium, copper and zinc into
water.
Turbiditymeans the degree of cloudiness inwater due to suspended
organic or inorganic particles (silt, clay, organic matter, plankton, etc.)
and is a valuable parameter for evaluating water quality (Tziortzioti
et al., 2019). The degree of turbidity is based on scattering of light
from the suspended particles. High turbidity reduces the depth of light
can penetrate which can prevent or decrease the efficiency of UV light
treatment.
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LINDHOLM-LEHTO 3
2.1 Nitrogen species
In RAS, nitrogen compounds can accumulate in water (ammonium-N,
nitrite), which are toxic to fish even at low concentrations (Timmons
et al., 2018). Intensified production in RAS leads to an increase in
dissolved waste, including ammonia (NH3) (Ip et al., 2001). Ammonia
(NH3) is highly toxic to fish and can deteriorate gills and result in mor-
tality (Wicks et al., 2002). Typically, the upper safe limit for NH3-N for
salmonids is 0.0125mg L−1 (Timmons et al., 2018).
Ammonia can exist in two forms: NH3 and in the ionised form
NH4
+, which are in equilibrium in water based on temperature and pH
(Timmons et al., 2018). Together, they are referred to as total ammo-
nia nitrogen (TAN). The proportion of free ammonia (NH3) increases
with increasing temperature and pH. Fish excrete nitrogen mainly
as ammonia-N (53–68%), but also as urea-N (6–10%), amino acids
(4–10%) and as protein (3–11%) (Kajimura et al., 2004). Fish have
varying tolerance of ammonia-nitrogen, depending on species, age
and physiological status. For example, adult fish are more tolerant to
ammonia than juveniles and fingerlings (Dauda et al., 2019). Gener-
ally, levels of ammonia below 1 mg L−1 and of TAN below 5 mg L−1
are recommended (Table 1) (Boyd, 2003; Ajani et al., 2011). However,
in some studies, increased concentrations of ammonium have been
beneficial in terms of growth rate and sublethal NH3-N (Kolarevic
et al., 2013).
In RAS, ammonia is converted by certain bacteria to less toxic nitrite
(ammonia-oxidising bacteria: AOB, e.g., Nitrosomonas) and further to
nitrate (nitrite-oxidising bacteria: NOB, e.g., Nitrospira, Nitrobacter) via
nitrification process which allows lower water use rates (Suurnäkki
et al., 2020). Typically, this is performed in nitrifying bioreactors, such
as moving bed bioreactors (Kamstra et al., 2017) or fixed bed biore-
actors (Pedersen et al., 2015) where biofilm containing the nitrifying
bacteria, is formed on plastic carrier material or on natural material,
such as sand particles.
Nitrite is toxic to fish, and concentrations below 0.5 mg L−1 are
recommended (Ajani et al., 2011). Nitrate is a less toxic oxidation
product, and most fish species can tolerate levels up to 200 mg L−1
(Dauda & Akinwole, 2015), although NO3-N concentrations of 100–
1000 mg L−1 are not uncommon (Preena et al., 2021). However, high
concentrations of nitrate can inhibit fish growth and increase mortal-
ity (Table 1) (Davidson et al., 2014). Typically, nitrate concentrations
in RAS are controlled by adjusting the water exchange rate and biofil-
ters, adding denitrification, or even phytoremediation into the system
(Martins et al., 2010; Schipper et al., 2010; Pulkkinen et al., 2021).
Fish feeds and feed load are important factors when dimensioning
ammonia removal capacity in RAS. TAN production in fish depends on
the feeding interval (Pedersen et al., 2012) and digestibility (Médale
et al., 1995) and it may increase if the amino acid profile in the fish feed
is not balanced (Bureau & Hua, 2010). It is beneficial to disperse the
feed throughout the day in RAS to ensure a steady ammonia load into
the bioreactors.
The feed loading (kg feed per m3 make-up water) reflects the inten-
sity of recirculationwhich is themain critical parameter that influences
water quality deterioration (Pedersen et al., 2012). Upper limits of feed
loading are determined based on the raised fish species, the prevail-
ing environmental conditions, the type of feed and the used water
treatment equipment. Higher feed loads are possible with increased
biofilter nitrification capacity, when fish performance is not restricted
by nitrate accumulation or by deteriorated water quality in general
(Davidson et al., 2011a). For example, declined health of rainbow trout
(Oncorhynchusmykiss) and increasedmortalitywere observed in a com-
mercial RAS with 1.3–2.0 kg m−3 feed loads (Davidson et al., 2009). At
very high feed loads, even abnormal swimming behaviour, side swim-
ming and deformities in rainbow trout have been observed (Davidson
et al., 2011b).
When aiming for very low water exchange rates in RAS or even
zero-discharge systems, nitrate need to be removed from the system.
Nitrogen removal is most commonly achieved via heterotrophic deni-
trificationwhich converts nitrate tonitrogengas anduses carbonas the
electron donor and for microbial growth (Schipper et al., 2010). There
are other options for denitrification, such as anaerobic ammonium
oxidation (Anammox) and chemo-autotrophic denitrification (Burgin
& Hamilton, 2007). Additionally, biofloc system or biofloc technology
absorbs inorganic nitrogen from the circulating water and improves
water quality. In Biofloc system, microbial protein is produced for the
raised species which improves feed conversion ratio, FCR (Khanjani &
Sharifinia, 2020). Biofloc has been widely studied in recent decades
for example in shrimp and finfish farming (Abbaszadeh et al., 2019;
Ebrahimi et al., 2020).
Aquaponic systemsare also able to removenitrogen species via den-
itrification and utilise nitrogen formed in aquaculture for the needs
of plant growth (Wongkiew et al., 2017). Denitrification is carried out
in anoxic conditions by various archaea and heterotrophic bacteria,
such as Aerobacter, Acinetobacter and Pseudomonas (Wonkiew et al.,
2017). Organicmaterial in circulatingwater acts as electron donor and
the source of carbon. However, sufficient carbon source need to be
maintained to avoid accumulation of intermediate products NO and
N2O.
Themost detrimental problems experienced in RAS have been asso-
ciated with both low DO and high concentrations of metabolic waste,
such as TAN, ammonia (NH3-N), nitrite (NO2-N) and CO2 (Molleda,
2007). Typically, fish produce 1.0–1.4 mg L−1 TAN, 13–14 mg L−1 CO2
and 10–20mg L−1 total suspended solids (TSS) per every 10 mg L−1 of
consumedDO (Hagopian & Riley, 1998;Molleda, 2007).
2.2 Carbon dioxide
Carbon dioxide (CO2) is toxic to fish and is a limiting factor in intensive
systems. In RAS, fish density is much higher than with more traditional
aquaculture methods. High fish density leads to a significant increase
in CO2 content in water. Additionally, nitrifying bacteria produce CO2
in nitrification (Xiao et al., 2019). A high CO2 level in water reduces
the diffusion gradient between fish blood and water, resulting in blood
acidification and reduction in oxygen uptake (Sanni & Forsberg, 1996;
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4 LINDHOLM-LEHTO
TABLE 1 Limit concentrations of alkalinity (mg L−1), CO2 (mg L
−1), DO (mg L−1), H2S (µg L−1), nitrogen species (mg L−1), pH, selectedmetals
(µg L−1) and temperature (◦C)
Parameter Limit concentration Species/additional info References
Alkalinity (as CaCO3),
mg L−1
50–300
70–200
Atlantic salmon Timmons et al. (2018)Summerfelt
et al. (2015)
CO2, mg L
−1 15–20
7–10
<20
<80
Salmonids in freshwater;
salmonids in seawater-
sensitive species, salmonids-
tolerant species, tilapia
Molleda (2007)Timmons et al.
(2018)
Dissolved oxygen (DO),
mg L−1
6–9 (70–80%)
<5 (70%)
Molleda (2007)Timmons et al.
(2018)
H2S, µg L−1 2
5
In freshwater
in marine
Hjeltnes et al. (2019)
Sommerset et al. (2020)
NO3-N, mg L
−1 100
200
0–400
Chen et al. (2002)Molleda
(2007)Timmons et al. (2018)
NO2-N, mg L
−1
<0.1
0.1
In soft water Timmons et al. (2018)
NH3-N, mg L
−1 0.03
0.32
2.2
<0.0125–0.03
Arctic charr;
rainbow trout;
common carp
salmonids
Molleda (2007)Timmons et al.
(2018)Summerfelt et al. (2015)
TAN (NH3-N+NH4-N),
mg L−1
<1.0
<3.0
Long-term, cool-water fish
warm-water fish, Arctic charr
Molleda (2007)Timmons et al.
(2018)
Temperature, ◦C <15
15–20
>20
14–16
28–32
Cold-water species
cool-water species
warm-water species
rainbow trout
tilapia
Timmons et al. (2018)
pH 4.2
6.5–8.5
Rainbow trout, roach LC 8-daymedian
general suitable pH range
Alabaster and Lloyd
(1980)Timmons et al. (2018)
Cadmium (Cd), µg L−1 11 Salmonid juveniles and adults, (hardness
4mg L−1 as CaCO3)
Alabaster and Lloyd (1980)
Copper (Cu), µg L−1 5.0
<30
Rainbow trout (hardness 10mg L−1 as
CaCO3)
Alabaster and Lloyd
(1980)Davidson et al. (2009)
Zinc (Zn), µg L−1 30
<269
Salmonids (hardness 10mg L−1 as CaCO3) Alabaster and Lloyd
(1980)Davidson et al. (2009)
Molleda, 2007). Fish ventilate CO2 via the gills as molecular CO2 gas,
which forms carbonic acid H2CO3, bicarbonate (HCO3
−) and carbon-
ate (CO3
2−) in water which are in equilibrium, based on pH and partial
pressure ofCO2 (Fig. 1) (Boyd, 2000;Molleda, 2007). For rainbow trout
(Oncorhynchus mykiss), excretion of CO2 has been estimated to 1–2mg
CO2 kg
−1 min−1. Typically, a limit value for CO2 is 20 mg L
−1 in water,
but tilapia (Oreochromis niloticus), for example, can tolerate as much as
60mgCO2 L
−1 (Timmons et al., 2018).
Excessively high concentrations can damage the respiratory system
of fish or even result in mortality (Fivelstad et al., 2003) and decrease
biofilter efficiency (Ren, 2014; Xiao et al., 2019). Removal of CO2 also
affects thewater pH. For example, an 80% decrease of CO2 can lead to
a significant increase of pH (Chen et al., 2009). The rate ofCO2 removal
is affected by the initial CO2 content, water flow, gas-water volume
ratio, type and structure of equipment and the inlet air flow rate (Gong
et al., 2017).
F IGURE 1 Mole fractions as a function of pH on proportions of
CO2, HCO
3− and CO3
2− (Boyd, 2000;Molleda, 2007).
Over the years, a variety of equipment has been used for CO2
removal. CO2 degassing towers have been used since the 1980s and
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LINDHOLM-LEHTO 5
their effect has been evaluated by (Summerfelt et al., 2003). Addition-
ally, the injection of micron-sized air bubbles into a foam fractionator
increases aeration and CO2 removal (Barrut et al., 2013). For example,
an airlift pump with CO2-stripping can remove 13-20 g CO2 kWh
−1
(Loyless & Malone, 1998) and paddlewheels 1.2 kg CO2 kWh
−1
(Eshchar et al., 2003).
2.3 Alkalinity
Total alkalinity is described as the concentration of bases in water
which can react with a hydrogen ion (H+). Several compounds can
react in water with hydrogen ion and the total alkalinity describes the
contribution of different ions to alkalinity (Boyd et al., 2016). How-
ever, in natural waters alkalinity ismostly derived fromHCO3
−, CO3
2−
and OH− (Eq. 1, Boyd et al., 2016). Traditionally, alkalinity has been
expressed as mg CaCO3 L
−1 because alkalinity mainly originates from
limestone (mixture of CaCO3 and MgCO3) or as milliequivalents per
litre of calciumoxide (CaO). Limestone composition varies fromCaCO3
(calcite), MgCO3⋅CaCO3 (dolomite) to mixture of CaCO3 and MgCO3
(Boyd et al., 2016). Besides alkalinity, limestone is a major source of
hardness, the term used to describe the ability of water to precipitate
soap and defined as the concentrations of primarily calcium (Ca2+) and
magnesium (Mg2+; Timmons et al., 2018).
Alkalinity =
[
HCO−3
]
+ 2
[
CO2−3
]
+
[
OH−
]
−
[
H+
]
(1)
Alkalinity is also connected to buffering capacity. A buffer includes
a mixture of a weak acid and its conjugate base (salt) or a weak base
and its conjugate acid, such as acetic acid and its conjugate base sodium
acetate or ammonium hydroxide and its conjugate acid ammonium
chloride (Boyd et al., 2016). Dissolved CO2, HCO3
− and CO3
2− buffer
water against sudden changes in pH and water with low alkalinity will
lead to greater fluctuation in pH (Boyd et al., 2016).
The pH of most freshwaters is based on HCO3
− ions and dissolved
acid CO2 from air, excluding effects of biological activities and pol-
lution. Typical alkalinity in freshwater ranges from below 5 mg L−1
to over 500 mg CaCO3 L
−1, based the geology of the aquifer, while
the alkalinity of seawater is about 120 mg CaCO3 L
−1 (Timmons
et al., 2018).
In aquaculture, acids and bases may be added in circulating water
which leads to change in alkalinity andpH.Forexample, removal ofCO2
from water increases pH, and at pH 8.3 the concentration of CO2 is
reduced tonegligible (Boydet al., 2016). Besides total alkalinity andpH,
concentrationof dissolvedCO2 is affectedby temperate; its concentra-
tion decreases with increasing pH and temperature. Variety of bases,
for example, CaCO3, Na2CO3 and NaOH, can be added as alkalinity
supplements (Timmons et al., 2018).
Maintaining adequate alkalinity concentrations has been reported
to be critical for nitrification. For example, alkalinities of 40–80 mg
CaCO3 L
−1 have been reported for wastewater. For aquaculture, Chen
et al. (2006) recommend maintaining an alkalinity level at 200 mg
CaCO3 L
−1 to support nitrification. Summerfelt et al. (2015) suggested
alkalinity of 70 mg CaCO3 L
−1, while a wide range of 50–300 mg
CaCO3 L
−1 has also been reported (Timmons et al., 2018).
2.4 Temperature
Each aquaculture farm has a unique optimum temperature range. Fish
can be classified into three classifications depending on their temper-
ature preference: cold-water, cool-water and warm-water species. For
cold-water species, optimum water temperatures are below 15◦C, for
cool-water species between 15 and 20◦C, and for warm-water species
above 20◦C (Timmons et al., 2018, Table 1). Temperature affects the
physiological processes of the reared species, such as respiration rate,
efficiency of feeding, growth, behaviour, reproduction and depuration
(Drake et al., 2010). Additionally, several factors affect the tolerance
of fish to different temperatures, including species, age, size and past
thermal history (Timmons et al., 2018).
In RAS, temperature should be measured from several locations
such as in rearing tank water and slaughtered fish (Lekang, 2013).
Especially, measurement of inlet water temperature is important for
designing and selecting a suitable heating equipment and for oper-
ating a RAS. The control of rearing temperature allows maintaining
good rearing conditions for optimum growth and feed utilisation,
although the inlet water temperature may vary considerably between
seasons (Dalsgaard et al., 2013). A monitoring equipment based
on a programmable logic controller (PLC) for real-time monitoring
of recirculating water and water level was reported by Wu et al.
(2011). On the other hand, water source heat pumps generate low-
grade heat from natural sources and can be used for heating and
cooling.
For heating, four different heating methods are typically used; boil-
ers, geothermal energy, factory waste heat and heat pumps or other
equipment (Xiao et al., 2019). Industrial heat is limited by geographical
conditions. Heating by boilers is common, but increasing attention to
environmental pollution is likely to reduce the attractiveness of boiler
heating. So far, only a limited number of studies have been related to
temperature control in RAS (Good et al., 2011; Davidson et al., 2014;
Xin et al., 2017).
Water source heat pumpshavebeenused toheat aquaculturewater
and to maintain stable temperature around the year (Xin et al., 2017),
while Good et al. (2011) used a heat exchanger in RAS rearing rain-
bow trout (O. mykiss) and Davidson et al. (2014) a geothermal heat
exchanger. Geothermal energy has been used for heating in RAS farms
producing salmon, trout, tropical fish, lobsters, shrimp and prawns
(Ragnarsson, 2014). Waste heat from industry has been used for com-
mercial oyster, penaeid shrimp and salmon farming (Rickard, 1998),
while heat from power plants has been used for eel and salmonid
fingerlings production (Lemercier & Serene, 1980; Ingebrigtsen & Tor-
rissen, 1980). Additionally, ground heat has been used as a heat source
for temperature control in RAS (Jiang et al., 2017). In recent years,
there has been interest in solar technologies to maintain selected
water temperature in RAS, but only a simulationmodel regarding solar
heating systems in RAS has so far been published (Fuller, 2007).
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6 LINDHOLM-LEHTO
2.5 Salinity
Salinity represents a content of dissolved salt in water, including
calcium, sodium, potassium, bicarbonate, chloride and sulphate ions
(Timmons et al., 2018).Water is commonly described as fresh, brackish
or saltwater based on its salinity.
Cl− and Na+ ions are predominant in sea water, while carbonates
and HCO3− in fresh water. Typically, sea water contains 35 g L−1 salt
(mainly 77.8%NaCl and 10.9%MgCl2; Boeuf & Payan, 2001). It ismore
difficult to determine general values for fresh water, but 0.32 g L−1
(35.1% CO3
2−, 20.4% HCO2
3−, 12.1% SO4
2−, 11.7% SiO2 and 5.8%
Na+) have been reported (Boeuf & Payan, 2001).
Fish maintain concentrations of dissolved salts in their body fluids
via osmoregulation by regulating the uptake of ions from the environ-
ment and through the restriction of ion loss (Timmons et al., 2018). For
example, the best salinity range on growth for Atlantic salmon Salmo
salar is 22–28 ppt or g L−1 (0–35 tolerated), 8 for tilapia O. niloticus
(0–16 tolerated) and 0 g L−1 for rainbow trout O. mykiss (0–34 tol-
erated) (Boeuf & Payan, 2001). Most freshwater fish reproduce and
grow well at salinities up to at least 4–5 g L−1. Freshwater aquacul-
ture systems are generally maintained at 2–3 g L−1 salinity (Timmons
et al., 2018).
Seawater RAS may have higher operating costs compared with
freshwater or brackish water RAS because of the lower efficiency of
CO2 (Moran, 2010) and ammonia removal in seawater and require-
ment to increased scale of equipment (Bakke et al., 2017). On the
other hand, problems related to accumulationof off-flavours havebeen
observed less often in saline water (15–33 g L−1; Tucker, 2000).
Salinity affects reaction rates for ammonia oxidising (AOB) andNOB
in brackish or saltwater conditions (NaCl above 5 g L−1; Kinyage et al.,
2019). At very low salinity, NaCl below 3.7 g L−1, only minor effects
have reported whereas complete inhibition was observed at a salinity
of NaCl above 24 g L−1 (Cortés-Lorenzo et al., 2015).
Feed intake, feed conversion and growth rate are improved in brack-
ish conditions (8–20 g L−1) due to reduced energy expenditure on
osmoregulation and lower standard metabolic rate (Árnason et al.,
2013). Furthermore, brackish water (12 g L−1) combined with mod-
erate exercise (water velocity of minimum 1 body lengths s−1) has
shown a positive effect on salmon growth, survival and welfare in RAS
(Ytrestøyl et al., 2020).
2.6 Hydrogen sulphide
The smell of hydrogen sulphide (H2S) resembles rotten eggs. It is highly
soluble in water (4000 mg L−1 at 20◦C (Barton et al., 2014). H2S
gas is also colourless, somewhat heavier than air (1.19 at 15◦C) and
flammable (Rubright et al., 2017). In water, H2S equilibrates with bisul-
phide (HS−) and sulphide (S2−) (Eq. 2). H2S and S
2− are toxic, whileHS−
is not (Tanudjaja, 2021). The dissociation ofH2S greatly depends onpH,
andHS− formation begins at pH 5 (Fig. 2). In marine water systems, pH
below6.8 is amatter of concern due to sulphides, which can trigger the
production of H2S (Rojas-Tirado, 2018).
H2S (g)⇔H2S (aq)⇔HS
−
+H+ ⇔ S2− + 2H+ (2)
H2S is toxic to all aquatic species at very low concentrations (Lien
et al., 2022). Long-termexposure can cause growth reduction andgreat
stress on fish due to disruption of the respiration process and cellular
anoxia (Kiemer et al., 1995). In marine water, sulphate concentration
is about 1000 times higher than in freshwater (Letelier-Gordo et al.,
2020), which can lead toH2S formation.Marine RAS are therefore vul-
nerable to H2S outbreaks. In recent years, H2S poisoning has caused
severe fish mortalities and resulted in high economic losses (Hjeltnes
et al., 2019; Sommerset et al., 2020).
Although H2S is known to be toxic, toxicity levels have not been set
by the authorities. However, for freshwater species, over 2 µg L−1 and
marine species, over 5 µg L−1 are not recommended (Table 1) (Boyd,
2014; Hjeltnes et al., 2019; Sommerset et al., 2020). The 96-h lethal
concentration for H2S in freshwater ranges from 20 to 50 µg L−1, and
in amarine environment from 50 to 500 µg L−1 (Boyd, 2014).
H2S poisoning occurs and harms the fish quickly (Lien et al.,
2022). Frequent measurements are therefore required to obtain
specific information regarding H2S formation. Unfortunately, the
monitoring of H2S levels may not be enough, and the prediction
of potential occurrences is required to prevent the problems in
advance.
Possible factors leading to H2S formation are sulphate content in
water (freshwater 5–50 mg L−1, sea water 2700 mg L−1), the pres-
ence of carbon-based compounds in water, biodegradation reactions
in anoxic conditions with accumulated organic material and bacteria,
for example, sulphate-reducing bacteria or methane-reducing bacte-
ria (Li & Lancaster, 2013; Letelier-Gordo et al., 2020). Certain physical
properties such as high turbidity, sedimentation of organic matter and
lowwater flow rate can also affect H2S formation (Yu & Bishop, 2001).
Additionally, carbon-based material from uneaten feed or faeces can
react with sulphate, forming HS− and later toxic H2S (Eq. 3). Organic
matter can also participate inH2Sproduction via biodegradationwhich
occurs via oxidation and reduction reactions; electrons are transferred
from organic carbon donor to electron acceptor (Lien et al., 2022).
CH4 + SO
2−
4 →HCO
−
3 +HS
−
+H2O (3)
2.7 Ozone
Ozone is an environmentally safe disinfectant (Hansen et al., 2016)
which improves water quality in RAS due to the oxidisation reactions
of nitrite, organic material, chemical oxygen demand, colour and sus-
pended solids (Summerfelt et al., 2009; Davidson et al., 2011a). Ozone
can also attack off-flavour-causing compounds such as geosmin, bacte-
ria and fish pathogens (Summerfelt et al., 2009). Ozone reacts rapidly
with any organic matter, but residual ozone fed directly to a rearing
tank severely threatens farmed species (Powell & Scolding, 2018).
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LINDHOLM-LEHTO 7
F IGURE 2 Mole fractions of hydrogen sulphide (H2S), bisulphide (HS
−) and sulphide (S2−) as a function of pH (Applied analytics, 2022).
Several commercial ozone sensors are available. However, they
can be very expensive or unreliable or do not show the changes in
ozone concentration. ORP is therefore widely used to monitor the
ozone addition (Davidson et al., 2011a; Powell & Scolding, 2018). ORP
records the readiness of substances in solution to give or receive elec-
trons. In RAS, an ORP sensor should be placed at a point where ozone
is completely consumed and downstream of the ozone addition point
to prevent ozone damaging the sensors (Bullock et al., 1997). However,
ORP gives only an indirect result by the difference in readings before
and after the ozone treatment, and other methods such as mediated
electrochemical oxidation and changes in UV absorbance at 254 nm or
at272nmhavebeen suggested (Hansenet al., 2010;Wenket al., 2013).
The ozone production result can be determined by titration with an
iodometric standardmethod (IOA Standardization Committee Europe,
001/87 (F), 1987), while dissolved ozone in water with the stan-
dard colorimetric indigo -method (IOA Standardization Committee –
Europe, 006/ 89 (F), 1989), as recently reported in Pettersson et al.
(2022).
3 MEASUREMENTS
3.1 Measurements of water quality
Successful intensive aquaculture requires the monitoring of several
water quality parameters, such as DO, salinity, temperature, pH and
electrical conductivity (EC) (Jamroen et al., 2023). Traditionally, water
quality parameters have beenmeasured at certain intervals with hand-
held sensors. However, this requires staff, can be time consuming and
is possible only during working hours. In recent years, instrumenta-
tion, automation and monitoring systems have developed and become
more common and many of the basic measurements can be carried
out by online instrumentation (Lekang, 2013). The development of
information technology and low-cost sensors has increased the feasi-
bility of monitoring via wireless sensor networks (WSN). The special
conditions in aquaculture must be considered when designing and
installing instruments (Lekang, 2013). Besides the price of instrumen-
tation, maintenance, running costs and calibration are required, and
sensors may require changing at fixed intervals.
Real-time and efficient monitoring of water quality is essential to
ensure cost-effective RASmanagement. For example, Zhu et al. (2010)
reported an onlinewatermonitoring systemwhichwas able tomonitor
DO, pH, temperature and EC. Zhang et al. (2011) used an Orion5-Star
Portable pH/ORP/DO/EC Multimeter to measure these factors in a
RAS. Later, Odey and Li (2013) used an AquaMesh wireless mesh sen-
sor network to measure pH, DO, temperature and EC. Several studies
have reported methods to measure these variables online in aquacul-
ture (Odey & Li, 2013; Schmidt et al., 2018 Danh et al., 2020) but they
all measured the basic variables of water quality.
The most common basic water quality parameters, such as temper-
ature, pH and DO, can be measured with portable instruments such as
Multi 3410 (WTWGmbH) (Chun et al., 2018). Although portable alter-
natives are available, nitrite, nitrate and phosphate are oftenmeasured
more accurately in a laboratory, using an ion-exchange chromatograph
and suppressed conductivity detector (e.g., Dionex DX-500, Dionex
ICS1600, Dionex Integrion HPIC; Chun et al., 2018; Lindholm-Lehto
et al., 2020, 2021).
Instruments applying laboratory methods have been modified for
aquaculture facilities. A typical detector is a spectrophotometer, which
measures the absorption of light in a sample. Integration of monitoring
equipment and intelligent data management have been commercially
available, for example, fromGreenspan and Fleck in Australia, Gimat in
Germany, and Isoc, Hydrolab and Emnet in the USA (Zhang, 2007; Lv,
2015). Additionally, Siemens has developed a YSI5200monitoring sys-
tems (Shi et al., 2011). YSI has designedmonitoring and control systems
specifically for aquaculture with sophisticated alarm modes (Timmons
et al., 2018). Model 5200A can continuously monitor and log DO, pH,
conductivity, ORP, salinity and temperature, and Model 5400 for four
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8 LINDHOLM-LEHTO
DO probes and four additional inputs such as temperature, pH and
ORP.
As a result of the development of online instruments, CO2, ammonia
and nitrate sensors are widely available (Pulkkinen et al., 2018). The
sensors can be for individual parameters or several sensors included
in one instrument (Lekang, 2013). For example, automatic monitor-
ing of DO, pH and temperature in a RAS was performed with WATT
TriO Matic 700IQ (SW), WATT Sensolyt 700 IQ (SW) and WATT Tri-
oxyTherm sensors (Zhang, 2007).WSN equipment greatly reduces the
requirement for maintenance and costs, but especially in marine sys-
tems, coating of sensors is required to prevent corrosion (Hu et al.,
2020).
Water quality can also be monitored by electrochemical analysis.
This includes salinity, pH,DO, total organic carbon (TOC), temperature,
BOD, dissolved carbon and reduction potential (Bergheim & Fivel-
stad, 2014; Kolarevic et al., 2014). For example, companies supplying
electrochemical sensors commercially include Oxygard Pacific (Oxy-
Guard International A/S, Denmark) and Pentair Point Four (Pentair,
UK). These sensorst’ measurements are not specific but give a rough
indication of water quality, and more accurate analyses for specific
quantification can be performed in the laboratory (da Silva et al., 2018).
Tziortzioti et al. (2019) reported an inexpensive, portable device
for water quality measurements without the need for a communica-
tions infrastructure and network connection. The Arduino device was
equipped with SD card reader and an Ethernet module, and the mea-
surement data were stored on the SD card (Tziorzioti et al., 2019).
The card can be removed and connected to a laptop or a smart phone
for data transfer if necessary. The device included a digital tempera-
ture sensor, a total dissolved solidsmeter, an analogue turbidity sensor
for measuring suspended particles, an analogue DO meter and an
analogue pHMeter.
Santos et al. (2022) reported a pilot design of electrochemical oxida-
tion of ammonium nitrogen in marine RAS water rearing gilthead sea
bream (Sparus aurata) and sea bass (Dicentrarchus labrax). They mea-
sured TAN, fish growth (specific growth rate SGR, FCR, specific feed
rate SFR), microbial count (FCUmL−1) andwater and energy consump-
tion (Santos et al., 2022). The system included incorporated automatic
online analysers for monitoring pH, DO, temperature, ORP, TAN and
chlorine content. The TAN concentration was monitored in real time,
while the other parameters were periodically measured.
Lien et al. (2022) developed a sensor to detect H2S at sub µg L−1
levels. The AquaSense system was a mobile wireless and a real-time
monitoring system which consisted of units in different locations in a
RAS. The sensors measured H2S (µg L−1), DO (% saturation), CO2 (mg
L−1), pH, salinity (‰), alkalinity (mg L−1), turbidity (NTU) and tempera-
ture (◦C) (Lien et al., 2022). The sensors are not exposed to water. The
system was automatically calibrated by feeding calibration gas to sen-
sors at selected intervals. The sensors in a RAS communicated via an
open network and collected the data for storage locally or stored in
the cloud service. The H2S sensor covered the 0–80 µg L−1 range (Lien
et al., 2022).
A future trend in aquaculture is an automatic remote monitoring
and computer control of systems. For example, Zhu et al. (2010) used
a Code Division Multiple Access (CDMA) service and an IPsec-based
virtual private network tomonitorwater quality. CDMA is a competing
cell phone service technology to GSM. The system consisted of water
quality control components, data acquisition and data transformation
and transmission. It was able to monitor water and room temperature,
DO saturation, DO concentration, pH, EC and salinity, and notify any
abnormalities (Zhu et al., 2010).
3.2 Measurement frequency
Monitoring of water quality should include many parameters (Table 2).
Some of them require constant monitoring (e.g., DO, CO2, pH) to avoid
detrimental disturbances in RAS, while others can be monitored less
frequently (e.g., off-flavours, trace elements and metals). However,
effective online monitoring systems are unavailable for all parameters,
especially not at reasonable cost.
To maintain water quality at optimal range, quality parameter data
need to be gathered regularly. Traditionally, water quality has been
monitored by manually taking samples and sent for analysis in a lab-
oratory (Pasika & Gandla, 2020). This takes time, requires analytical
equipment and can be labour intensive (Pasika & Gandla, 2020), but
does not provide real-time data. There are various opinions for, how
often water quality parameters should be measured (Jamroen et al.,
2023). For example, Ferreira et al. (2011) suggested dailymonitoring of
DOand temperature, and salinity, butweeklymonitoringof pHand tur-
bidity.However, dramatic changes inwater quality canbemissedwhich
can lead tomajor fishmortalities and financial losses. New sensor tech-
nology and wireless communication for remote monitoring is possible
in real-time (Jamroen et al., 2023). Real-time monitoring of selected
water quality parameters is required for farmers to recognise low
water quality andmakemanagement decisions (Oberle et al., 2019).
In aquaculture, economic constrains, high costs of human resources
and real-timemonitoring of all the importantwater quality parameters
have long been real challenges for farmers (Rashid et al., 2021). It is
impossible to monitor water quality based only on experience, but an
intelligent system can monitor water quality parameters in real time
and help maintain good water quality (Saha et al., 2019; Rashid et al.,
2021). A water quality prediction model can be useful for predicting
dynamic changes in water. Furthermore, a smart aquaculture system
can reduce labour costs and be beneficial for fish health (Ghose, 2014).
A monitoring system with sensors and a microcontroller can mon-
itor pH, turbidity, water level, temperature and humidity (Pasika &
Gandla, 2020). The data were collected continuously and in real time
sent wirelessly to themonitoring station. The system included amicro-
controller unit with a sensor network for sampling every 10 s from
the water tank (Pasika & Gandla, 2020). Additionally, an algorithmwas
used tomonitor the changes in water quality parameters.
3.3 Real-time measurements
Variousmethods forwater qualitymonitoring havebeen reported (Zhu
et al., 2010; Huan et al., 2020; Lin et al., 2021). Typically, they can
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LINDHOLM-LEHTO 9
TABLE 2 Selected water quality parameters (alkalinity, DO, CO2, EC, nitrite-N, nitrate-N, pH, ORP, salinity TAN, temperature and TOC)
typically monitored in RAS, examples of their analysis methods and instrumentation
Parameter Method of analysis Instrumentation References
Alkalinity Standard titration
method (ISO
9963−1:1994)
HachMethod
8203–Sulfuric Acid Digital
Titration
TitraLab AT1000,
Hach
Lindholm-Lehto et al.
(2021)Davidson
et al.
(2017)Pulkkinen
et al. (2018)
Dissolved
oxygen
(DO)
Portable instruments
online-monitoring,
electrochemical analysis
Orion5-Star
Portable
pH/ORP/DO/EC
Multimeter
Oxygard Pacific
Zhang et al.
(2011)Schmidt et al.
(2018)Danh et al.
(2020)
Carbon
dioxide
(CO2)
Online-monitoring
quick spectrophotometric
tests
Franatech
HachMethod
8223
Pulkkinen et al.
(2018)Davidson
et al. (2019)
Electrical con-
ductivity
(EC)
Portable instruments
online-monitoring
Orion5-Star
Portable
pH/ORP/DO/EC
Multimeter
AquaMesh
network
Oxygard Pacific
Zhang et al.
(2011)Odey and Li
(2013)da Silva et al.
(2018)
Hydrogen
sulphide
(H2S)
Wireless onlinemonitoring
system
AquaSense system Lien et al. (2022)
Nitrite-N
Nitrate-N
Ion chromatography, IC
portable instruments
online- monitoring
quick spectrophotometric
tests
Dionex DX-500
(Dionex)
Multi 3410
(WTWGmbH)
LCK340,
LCK341,
Chun et al.
(2018)Lindholm-
Lehto et al. (2020,
2021)
Pulkkinen et al.
(2018)
Oxidative
reduction
potential
(ORP/Redox)
Portable instruments
online-monitoring
electrochemical analysis
LAQUAact, Horiba
scientific D-74
LoRaWAN (Long
RangeWide Area
Network),
Tolentino et al.
(2021)Pettersson
et al. (2022)Schmidt
et al. (2018)Danh
et al. (2020)
pH Portable instruments
online-monitoring
electrochemical analysis
AquaMesh network
Oxygard Pacific
ProMinent
Zhu et al. (2010)Odey
and Li
(2013)Pulkkinen
et al. (2018)
Salinity Ion chromatography, IC
portable instruments
Dionex DX-500
Oxygard Pacific
YSI 30 Salinity
Meter
Danh et al.
(2020)Lindholm-
Lehto et al. (2020,
2021)
Total nitrogen
(TAN)
Quick spectrophotometric
tests
HachMethod 8038
USEPANessler
Davidson et al. (2019)
Temperature Electrochemical analysis
portable instruments
online-monitoring
Oxygard Pacific
Temperature
Meter
Danh et al.
(2020)Bergheim and
Fivelstad (2014)
Kolarevic et al.
(2014)
Total organic
carbon
(TOC)
Electrochemical analysis Oxygard Pacific Bergheim and
Fivelstad (2014)
Kolarevic et al.
(2014)
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10 LINDHOLM-LEHTO
measure the basic water quality factors (e.g., DO, pH, temperature)
which greatly affect the survival of the reared species.
In recent years, a variety of monitoring systems has been reported,
such as a remote monitoring system for aquaculture (Wang et al.,
2012), WSN (Nam et al., 2015) and a WSN automatic monitoring sys-
tem for fisheries that combines WiFi and ZigBee technologies (Chen
et al., 2016). Zigbee is built for control and sensor networks forwireless
personal area networks (WPANs) and operates on 2.4 GHz, 900 MHz
and 868MHz frequencies.WSN consists of self-organised sensors that
measure, collect, transmit and process data in real time. The informa-
tion is displayed on a computer or conveyed for remote monitoring
(Chen et al., 2016). Over the last decade,WSN has been widely used in
aquaculture (Zhang et al., 2011; Huang et al., 2013; Cario et al., 2017).
Odey and Li (2013) used an AquaMesh wireless mesh sensor net-
work to measure pH, DO and EC. Later, WSN and a general packet
radio service (GPRS) were applied to remotely monitor water quality
parameters and feed consumption (Lorena et al., 2018). Lin et al. (2021)
used online monitoring of temperature, pH, DO and EC in an intensive
culture system. They used a portable pH/ORP/DO/EC Multimeter to
measure these variables in a RAS connected with a constructed wet-
land. The applications have been in used in variety of industries, also in
fish farms (Zhang et al., 2011; Huang et al., 2013; Chandanapalli, 2014;
Luo et al., 2015; Cario et al., 2017). Physical water quality parameters
were measured in real time and stored in a database. However, these
systems included only the most basic variables (temperature, DO, pH,
water level). A responsiblepersonwas informedof aproblembySMSor
email (Zhang et al., 2011). Graphical display of real-time datawas avail-
able (Huang et al., 2013), while solar and lithium cells have also been
used as power supply (Luo et al., 2015).
Long transmission distance, fast communication and high transmis-
sion distance quality have been achieved with the 4G technology. In
future, 5G technologywill be applied to further enhance thedata trans-
fer. Addition of data processing to support subsequent analysis can
improve data quality. It consists of data cleaning, integration, trans-
formation and data reduction (Fang, 2009). This usually means data
repair and noise reduction. Several different data repairing mecha-
nisms have been suggested, such as request retransmissionmechanism
(Li et al., 2014a), distributed storage mechanism (Omiwade & Zheng,
2012), multi-path disjoint data transmission (Li et al., 2014b) and data
redundancy backup (Srouji et al., 2011). Additionally, a compression
sensing algorithm can be incorporated (Zhao, 2015).
Many noise reduction methods have been proposed, such as least
square method, quadratic bilinear time frequency analysis, Fourier
transform and wavelet transform, to eliminate noise interference in
measurements (Wickersham et al., 2014; Hu et al., 2020). The wavelet
analysis can realise the separation and extraction of frequencies for
water quality signals (Wickersham et al., 2014). It is a convenient tool
which has been used, for example, in hydrological and water quality
prediction (Ebrahimi et al., 2013; Yu et al., 2014).
Tolentino et al. (2021) reported a systemwhichmonitored and auto-
matically corrected water quality parameters in an intensive system
rearing Nile tilapia (O. niloticus). They developed a monitoring sys-
tem for pH, ORP, turbidity, temperature, salinity and DO in water.
Furthermore, the system includedan internet-based access andonline-
applications to monitor the status of the system and parameters
(Tolentino et al., 2021). The system consisted of sensors, microcon-
trollers, a Long RangeWide Area Network (LoRaWAN), and correcting
devices: a microcontroller, water pump, heater, water bottle and drum.
Water quality was improved by adding new replacement water, while
pHwas corrected by adding sodium bicarbonate solution.
3.4 Internet of Things in aquaculture
In recent years, Internet of Things (IoT) has become increasingly com-
mon. In aquaculture, the IoT has been applied in real-time monitoring
and adjusting of water levels and pumping (Kassem et al., 2021). Anand
and Regi (2018) used aNarrowBand (NB)-IoT system for remotemon-
itoring of water levels in rearing tanks. This technology had low costs,
low power consumption and wide coverage which is suitable for aqua-
culture. For example, an IoT-based water quality monitoring system
for temperature, pH, DO and salinity (Dahn et al., 2020). Lin et al.
(2021) showed that awirelessmulti-sensor IoT integratedwith sensors
measuring pH, temperature, DO and EC with WiFi communication for
aquaculture, showing good accuracy and confidence.
Huan et al. (2020) reported a monitoring system for aquaculture
water quality based on NB-IoT with chip and sensor technology to
collect aquatic environment information. It was applied for the non-
gateway data report through the NB module and a cloud platform
to save the received data. Temperature, pH and DO sensor devices
collected the water quality data and encoded them for the data
frame format. Additionally, the system enabled the remote control of
equipment.
In the study ofKassemet al. (2021), theRASmonitoring systemcon-
sisted of three components: monitoring of the most vital water quality
parameters, monitoring the water sampling inlets connected to basin
water, and the components responsible for cleaning pipes. No cleaning
fluid was fed into the rearing tanks. The sensor case contained a sep-
arate cleaning mechanism to ensure the cleaning of sensors and their
calibration (Kassemet al., 2021). The system run-timedependedon the
distance from the sampling point to the sensor and controller (about
two hours, including the cleaning sequence). The systems showed high
accuracy due to automated sampling and cleaning. It was run non-
stop to ensure multiple measurements per day (Kassem et al., 2021). A
decreased labour requirement led to decreased costs, but it could still
measure a wide range of parameters: ammonia, nitrite, pH, total vibrio
(cfumL−1), alkalinity, temperature, salinity and DO.
Rashid et al. (2021) reported a system applying an IoT-based mon-
itoring system for real-time water quality, which focused on water
level parameters. They collected data via sensors, analysed the data
with machine learning tools to study and monitor the water qual-
ity. The water quality parameters included pH, temperature and TSS,
and the correlation between the parameters was also studied (Rashid
et al., 2021). The prediction model was trained based on the col-
lected data. They showed that the system increased efficiency, reduced
labour requirements and ensured more sustainable and economical
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LINDHOLM-LEHTO 11
production. They also reported good testing accuracy andperformance
but still wished to improve it in the future.
IoT systems in aquaculture typically use WSN with wide coverage
area and good scalability (Pule et al., 2017). These technologies include
Zigbee, Bluetooth (Hu et al., 2020) and General Packet Radio Services
(GPRS)/CDMA/long-term evolution (Zhu et al., 2010). Zigbee is widely
used in WSN for water quality monitoring. However, sensitive sys-
tems can easily malfunction and have high energy consumption in long
distance transmission.
A fusion of digital technologies and use of IoT can transform a
traditional farming model into smart farming (Narwane et al., 2022).
WSNs have made significant contribution to various farming appli-
cations (Jamroen et al., 2020, 2023). Wang et al. (2012) designed a
remote monitoring system to increase the level of automation and
used a 3G cellular technology with an Android-basedmobile operating
architecture. Nam et al. (2015) developed aWSN-based remote water
quality monitoring system by combining a ZigBee network protocol
andCDMA technology. Postolache et al. (2014) proposed an IoT-based
system for water quality monitoring (EC, temperature and turbid-
ity) in aquaculture, using WSN architecture. Recently, a photovoltaic
(PV)/battery energy storage (BES)-powered water quality monitoring
system was introduced, based on the NB-IoT (Jamroen et al., 2023).
The system couldmeasure DO, pH, temperature, turbidity and salinity,
as well as electrical parameters’ PV power, system consumption, BES
power and state of charge for system functionality.
Besides the real-time information they provide on water qual-
ity parameters, early warning signs are also valuable for farmers in
detecting abnormalities (Hu et al., 2020). In smart aquaculture, the
integration of artificial intelligence and IoT systems can control the
risks and improve the quality of aquatic production and ensure the
survival of the reared species. This requires real-time collection and
processing of reliable water quality data.
3.5 More advanced analyses
Organic compounds such as veterinary drugs, antibiotics, off-flavour
compounds and ozonation by-products in marine systems can enter
the system, for example, via inlet water, or are formed in the system.
Medications can also be needed in aquaculture, including anaesthet-
ics, vaccines and antibiotics (Costello et al., 2001; Dauda et al., 2019).
However, these chemicals are important for aquaculture purposes but
are used in low concentrations. Additionally, the detection of cortisol
levels and other hormones in aquaculture water and fish have become
more important for fish welfare studies (Rollo et al., 2006; Mota et al.,
2017; Hanke et al., 2019; Höglund et al., 2022;). Some compounds
may be undesirable in fish products (e.g., off-flavours geosmin and 2-
methylisoborneol), or they can pose a risk to the raised species (e.g.,
ozonation by-products). They need to be reliably detected, identified
and quantified. This usually requires more advanced chemical knowl-
edge and equipment, and these analyses are therefore performed in a
laboratory instead of on a fish farm (Table 3).
Trace metals such as zinc and copper can be led in the system via
feed or by erosion of materials, or via inlet water (Kristensen et al.,
2009; Bergheim & Fivelstad, 2014). Heavy metals are toxic to fish, as
they can interact with osmoregulation and the accumulation of other
toxic compounds such as ammonia, or remain in fish flesh, posing a risk
to fish consumers (da Silva et al., 2018). This highlights the importance
of monitoring tracemetals and elements in RAS.
Compound can be analysed with techniques based on liquid (LC)
or gas chromatography (GC) based on its properties. Additionally, for
the detection of low concentrations of analytes in complex RAS water
matrix, a variety of pretreatment methods is required, including solid
phase extraction (Gorito et al., 2022; Höglund et al., 2022), solid phase
micro extraction (Lindholm-Lehto, 2022) and dynamic headspace (HS)
(Podduturi et al., 2017), to name a few (Table 3). In the case of
volatile and semi-volatile compounds, GC-based methods are pre-
ferred (Lindholm-Lehto et al., 2019; Lindholm-Lehto, 2022), while LC
with tandem mass spectrometry (MS/MS) detection is more suitable
for antibiotics (Freitas et al., 2014).
4 EFFECTS OF WATER QUALITY
4.1 Water quality and fish behaviour
The stress response of fish is related to water quality (Iryna et al.,
2013; Hu et al., 2020). Stress in fish can lead to inhibited growth,
a weaker immune system and changes in fish behaviour (Hjeltnes
et al., 2022). These changes can be crucial, especially as optimal
growth is highly desirable (da Silva et al., 2018). For example, stressed
zebrafish (Danio rerio) showed increased body temperature (2–4◦C)
which can be considered as a fever response (Rey et al., 2015). Rey
et al. (2015) suggested that the observed emotional fever is asso-
ciated with consciousness in fish. The zebrafish clearly showed the
capacity for emotional fever but the link between consciousness is
still debated. On the other hand, water properties (temperature) can
affect fish growthandgenetic sexdeterminationbasedon temperature
(Santi et al., 2017). High temperatures (36◦C) led to masculinisation
of African catfish (Clarias gariepinus) when exposed 6–8 days after
hatching. The exposure during the short thermosensitive period led to
90–100%males (Santi et al., 2017).
Certain pollutants can change the movement behaviour of fish, and
by measuring the intensity of this behaviour, pollutant concentration
can be calculated (Zhang et al., 2013). For a pollutant, models can show
if the water quality is polluted or unpolluted but not determine a spe-
cific concentration (Peng, 2017). So far, more advanced interactions
remain subjects for further studies.
Water quality has been evaluated by studying the average move-
ment speed, height, distant and position distribution of fish (Bernatow-
icz et al., 2009). Fen (2014) on the other hand, used group behaviour
parameters: swimming speed and distance to nearest neighbor, to
quantify normal and abnormal water quality. However, all these meth-
ods are applicable only in certain conditions, and only a few studies
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12 LINDHOLM-LEHTO
TABLE 3 Selected water quality parameters measured in RASwhich require more advanced analyses in the laboratory and examples of
instrumentation required for their analysis
Parameter Instrumentation References
Antibiotics LC-MS/MSa Gorito et al. (2022)Shi et al. (2022)
Cortisol LC-MS/MSaradioimmunoassay (RIA)
Cortisol EIA kit
Hanke et al. (2019)Mota et al.
(2017)Höglund et al. (2022)Rollo et al.
(2006)
DOC, TOCb Aurora 1030W
TOC analyzer
Shimdadzu TOC-L analyzer
Li et al. (2016)Pettersson et al. (2022)
Metals ICP-OESc: Perkin-Elmer Optima 8300
ICP-MSd: Perkin Elmer NexION®350D
Lindholm-Lehto et al. (2020, 2021)
Molecular mass of NOMe HPSEC-EEMf/UV Jokubauskaite et al. (2015)Ignatev and
Tuhkanen (2019)
Molecular mass of NOMe HPSEC-DAD/FLDgEEM-PARAFACh Li et al. (2014c, 2016)
Off-flavoursi Dynamic HSj-GC-MS
SPME-GC-MS
SPME-GC-MS/MS
Podduturi et al. (2017)Lindholm-Lehto et al.
(2019)Lindholm-Lehto (2022)
Trihalomethanes
Brominated oxidation
by-products
GC-MSUSEPAMethod 524.2
DR/2800 Spectrophotometer
Schroeder et al. (2011)Li et al. (2016)
aLiquid chromatography (LC)–tandemmass spectrometry (MS/MS).
bDissolved organic matter (DOC), total organic carbon (TOC).
cInductively coupled plasma optical emission spectrometer (ICP-OES).
dInductively coupled plasmamass spectrometry (ICP-MS).
eOrganic material, including humic and fulvic acids, protein-like compounds (NOM).
fExcitation emissionmatrix (EEM).
gHigh performance size exclusion chromatography (HPSEC)-diode array detector (DAD)/fluorescence detector (FLD).
hFluorescence excitation-emission-matrix combinedwith parallel factor analysis (EEM-PARAFAC).
iOff-flavours include a variety of compounds, such as geosmin, 2-methylisoborneol and other terpenes, aldehydes, fatty acids and so on.
jDynamic HSDynamic Headspace sampling of volatiles in Tenax TA traps.
report interactions between multiple water quality parameter and
behavioural characteristics of fish.
Based on fish behaviour, it is possible to obtain and predict changes
in water quality. The detection of fish behaviour can be based on video
imaging, and includes characteristics’ shape, texture, background,
colour, swimming speed and direction, fin beating frequency, feeding
condition and metabolic rate (Yang et al., 2013; Cook et al., 2014).
However, video imaging may be unsuitable for aquaculture environ-
ment, for example, in the case of high turbidity. Fish can be separated
from their backgrounds, based on background modelling, temporal
differencemethod and optical flowmethod (Hu et al., 2020). For exam-
ple, Zhang et al. (2015) used a computer vision algorithm to measure
pectoral fin and background subtraction to obtain fish location more
accurately.
Changes in swimming activity, swimming depth and acceleration can
reflect the response of fish to its surroundings (Martins et al., 2012;
Kolarevic et al., 2021). Although water quality parameters are fre-
quently monitored in RAS, fish behaviour is not typically as an integral
part of the systems (Kolarevic et al., 2016, 2021), and the conditions
in RAS on welfare and performance of the raised species need to be
improved.
A variety of water quality parameters (DO, CO2, nitrate, pH) and
feeding regimes can affect the swimming behaviour of fish (Davidson
et al., 2011a; Martins et al., 2012). Techniques applying biotelemetry
have been used to monitor the behaviour of individual farmed and
wild fish (Kolarevic et al., 2016, 2021; Sinisalo, 2022). With tags, algo-
rithms of acceleration and gravity forces can be measured accurately
and transmitted to acoustic receivers (AccelTag; Thelma Biotel, Nor-
way) (Martins et al., 2012). This technology has been used to monitor
swimming activity in sea cages (Føre et al., 2011).
An acoustic acceleration tag, AccelTag, allows real-time monitoring
of fish behaviour (Kolarevic et al., 2016). However, they are limited
by the available tag sizes (7 and 11 g). The tag size should be about
2%/body mass (Jepsen et al., 2004). By tagging Atlantic salmon post
smolts in RAS, swimming behaviour of fish can be monitored and
observe changes in water quality and stress events (Kolarevic et al.,
2016). Acoustic acceleration tags can therefore be a suitable tool for
welfare andmanagementpractice studies and for responses to changes
in water quality and chronic thresholds of water quality parameters.
Fishmovement in goodwater quality differs from those in abnormal
water quality. Cheng et al. (2019) monitored fish movements by two
cameras combined a three-dimensional motion trajectory system with
a Kuhn-Munkres algorithm. They showed that the learning model suc-
cessfully reflected the water quality. However, they could not assess
water quality in time and were not able to show which water quality
parameter caused the abnormal behaviour.
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LINDHOLM-LEHTO 13
WSNs have also been applied for monitoring of fish behaviour and
water quality. For example, Parra et al. (2018) used a WSN to monitor
feeding of fish and water quality in rearing tanks. Sensors were used
to monitor temperature, turbidity, water level and conductivity, while
monitoring of fish behaviour included swimming depth and velocity.
Based on the monitored variables and fish behaviour, system was able
to control the changes in water quality.
4.2 Feeding
Fish appetite can be affected by water quality, especially temperature
and DO (Sun et al., 2016). Several issues affect feed intake, which can
bedue to physiological, nutritional or environmental issues (Zhou et al.,
2018). Frequency and time of feeding affects feeding intensity, and fish
behaviour can vary based on how feed is sprinkled in the tank (Martins
et al., 2012).
Excessive feeding increases costs and faeces and uneaten feed lead
to increased solid waste in the system and affect the water quality
andmicrobial abundance in the system (Rojas-Tirado et al., 2018; Zhou
et al., 2018). Currently, automated feeding systems are widely used in
aquaculture. However, predicting when feeding should be stopped is
often based on subjective experience (Zhou et al., 2018).
Feeding can be automatically adjusted based on fish appetite (Zhou
et al., 2017a). There are feeding systems that can calculate feed
demand real-time based on the quantity of fish. Fish behaviour is mon-
itored by machine vision, underwater acoustic technology and water
quality sensors. For example, acoustic sensors can detect feed (Juell
et al., 1993) and count the pellets by computer vision (Li et al., 2017) to
assess the fish appetite. Computer visionhas beenwidely usedbecause
it is relatively inexpensive and does not harm the fish (Sadoul et al.,
2014; Lin et al., 2018).
An intelligent feedback control can observe fish behaviour and
based on specific control algorithm, stop feeding in the case of aggre-
gation behaviour (Chang et al., 2005). However, computer vision often
requires good illumination conditions which can be challenging in tur-
bid water. A near infrared machine vision is more suitable, and with
image enhancement algorithms good results can be achieved, also in
poorly illuminated conditions (Zhou et al., 2017b). Zhou et al. (2018)
reported an automatic feeding control method based on near infrared
computer vision and a neuro-fuzzymodel for on-demand feeding. They
found significant increase in fish growth and the FCR was reduced by
10%, andwater quality was improved (Zhou et al., 2018).
5 CONCLUSIONS
In aquaculture, several water quality parameters need to bemonitored
to understand the aquatic conditions. There are currently no regula-
tions for which parameters to measure, and each farmer has their own
view of and possibilities for water quality measurements. So far, there
are no guidelines for acceptable ranges and fluctuations. These have
been listed in this study. Although suitable ranges vary between differ-
ent species, certain guidelines would be a valuable tool for designing
and running a RAS facility.
1. Traditionally, water quality parameters have beenmeasured at cer-
tain intervals with handheld sensors and quick laboratory tests, but
this can time-consuming and possible only during working hours. In
recent years, the development of information technology and low-
cost sensors has enabled monitoring via WSNs, online monitoring
systems and applications of IoT which allow real-time monitoring,
automatic data collection and storing.
2. Intelligent systems may include the prediction of problems before-
hand based on changes in water quality. Early warning signs are
valuable for farmers to detect abnormalities and act before major
issues occur. However, many of the modern sensors and moni-
toring systems need competent users and regular maintenance
and calibration. The effects of water quality can also be observed
by monitoring fish behaviour such as swimming activity, depth,
acceleration and feeding. Fish behaviour can be monitored by, for
example, acoustic acceleration tags and computer vision. This can
be a valuable addition to the monitoring regime with the more
traditional parameters.
3. All the new IoT-based monitoring systems can monitor the basic
water quality parameters (DO, pH, temperature, turbidity and
salinity), which can be sufficient for regular monitoring purposes.
However, the more advanced analyses (e.g., off-flavours, cortisol
levels) still need to be performed in a laboratory and cannot be per-
formed in real-time. Thesemayalso requiremoreadvancedanalysis
equipment and can only be performed by trained personnel. Devel-
opment of new techniqueswhich allows real-timemonitoring of the
more advanced water quality parameters remains as a subject of
future studies.
AUTHOR CONTRIBUTION
Petra Lindholm-Lehto: Formal analysis, investigation,writing –original
draft, resources
ACKNOWLEDGEMENTS
Financial support from the NordForsk: Sustainable Aquaculture –
Research and Innovation Projects is gratefully acknowledged.
CONFLICT OF INTEREST STATEMENT
The author of this research project would like to disclose the absence
any personal or financial relationshipwith people or organisations that
may inappropriately influence this work. This naturally includes all
grant and sources of funding described in the paper.
DATA AVAILABILITY STATEMENT
Not applicable.
ETHICS STATEMENT
This material is the authors’ own original work, which has not been
previously published elsewhere.
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14 LINDHOLM-LEHTO
ORCID
Petra Lindholm-Lehto https://orcid.org/0000-0003-1807-8116
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How to cite this article: Lindholm-Lehto, P. (2023)Water
quality monitoring in recirculating aquaculture systems.
Aquaculture, Fish and Fisheries, 1–19.
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iley Online Library for rules of use; OA articles are governed by the applicable Creative Commons License