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Citation: Giacosa, G.; Barnett, C.;
Rainham, D.G.; Walker, T.R.
Characterization of Annual Air
Emissions Reported by Pulp and
Paper Mills in Atlantic Canada.
Pollutants 2022, 2, 135–155. https://
doi.org/10.3390/pollutants2020011
Academic Editors: Artur Badyda and
Chris G. Tzanis
Received: 10 February 2022
Accepted: 29 March 2022
Published: 8 April 2022
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4.0/).
Article
Characterization of Annual Air Emissions Reported by Pulp
and Paper Mills in Atlantic Canada
Gianina Giacosa 1,* , Codey Barnett 2
, Daniel G. Rainham 3 and Tony R. Walker 1
1 School for Resource and Environmental Studies, Dalhousie University, Halifax, NS B3H 4R2, Canada;
trwalker@dal.ca
2 Nova Scotia Department of Environment and Climate Change, Halifax, NS B3J 2P8, Canada;
codey.barnett@novascotia.ca
3 School of Health and Human Performance, Dalhousie University, Halifax, NS B3H 4R2, Canada;
daniel.rainham@dal.ca
* Correspondence: gianina.giacosa@dal.ca
Abstract: The pulp and paper industry is a major contributor to water and air pollution globally. Pulp
and paper processing is an intensive energy consuming process that produces multiple contaminants
that pollute water, air, and affect ecological and human health. In Canada, the National Pollutant
Release Inventory (NPRI) is used to assess the release of air pollutants into the atmosphere from
industrial facilities (including pulp and paper mills) and provides a repository of annual emissions
reported by individual facilities. This study compared annual air emissions of carbon monoxide,
nitrogen oxides, total particulate matter (TPM), PM2.5, PM10, sulphur dioxide, and volatile organic
compounds from nine different pulp and/or paper mills in Atlantic Canada from three provinces
(Nova Scotia, New Brunswick, and Newfoundland and Labrador) between 2002 and 2019. Results
revealed that annual releases were several orders of magnitude higher than federal reporting thresh￾olds suggested by Environment and Climate Change Canada. Pulp mills emit higher pollutant loads
than those producing paper. The highest exceedance of a reporting threshold was for particulate
matter (PM2.5) at Northern Pulp in Nova Scotia. The emissions of PM2.5 were on average (over a
17-year period) about 100,000% above the reporting threshold of 0.3 tonnes per year.
Keywords: air pollution; pulp and paper; National Pollutant Release Inventory (NPRI); Atlantic
Canadian provinces
1. Introduction
Combustion of fossil fuels and biofuels during energy intensive production processes
emits pollutants into the atmosphere [1], which threatens human and ecological health [2–5].
However, atmospheric emissions from industrial facilities were once considered a symbol
of economic growth, and their effects were not considered harmful until late in the last
century [6]. In recent decades, stringent standards were developed around the world to
protect human and environmental health [7,8]. In 1970, the Clean Air Act was established
in the United States due to growing concerns over air pollution impacts. Even though
current legislation in the United States has saved millions of lives, many premature deaths
still occur because of breathing polluted air, principally in marginalized sectors such as
poor Black or Latino communities [9]. In Canada, the Canadian Environmental Protection Act,
1999 provided legislative authority to protect human and environmental health but was
highly criticized for its lack of scientific basis and is currently being amended [10–12]. In
2006, the Canadian government published a Notice of Intent to regulate air emissions, and
one year later, the Clean Air Regulatory Agenda was published to establish a framework
on emissions reduction targets and enforceable regulations [13].
Pollutants 2022, 2, 135–155. https://doi.org/10.3390/pollutants2020011 https://www.mdpi.com/journal/pollutants 

Pollutants 2022, 2 136
1.1. Air Emission Regulation in Canada
In Canada, all companies and organizations that emit certain substances into air, water
or land and meet specific threshold requirements must report annual emissions to the
federal National Pollutant Release Inventory (NPRI) [14,15]. The NPRI is a registry of
annual estimations of emissions and disposal to the environment and was created with
the purpose of making pollution data accessible to the Canadian public [14,16]. Due
to the threat that some of the releases may pose to human and environmental health,
this information was then published on the Environment and Climate Change Canada
(ECCC) website [17]. The creation of the NPRI program resulted in a decrease in overall
emissions [15,18], although the toxicity of the releases did not decrease [15]. The decrease
in overall emissions may have been a direct result of increased public awareness and public
pressure, which is the intent of the NPRI program. However, there may have been other
reasons, such as improvements in equipment and technology or improvements in industry
practices and activities. ECCC requires that releases above reporting thresholds, shown
in Table 1 for the period 2020 to 2021, must be reported to the NPRI program [19]. These
thresholds are the lower limit trigger for reporting annual emissions; however, there are no
regulations for exceedances.
Table 1. NPRI reporting thresholds for 2020 to 2021 (retrieved from [17]).
Pollutant CO NOx SO2 TPM PM2.5 PM10 VOC
NPRI threshold (tonnes/year) 20 20 20 20 0.3 0.5 10
Desirable concentrations of ambient air pollutants, including fine particles (PM2.5),
ozone (O3), sulphur dioxide (SO2), and nitrogen dioxide (NO2), are specified in the Cana￾dian Ambient Air Quality Standards (CAAQS), a national guideline that considers an
averaging period to report the concentration of the pollutant in µg/m3 or ppb [20], not
compatible with the units reported by NPRI. While there are few studies comparing thresh￾olds in units of tonnes per year, a recent study relates 10-year NPRI industrial air emissions
to childhood-onset asthma in Quebec characterizing ‘major emitters’ those industries, for
which its PM2.5 or SO2 annual emissions exceeded 100 tonnes [5]. Emissions reported
through the NPRI program and science-based estimation tools are combined to generate
the Air Pollutant Emission Inventory (APEI), which reports air emissions for 17 pollutants
since 1990 [21,22]. ECCC recommended thresholds for annual releases (in tonnes) only for
total particulate matter (TPM) and SO2 in the Code of Practice for the Management of Air
Emissions from Pulp and Paper Facilities (CPMAEPPF) [23]. These limits are divided into
two categories for both pollutants depending on the processes occurring in the facilities
(chemical or mechanical) and should be calculated by considering the annual production
of each mill. For chemical facilities, emission limits are 2 kg and 4 kg/tonne of production
for TPM and SO2, respectively; for mechanical facilities, those emission limits are 0.5 kg
and 1.5 kg/tonne of production for TPM and SO2, respectively.
1.2. Pulp and Paper Mills and Air Pollution
Currently, mixtures of air pollutants are considered a management challenge due to the
interaction between the chemical and physical components of substances that can increase
potential toxicity of emissions [6,24]. While air pollutants exist naturally in the atmosphere
from wildfires, volcanic eruptions and biological decomposition, these acid and particulate
emissions are relatively small quantities on average and rarely pose threats to human or
ecological health [4,25]. Anthropogenic emissions, mainly from industrial activities and
fossil fuel combustion, produce the majority of hazardous air pollutants [2,6,24–27]. Pulp
and paper (P&P) industries emit large amounts of atmospheric pollutants and greenhouse
gases [1,28], although there are few studies that quantify the spectrum of emissions [29].
Numerous studies have been conducted on water pollution impacts from wastewater efflu￾ent due to P&P mills [8,30–35], but there have been comparatively few studies to evaluate 

Pollutants 2022, 2 137
the contribution of the industry to the concentrations of hazardous air emissions [36]. Air
pollution from P&P mills is mainly caused by the production of various volatile sulfur
compounds (from sulfite pulping process), odour emissions (from reduced sulfur), SO2,
and nitrogen oxides (NOx) [37,38]. Stack emissions can also contain carbon monoxide
(CO) [24]. Biomass combustion can increase the emissions of particulate matter (PM) and
of gaseous and semi volatile organic compounds (VOCs) [24,29]. Exposure to these pollu￾tants can affect human health, causing cancer or lung diseases [9,39,40], and may result in
depression or psychological problems [2]. Exposure to particulates is associated with an
increased risk of mortality from stroke, heart, or pulmonary disease, among others [6,41,42].
One method of reducing human health and environmental impacts of air pollutants is
via continuous atmospheric monitoring of pollutant concentrations. Modeling exposures
to these concentrations supports epidemiological studies to evaluate health risks and the
development of management strategies and relevant health interventions [15,18].
In Canada, there are currently 102 pulp, paper, board, and/or tissue mills in opera￾tion or which have been temporarily closed [43]. However, few studies have quantified
their compliance with emission standards based on our literature review. One of the
most controversial mills in Atlantic Canada is the Northern Pulp mill in Pictou, Nova
Scotia (NS), where locals have long been concerned about health issues and unpleasant
odours [44]. While managers of the facility report the best practices with respect to regula￾tory compliance [45], environmental monitoring revealed emission exceedances and locals
remain concerned about impacts to human health [29,46–50]. Currently, Nova Scotia does
not legislate requirements for emitters to assess human health risks from emissions [50].
Hoffman et al. (2017) also revealed that sediment and water samples, specifically dioxins
and furans and metals, from Boat Harbour (a tidal estuary designed to receive wastewater
effluent from the mill) were above both the Canadian Sediment Quality Guidelines and
Canadian Water Quality Guidelines [50]. However, ambient air pollution concentrations
in nearby communities were below the Canadian Council of Minister of the Environment
guideline limits. Hoffman et al. [49] found discordance between levels of pollution reported
by the mill on NPRI, identifying Total Reduced Sulfurs (TRS) to be three times higher in
comparison to other Canadian Kraft mills, revealing that the main pollutants from the NP
mill were sulfur odours and PM.
The current limitations of air pollution monitoring (e.g., the NPRI is a self-reported
estimated inventory) and the absence of upper air emissions thresholds entangles the
identification of harmful releases into the environment. This study, focused on the air
emissions from the P&P industry in Atlantic Canada, compares annual releases among
different facilities, identifies the main limitations of the existent reporting tools, and recom￾mends how to improve environmental and human protection regarding air quality. The
analysis includes air emissions by nine pulp and/or paper mills for 17 years using publicly
available data from NPRI [51] and for 30 years using data from the APEI inventory. The
seven pollutants studied were CO, NOx, TPM, PM2.5, PM10, SO2, and VOCs, as these air
pollutants are widely reported by industrial facilities as mandated by ECCC for the NPRI
inventory and are known to increase risk to human health [14,17].
2. Materials and Methods
2.1. Data Collection
There are nine pulp and/or paper mills in Atlantic Canada and all of them report to
NPRI, although only eight of them are currently in operation. Six are in New Brunswick
(NB), two in Nova Scotia (NS), and one in Newfoundland and Labrador (NL); five out the
nine facilities are pulp mills. Figure 1 shows the location of each facility in Atlantic Canada
and the Appendix A presents background information about each one. Table 2 provides
details of each facility as pulp mill (PU), paper mill (PA), or pulp and paper mill (PP). The
NPRI ID identifies each facility that reports, and the North America Industry Classification
System (NAICS) code classifies the type of processes and production associated with each
facility. The two first digits of the NAICS indicate the sector; the third digit indicates 

Pollutants 2022, 2 138
the subsector; and the fourth and fifth digit indicate the industry group and the industry,
respectively [52]. The sixth digit designates national industries (it is zero when there are no
additional details) [52]. Pulp, paper, and paperboard mills are assigned the code 3221 [53]. A
further classification including lower levels for those industries is presented in Table 2 where
the following is the case: (i) 322112, indicates chemical pulp mills, (ii) 322121, indicates
papermills producing paper except from newsprint, (iii) 322122, indicates papermills
producing newsprint, and (iv) 322130, indicates paperboard mills.
Pollutants 2022, 2, FOR PEER REVIEW 4 
each facility. The two first digits of the NAICS indicate the sector; the third digit indicates 
the subsector; and the fourth and fifth digit indicate the industry group and the industry, 
respectively [52]. The sixth digit designates national industries (it is zero when there are 
no additional details) [52]. Pulp, paper, and paperboard mills are assigned the code 3221 
[53]. A further classification including lower levels for those industries is presented in 
Table 2 where the following is the case: (i) 322112, indicates chemical pulp mills, (ii) 
322121, indicates papermills producing paper except from newsprint, (iii) 322122, indi￾cates papermills producing newsprint, and (iv) 322130, indicates paperboard mills. 
Figure 1. Location of mills and major populated centres. Pulp mills are represented with a circle, 
paper mills with a square, and the pulp and paper mill with a triangle.
Table 2. Location of Atlantic Canadian pulp and/or paper mills and their characteristics. PA: Paper; 
PU: Pulp; PP: Pulp and Paper.
Mill Location ID Type Product Production 
(tpy) 4 Employees NPRI 
ID 
NAICS 6 
Code 
Northern Pulp 
(−62.72°, 45.65°) 
New 
Glasgow, 
NS 
NP PU Kraft pulp 280,000 330 2 815 322112 
Irving P & P 
Limited 
(−66.09°, 45.26°) 
Saint 
John, NB IP PU Bleached 
kraft pulp 335,000 335 2 2604 322112 
Twin Rivers Paper 
(−68.33°, 47.37°) 
Edmundst
on, NB ED PU Bleached 
pulp 370,000 280 2 1221 322112 
Atholville, AV 
Group 
(−66.72°, 47.99°) 
Atholville
, NB AT PU Pulp ND 1 275 3 5008 322112 
Figure 1. Location of mills and major populated centres. Pulp mills are represented with a circle,
paper mills with a square, and the pulp and paper mill with a triangle. 

Pollutants 2022, 2 139
Table 2. Location of Atlantic Canadian pulp and/or paper mills and their characteristics. PA: Paper; PU: Pulp; PP: Pulp and Paper.
Mill Location ID Type Product Production (tpy) 4 Employees NPRI ID NAICS 6 Code
Northern Pulp
(−62.72◦
, 45.65◦
)
New Glasgow, NS NP PU Kraft pulp 280,000 330 2 815 322112
Irving P & P Limited
(−66.09◦
, 45.26◦
)
Saint John, NB IP PU Bleached kraft pulp 335,000 335 2 2604 322112
Twin Rivers Paper
(−68.33◦
, 47.37◦
)
Edmundston, NB ED PU Bleached pulp 370,000 280 2 1221 322112
Atholville, AV Group
(−66.72◦
, 47.99◦
)
Atholville, NB AT PU Pulp ND 1 275 3 5008 322112
Nackawic, AV Group
(−67.23◦
, 46.01◦
)
Nackawic, NB NA PU Pulp ND 1 365 3 2181 322112
Port Hawkesbury Paper
(−61.36◦
, 45.60◦
)
Hawkesbury, NS HA PA Paper 400,000 350 3 2221 322122
Lake Utopia Paper
(−66.77◦
, 45.16◦
)
Utopia, NB UT PA Corrugate medium 185,000 140 2 1572 322130
Irving Paper Limited
(−66.02◦
, 45.28◦
)
Saint John, NB IA PA Paper 420,000 310 2 3394 322121
Corner Brook P & P
(−57.95◦
, 48.95◦
)
Corner Brook, NL CB PP Pulp and paper 255,500 304 2 4929 322122
1 No Data. 2 Number of employees retrieved from individual mill websites. 3 Number of employees retrieved from ECCC website (National Release Inventory. Available online:
https://www.canada.ca/en/environment-climate-change/services/national-pollutant-release-inventory/tools-resources-data/all-year-dashboard.html (accessed on 29 March 2022)).
4 Total annual capacity. Mills do not necessarily operate at maximum capacity every year. 

Pollutants 2022, 2 140
2.2. Data Analysis
Pollutant release data were collected from the APEI inventory for the provinces of
NS, NB, and NL between 1990 and 2019 and from the NPRI inventory for the nine mills
from 2002 to 2019. The air pollutants analyzed were pollutants reported by the facilities:
CO, NOx, TPM, PM2.5, PM10, SO2, and VOCs. Annual emissions reported in the NPRI
were compared for each facility for each pollutant. Then, differences from the reporting
threshold (DRT) for each pollutant in every mill were calculated using the following
equation (Equation (1)):
DRT = ((NPRIreported − Threshold) × 100)/Threshold (1)
where NPRIreported is each emission reported by the facility per annum and per pollutant.
The threshold indicates the lower release that industries need to report to NPRI (it estab￾lishes the lower limit to report to NPRI) and the corresponding value for each pollutant is
in Table 1. For the SO2 and PM2.5 thresholds suggested in CPMAEPPF, the specific annual
recommended limits, ARL, were calculated with the following equation (Equation (2)):
ARL = emireq × prdann (2)
where emireq is the base level emission requirements described in the previous section,
and prdann is the annual capacity of the mill presented in Table 2. The difference in
SO2 and PM2.5 CPMAEPPF ARL was calculated for each mill (Table 3). We compared
emission trends in time for each site, as well as compliance with the reporting thresholds.
A linear regression model was implemented to assess if there is significant change in the
annual trends. The model was calculated with the emission as the dependent variable
with the year as a predictor to obtain the p-value at a 95% confidence level. Emissions are
considered statistically significant when the p-value is <0.05 for the individual site’s and
<0.001 (rounding the confidence level to the multiple models, 0.05/63) when all sites and
contaminants are considered.
Table 3. Annual recommended limits (ARL) for TPM and SO2 releases according to the CPMAEPPF
(retrieved from [54]).
Tonnes Per Year NP IP ED AT NA HA UT IA CB
TPM 560 670 740 ND 1 ND 1 200 93 210 128
SO2 1120 1340 1480 ND 1 ND 1 600 278 630 383
1 ND indicates no data. Annual capacity production in the mill was unavailable to calculate the annual thresh￾old emission.
3. Results
3.1. Air Emissions Reported by Province
Annual emissions of NOx, TPM, PM10, PM2.5, SO2, and VOCs registered in the APEI
for each province show that the releases have decreased since 1990 (Figure 2). NB, the
province with more than half of the pulp and paper mills in Atlantic Canada, leads in air
emissions for almost all pollutants and the entire 30-year period. However, mills from NS
reported more TPM, PM10, and PM2.5 emissions than NB between 2008 and 2015 (panels c,
d, e). NL, with only one mill, maintained the lowest emissions among the three provinces
for the entire period for all pollutants, except for TPM (which was higher than NS between
2002 and 2006) and for SO2 (which was of similar magnitude and sometimes above NS
emissions since 2002). 

Pollutants 2022, 2 141 Pollutants 2022, 2, FOR PEER REVIEW 6 
Table 3. Annual recommended limits (ARL) for TPM and SO2 releases according to the CPMAEPPF 
(retrieved from [54]).
Tonnes Per Year NP IP ED AT NA HA UT IA CB 
TPM 560 670 740 ND 1 ND 1 200 93 210 128 
SO2 1120 1340 1480 ND 1 ND 1 600 278 630 383 
1 ND indicates no data. Annual capacity production in the mill was unavailable to calculate the 
annual threshold emission.
3. Results 
3.1. Air Emissions Reported by Province 
Annual emissions of NOx, TPM, PM10, PM2.5, SO2, and VOCs registered in the APEI 
for each province show that the releases have decreased since 1990 (Figure 2). NB, the 
province with more than half of the pulp and paper mills in Atlantic Canada, leads in air 
emissions for almost all pollutants and the entire 30-year period. However, mills from NS 
reported more TPM, PM10, and PM2.5 emissions than NB between 2008 and 2015 (panels c, 
d, e). NL, with only one mill, maintained the lowest emissions among the three provinces 
for the entire period for all pollutants, except for TPM (which was higher than NS between 
2002 and 2006) and for SO2 (which was of similar magnitude and sometimes above NS 
emissions since 2002).
 
Pollutants 2022, 2, FOR PEER REVIEW 7 
Figure 2. Air emissions registered in the APEI for Nova Scotia, New Brunswick and New￾foundland, and Labrador for pollutants (a) CO, (b) NOx, (c) TPM, (d) PM10, (e) PM2.5, (f) 
SO2, and (g) VOC.
3.2. Air Emissions Reported by Pollutant by Each Facility 
Annual releases for all nine mills from 2002 to 2019 are shown in Figure 3 for the 
seven pollutants. Solid lines represent the pulp mills: NP in blue, Irving P & P (IP) in 
orange, Twin Rivers (ED) in green, Atholville (AT) in red, and Nackawic (NA) in purple; 
dotted lines represent the paper mills: Port Hawkesbury (HA) in brown, Lake Utopia (UT) 
in pink, and Irving Paper (IA) in grey; and dot-dashed lines represent the P&P mill, Cor￾ner Brook (CB) in yellow. The facility mean values are represented by the black dotted 
line. Figure 3a shows that, until 2007, NP was the major emitter of CO, which was above 
3000 tonnes/year while all remaining mills were <2000 tonnes/year. Between 2008 and 
2015, IP and ED were the major emitters with releases above 1700 tonnes/year. From 2016, 
the major emitters were NP and AT with emissions of more than 3000 tonnes/year and 
were significant at p = 0.005 (Table 4). UT and HA, both paper mills, emitted little across 
the period in comparison with the rest of the mills, although both were close to the thresh￾old. CB, the P&P mill, also emitted little CO during the period in comparison to the others, 
but its emissions were above thresholds for the entire period and significant at p = 0.005. 
According to Figure 3b, the major emitter of NOx in the study period was ED with an 
average of 1238.8 tonnes/year for almost the entire period and significant at p = 0.001. IP 
was the second highest emitter for the entire period with an average of 975.7 tonnes/year. 
The rest of the mills were below 600 tonnes/year for almost the entire period, except 
for NP in 2019, which emitted 954 tonnes. None of the mills emitted below the threshold 
in any reporting year. The major emitter of TPM in the period was NP (Figure 3c). Before 
2015, NP emitted more than 1000 tonnes/year and some years even more than 2000 
tonnes/year, while the other mills remained below 300 tonnes/year. From 2016 to 2019, NP 
emitted <400 tonnes/year (but still more than the remaining mills) with a slight increasing 
trend observed in the last 3 years.
Figure 2. Air emissions registered in the APEI for Nova Scotia, New Brunswick and Newfoundland,
and Labrador for pollutants (a) CO, (b) NOx, (c) TPM, (d) PM10, (e) PM2.5, (f) SO2
, and (g) VOC.
3.2. Air Emissions Reported by Pollutant by Each Facility
Annual releases for all nine mills from 2002 to 2019 are shown in Figure 3 for the
seven pollutants. Solid lines represent the pulp mills: NP in blue, Irving P & P (IP) in
orange, Twin Rivers (ED) in green, Atholville (AT) in red, and Nackawic (NA) in purple;
dotted lines represent the paper mills: Port Hawkesbury (HA) in brown, Lake Utopia
(UT) in pink, and Irving Paper (IA) in grey; and dot-dashed lines represent the P&P mill,
Corner Brook (CB) in yellow. The facility mean values are represented by the black dotted
line. Figure 3a shows that, until 2007, NP was the major emitter of CO, which was above
3000 tonnes/year while all remaining mills were <2000 tonnes/year. Between 2008 and
2015, IP and ED were the major emitters with releases above 1700 tonnes/year. From 2016,
the major emitters were NP and AT with emissions of more than 3000 tonnes/year and 

Pollutants 2022, 2 142
were significant at p = 0.005 (Table 4). UT and HA, both paper mills, emitted little across the
period in comparison with the rest of the mills, although both were close to the threshold.
CB, the P&P mill, also emitted little CO during the period in comparison to the others,
but its emissions were above thresholds for the entire period and significant at p = 0.005.
According to Figure 3b, the major emitter of NOx in the study period was ED with an
average of 1238.8 tonnes/year for almost the entire period and significant at p = 0.001. IP
was the second highest emitter for the entire period with an average of 975.7 tonnes/year.
Pollutants 2022, 2, FOR PEER REVIEW 8 
Figure 3. Air pollutant emissions from 2002 to 2019 for each facility for pollutants (a) CO, (b) NOx, 
(c) TPM, (d) PM10, (e) PM2.5, (f) SO2, and (g) VOC.
Similar characteristics were observed for PM10 emissions in Figure 3d, as previously 
shown by Hoffman et al. [49]. From 2016 to 2019, all mills emitted <120 tonnes/year, except 
from NP, which emitted 127, 149, 172, and 240 tonnes, respectively, from 2016 to 2019. The 
releases of PM2.5, presented in Figure 3e, show that, from 2002 to 2015, NP was the major 
emitter (except in 2006 where AT emitted 390 tonnes and NP 325 tonnes) with a peak of 
1689 tonnes in 2008. Mean emissions were 994.4 and 174.1 tonnes/year for the study period 
for NP and for all the mills, respectively. From 2016 to 2019, all mills emitted <110 
tonnes/year. Sulphur oxides data reveal that from 2002 to 2007, IP was the major emitter 
that was consistently above 2500 tonnes/year (Figure 3f) with a maximum of 3665 tonnes 
in 2005. From 2008 to 2019, ED was the major emitter with ~1300 tonnes/year. The rest of 
the mills were below 1200 tonnes/year almost all the time but exceeded thresholds most 
Figure 3. Air pollutant emissions from 2002 to 2019 for each facility for pollutants (a) CO, (b) NOx,
(c) TPM, (d) PM10, (e) PM2.5, (f) SO2
, and (g) VOC. 

Pollutants 2022, 2 143
Table 4. p-values for the NPRI annual trends.
p-Value 1 CO NOx TPM PM2.5 PM10 SO2 VOC
Northern Pulp 0.037 0.566 0.410 0.219 0.095 0.721 0.001
Irving P & P Limited 0.000 0.074 0.002 0.003 0.000 0.000 0.000
Twin Rivers Paper 0.008 0.000 0.821 0.596 0.902 0.002 0.601
Atholville, AV Group 0.017 0.197 0.105 0.104 0.098 0.031 0.095
Nackawic, AV Group 0.098 0.006 0.006 0.971 0.388 0.000 0.001
Port Hawkesbury Paper 0.333 0.403 0.279 0.322 0.517 0.028 0.000
Lake Utopia Paper 0.208 0.665 0.044 0.178 0.510 0.019 0.019
Irving Paper Limited 0.030 0.728 0.124 0.191 0.354 0.015 0.017
Corner Brook P & P 0.013 0.130 0.091 0.109 0.234 0.000 0.623
1 Significant values at p = 0.05 are in blue. Significant values at p = 0.001 are in red.
The rest of the mills were below 600 tonnes/year for almost the entire period, except
for NP in 2019, which emitted 954 tonnes. None of the mills emitted below the threshold in
any reporting year. The major emitter of TPM in the period was NP (Figure 3c). Before 2015,
NP emitted more than 1000 tonnes/year and some years even more than 2000 tonnes/year,
while the other mills remained below 300 tonnes/year. From 2016 to 2019, NP emitted
<400 tonnes/year (but still more than the remaining mills) with a slight increasing trend
observed in the last 3 years.
Similar characteristics were observed for PM10 emissions in Figure 3d, as previously
shown by Hoffman et al. [49]. From 2016 to 2019, all mills emitted <120 tonnes/year,
except from NP, which emitted 127, 149, 172, and 240 tonnes, respectively, from 2016 to
2019. The releases of PM2.5, presented in Figure 3e, show that, from 2002 to 2015, NP
was the major emitter (except in 2006 where AT emitted 390 tonnes and NP 325 tonnes)
with a peak of 1689 tonnes in 2008. Mean emissions were 994.4 and 174.1 tonnes/year
for the study period for NP and for all the mills, respectively. From 2016 to 2019, all
mills emitted <110 tonnes/year. Sulphur oxides data reveal that from 2002 to 2007, IP
was the major emitter that was consistently above 2500 tonnes/year (Figure 3f) with a
maximum of 3665 tonnes in 2005. From 2008 to 2019, ED was the major emitter with
~1300 tonnes/year. The rest of the mills were below 1200 tonnes/year almost all the time
but exceeded thresholds most of the time except for NP and CB, which were below the
threshold five and two out of the seventeen years, respectively. Except for NP, all the
mill’s emissions were significant at least at p = 0.001. Figure 3g shows VOC emissions. In
2002 and 2003, ED was the largest emitter with 601 and 596 tonnes, respectively, and in
2004, the emission was 1412 tonnes in AT. From 2005 to 2019, ED emitted between 400 and
650 tonnes/year and was the major VOC emitter. The rest of the VOC emissions remained
<400 tonnes/year for all mills.
Figure 4 presents boxplots for all pollutants, where the red line represents the median,
the extremes of the box represent the upper and the lower quartile, the whiskers the range
of the data, and the empty circles the outliers. The mean releases and the standard deviation
of each mill along with the mean releases of the major pollutants (considering the criteria
in [5]) are presented in Table 5. The major spread for CO was in NP releases, even though
the highest mean release was in IP and the major release was in AT. Releases of NOx had
the highest spread and the highest mean in ED. For TPM, PM10, and PM2.5 the highest
spread was in NP with 659.3, 567.8, and 457.7, respectively, vs. 119.4 to 5.0 tonnes in the
other mills. The mean of TPM, PM10, and PM2.5 in NP is ~10 times higher for the three
pollutants in comparison with the rest of the mills. It is interesting to note that the lowest
release of TPM in NP is higher than the median release in the rest of the mills. The highest
dispersion in SO2 releases was observed at IP, but the highest mean occurred in ED. The
highest spread among all pollutants is observed in SO2. VOCs presented the highest spread
and the highest release in AT, but the highest mean releases were in ED. 

Pollutants 2022, 2 144 Pollutants 2022, 2, FOR PEER REVIEW 10 
Figure 4. Distribution of air pollutant emissions from 2002 to 2019 for each facility for the pollutants 
(a) CO, (b) NOx, (c) TPM, (d) PM10, (e) PM2.5, (f) SO2, and (g) VOC.
Figure 4. Distribution of air pollutant emissions from 2002 to 2019 for each facility for the pollutants
(a) CO, (b) NOx, (c) TPM, (d) PM10, (e) PM2.5, (f) SO2
, and (g) VOC. 

Pollutants 2022, 2 145
Table 5. Mean and standard deviation (±) of air releases in each mill from 2002 to 2019.
Tonnes/Year CO NOx TPM PM2.5 PM10 SO2 VOC
Northern Pulp 1985.8 ± 1292.7 522.8 ± 166.0 1115 ± 659.3 944.4 ± 567.8 717.5 ± 457.7 159.1 ± 186.9 211.9 ± 114.0
Irving P & P Limited 1927.1 ± 224.3 975.7 ± 133.1 179 ± 66.1 129.9 ± 52.4 100.2 ± 53.1 1628.8 ± 1173.5 274.7 ± 61.3
Twin Rivers Paper 1551.4 ± 263.0 1238.8 ± 213.5 159.9 ± 74.8 125.9 ± 64.0 102.7 ± 48.0 1488.2 ± 276.0 541.4 ± 102.3
Atholville, AV Group 1256.9 ± 1208.3 477.9 ± 96.7 134.9 ± 119.4 117.7 ± 103.3 105.3 ± 93.3 683.9 ± 185.6 290.2 ± 280.1
Nackawic, AV Group 698.9 ± 164.2 551.8 ± 80.7 226.8 ± 52.0 137.8 ± 41.1 97.1 ± 32.1 1034.4 ± 406.4 183.6 ± 35.4
Port Hawkesbury Paper 342.9 ± 174.0 312.2 ± 120.9 79.0 ± 35.8 38.2 ± 21.2 15.0 ± 6.9 320.8 ± 311.3 203.8 ± 148.3
Lake Utopia Paper 49.6 ± 27.9 167.9 ± 33.4 15.0 ± 9.9 12.0 ± 8.4 9.5 ± 5.2 401.7 ± 323.1 91.7 ± 135.2
Irving Paper Limited 56.1 ± 12.9 131.3 ± 33.2 26.4 ± 8.8 14.7 ± 8.5 10.3 ± 5.0 331.7 ± 245.7 36.9 ± 5.8
Corner Brook P & P 127.8 ± 27.1 181.2 ± 41.9 49.6 ± 21.9 45.9 ± 17.6 37.3 ± 15.1 206.2 ± 202.9 127.1 ± 40.5
Mean 1 888.5 506.6 220.6 174.1 132.8 695.0 217.9
Major emitters 2 1006.1 510.2 304.8 325.6 295.4 746.1 304.8
Percentage of major emissions 3 22.8% 1.9% 42.0% 59.3% 67.3% 14.2% 27.8%
1 Mean of all releases in each mill and in each pollutant. 2 Mean of all releases in each mill considering only those > 100 tonnes/year. 3 Percentage of all releases considering only
those > 100 tonnes/year. 

Pollutants 2022, 2 146
3.3. Comparison with Thresholds
Figure 5a shows the mean DRT (Table 1) observed for every pollutant and for the entire
period for all sites. PM2.5 and PM10 were often orders of magnitude higher than thresholds,
sometimes above 3000% and in some cases above 6000% prior to 2016. This decreased
to <2000% after 2016. However, it is likely that this difference is heavily influenced by
NP emissions, observed in Figure 3c,d. The dramatic reduction observed in 2017 at NP
was likely due to a precipitator installation in 2016, which was intended to reduce PM
emissions [29,45,47]. Other pollutants exhibited a more stable behavior, with values within
1000% of the reporting threshold for the study period. DRT for all mills for each year,
averaged across all pollutants, is shown in Figure 5b. NP consistently reported higher
thresholds for all pollutants, especially prior to 2017, which was as much as 100,000%
above the reporting PM thresholds in some years. From 2017, NP emissions still exceeded
reporting thresholds by ~20,000% on average across all pollutants. Those values are
comparable to other pulp mills, which appear to release more pollutants compared to
the three paper mills (HA, UT, and IA) and the P&P mill (CB), where releases were on
average <10,000% above threshold values. Even though HA changed its operation from
pulp to paper in 2012, it did not seem to have a substantial impact on overall pollutant
releases. Figure 5c shows the DRT averaged over the period, discriminated by site and
pollutant. Again, major pollutants were PM2.5 and PM10 at NP, which were 100,000% above
thresholds for the entire period. For pulp mills, PM2.5 was the principal pollutant higher
than the threshold, being ~4000% above, followed by PM10 at ~3000% over the threshold.
At CB, PM2.5 and PM10 releases were ~2000% above threshold, showing that releases from
these P&P mills were not as high as other pulp mills but were higher than paper mills. For
other pollutants and mills, differences from thresholds were <1000%.
Pollutants 2022, 2, FOR PEER REVIEW 12 
Figure 5. Mean difference from reporting thresholds (DRT) over (a) the sites, (b) the pollutants, and 
(c) the entire period. White represents no data. 
The difference from the ARL on the CPMAEPFF for TPM and SO2 is presented in 
Figure 6. For TPM, all mills emitted under the limit suggested (~70%) and with a low dis￾persion (~10%) for the entire period, except for NP. The TPM exceedance in NP was as 
high as ~300%, twice in the period, and only below ARL after 2016. NP had the highest 
mean exceedance of 99.1% and the highest standard deviation exceedance of 117.7% above 
ARL. In contrast, NP presented the lowest standard deviation of exceedance (16.7%) and 
the lowest mean exceedance (−85.7%) for SO2 emissions. IP and UT presented the highest 
annual exceedance of ~200% and ~350%, respectively, and both were at the beginning of 
the study period. The highest standard deviation exceedance was in UT with 116.4%, fol￾lowed by IP with 87.6%. ED had a mean of exceedance 0.6% and a standard deviation 
exceedance of 18.6%, which indicated that ED was close to the exceedance limit during 
the entire study period. After 2008, most mills emitted below the CPMAEPPF ARL or were 
comparable.
Figure 5. Mean difference from reporting thresholds (DRT) over (a) the sites, (b) the pollutants, and
(c) the entire period. White represents no data.
The difference from the ARL on the CPMAEPFF for TPM and SO2 is presented in
Figure 6. For TPM, all mills emitted under the limit suggested (~70%) and with a low
dispersion (~10%) for the entire period, except for NP. The TPM exceedance in NP was as
high as ~300%, twice in the period, and only below ARL after 2016. NP had the highest 

Pollutants 2022, 2 147
mean exceedance of 99.1% and the highest standard deviation exceedance of 117.7% above
ARL. In contrast, NP presented the lowest standard deviation of exceedance (16.7%) and
the lowest mean exceedance (−85.7%) for SO2 emissions. IP and UT presented the highest
annual exceedance of ~200% and ~350%, respectively, and both were at the beginning of the
study period. The highest standard deviation exceedance was in UT with 116.4%, followed
by IP with 87.6%. ED had a mean of exceedance 0.6% and a standard deviation exceedance
of 18.6%, which indicated that ED was close to the exceedance limit during the entire study
period. After 2008, most mills emitted below the CPMAEPPF ARL or were comparable.
Pollutants 2022, 2, FOR PEER REVIEW 13 
Figure 6. Percentual difference from the ARL on the CPMAEPPF for (a) TPM and (b) SO2. Pulp mills 
are represented by a solid line and paper mills by a dotted line. The black dotted line represents the 
mean on all mills and the black slashed line represents when a release equals the threshold sug￾gested by CPMAEPPF. 
4. Discussion 
All mills in Atlantic Canada are located in or near urban areas (<5 km away, see Ap￾pendix A) and have air emissions well above NPRI reporting thresholds for a suite of 
pollutants, meaning that local populations (including mill workers) are regularly exposed 
to air pollutants emitted by mills regardless of prevailing winds. The intensity and dura￾tion of air pollutant exposure on populated centres distant from the mill depend on how 
frequently winds blow from the mill towards nearby towns, which cannot be determined 
by using only annual NPRI data. No P&P mill studied significantly reduced their mean 
annual air emissions (pollutant means) in the 17 years of analysis, as has been observed 
in other facilities [15,18]. The only exception (although still above reporting thresholds 
and higher than other pulp mill releases) was NP, which dramatically reduced PM emis￾sions after installing a precipitator, which resulted in emissions of similar magnitude com￾pared to other pulp mills in Atlantic Canada (Figure 5). Techniques to reduce emissions 
can be hard for industries to implement due to high costs [28] and the challenge of ade￾quately planning the improvements, as they depend both on the source of energy used 
and technology for upgrades [38]. In this case, NP could effectively reduce PM emissions 
with the incorporation of a recovery boiler [29].
While the use of NPRI has increased in the last decade, in part because of its open 
access and the addition of new pollutants, its limitations may undermine its usefulness 
[14]. Among the limitations that prevent NPRI from being widely used are issues with its 
completeness, data quality, and inventory comprehensiveness [5,14,15,18]. Most NPRI us￾ers are interested in air emissions, geospatial analysis of emissions, and environmental 
monitoring [14]. Therefore, the completeness of the repository, where yearly releases are 
always included (regardless of whether they are below the NPRI lower threshold or not), 
is essential to generate a proper mapping of emissions and to compare how they evolve 
over time. Moreover, high-quality data where industries not only estimate but accurately 
Figure 6. Percentual difference from the ARL on the CPMAEPPF for (a) TPM and (b) SO2
. Pulp mills
are represented by a solid line and paper mills by a dotted line. The black dotted line represents the
mean on all mills and the black slashed line represents when a release equals the threshold suggested
by CPMAEPPF.
4. Discussion
All mills in Atlantic Canada are located in or near urban areas (<5 km away, see
Appendix A) and have air emissions well above NPRI reporting thresholds for a suite of
pollutants, meaning that local populations (including mill workers) are regularly exposed to
air pollutants emitted by mills regardless of prevailing winds. The intensity and duration of
air pollutant exposure on populated centres distant from the mill depend on how frequently
winds blow from the mill towards nearby towns, which cannot be determined by using
only annual NPRI data. No P&P mill studied significantly reduced their mean annual
air emissions (pollutant means) in the 17 years of analysis, as has been observed in other
facilities [15,18]. The only exception (although still above reporting thresholds and higher
than other pulp mill releases) was NP, which dramatically reduced PM emissions after
installing a precipitator, which resulted in emissions of similar magnitude compared to
other pulp mills in Atlantic Canada (Figure 5). Techniques to reduce emissions can be hard
for industries to implement due to high costs [28] and the challenge of adequately planning
the improvements, as they depend both on the source of energy used and technology for
upgrades [38]. In this case, NP could effectively reduce PM emissions with the incorporation
of a recovery boiler [29].
While the use of NPRI has increased in the last decade, in part because of its open
access and the addition of new pollutants, its limitations may undermine its usefulness [14]. 

Pollutants 2022, 2 148
Among the limitations that prevent NPRI from being widely used are issues with its
completeness, data quality, and inventory comprehensiveness [5,14,15,18]. Most NPRI
users are interested in air emissions, geospatial analysis of emissions, and environmental
monitoring [14]. Therefore, the completeness of the repository, where yearly releases are
always included (regardless of whether they are below the NPRI lower threshold or not), is
essential to generate a proper mapping of emissions and to compare how they evolve over
time. Moreover, high-quality data where industries not only estimate but accurately report
emissions, as well as enforced regulation, would allow better environmental assessments.
Reporting NPRI data alone is not enough to assure a decrease in pollutant emissions.
Although NPRI annual release data are designed to protect human and environmental
health, the releases are not regulated; therefore, the high emissions of potentially harmful
pollutants are not reduced. Huge variations were observed in emission releases, with
some reported just above NPRI release thresholds, whereas other emissions were reported
>100,000% above the threshold (e.g., PM in NP). Reporting thresholds appear to have little
to no influence on the adaptive management of P&P operations when PM emissions are
20, 1000, or even 50,000 times higher than the reporting threshold. This raise concerns
over when releases pose potential threats to human or environmental health, as it is
tremendously difficult to understand the contribution of these emissions to local or regional
air quality and from there to understand human exposures. This information is not currently
available, and a lower limit without a corresponding upper limit does not provide the
protection intended for human and environmental health. Even when data to identify
potential harmful releases are publicly available, if no action is taken to reduce high
emissions, it is unlikely that the problem will be addressed. Air emissions from all facilities
together, especially when they are in close proximity to each other, are an accumulative
source of air pollutants that can induce potential harm to ecosystems and human health.
There is a lack of standardization in how emissions are reported, due to differences
in units of measurement, different permissions depending on the jurisdiction, and on the
characteristics of the industry [18,49]. Air releases for P&P mills on NPRI are reported in
tonnes/year, so a comparison with CAAQS is not simple nor direct as more information
is needed to convert the release in tonnes to an emission rate (i.e., ambient temperature,
pressure, and gas flow [54]). Consequently, NPRI does not seem to be a tool that effectively
informs industrial performance but is rather an accounting tool that is not linked to the
enforcement of air quality standards or the enhancement of air quality for populations
living in and around the mills. Considering that most of the time all mills exceeded the
reporting thresholds, it would be helpful to compare how hazardous those releases are
with the inclusion of an upper limit or threshold or change the unit of reporting to enable
the comparison with other standards and countries. Moreover, it would be helpful to
compare how much mills are emitting relative to their annual pulp or paper production.
If it was possible to determine a ratio of production to release, such as tonnes of pulp
produced as a function of emissions, it would be possible to identify an unsustainable or
inefficient facility, which could be an indicator of outdated technology or poor management
practices. Another issue of this reporting inventory is that the indicators are relatively
crude measures of air pollution and do not provide insight into the toxicity of emissions.
In addition, some meteorological conditions (such as inversions or the direction of the
prevailing winds) or topographical features (such as a valley or hill) may increase the
impact of air pollution, which could be accumulated not only by different sources but
also by intrinsic characteristics of the location. Thus, exceeding a reporting threshold
has an impact not only on the point location of the release but it also has the potential
of affecting the surrounding environment (depending on the meteorological conditions
and the topography) and of combining with other mill’s releases (which can increase the
toxicity of emissions either by accumulation or because of chemical reactions).
In [5], the industries reporting NPRI within 2.5 km of children’s houses had mean
annual releases of 31.8 tonnes for PM2.5 and 788.0 tonnes for SO2. When they only con￾sidered the ‘major emitters’ (annual releases above 100 tonnes), mean releases increased 

Pollutants 2022, 2 149
to 290 tonnes/year for PM2.5 and 1350 tonnes/year for SO2. Mean releases from all P&P
mills in Atlantic Canada (Table 5) show that all PM2.5 releases in the P&P mills are four
times higher in comparison to the findings of [5] and of similar a magnitude when only
major emitters are considered. Conversely, SO2 mean releases from P&P in Atlantic Canada
(Table 5) are similar to those reported in [5], but when we consider the major emitters, the
industries in Quebec are almost twice as high as P&P mills in Atlantic Canada.
If the criteria of ‘major emitters’ were applied to this study, all pulp mills would exceed
this threshold. Only UT and IA (both paper mills) would not be considered major emitters
for most air pollutants, and CB and HA may fall in the major emitters category dependent
on the pollutant and on the year considered. Pulp mills seem to pollute more than paper
mills, and the P&P facility falls in the middle. This result is consistent with Tong et al.
(2018) [36], who compared emissions from five mills in China and found that gaseous
pollutants emitted from pulp mills are greater than those from paper mills. To reduce
the pollution caused by pulping, they suggested recycling wastepaper. The threshold of
100 tonnes/year for PM2.5 and SO2 discussed in [5] was previously introduced by [55],
although there is a lack of justification for using these criteria. Regardless, this threshold is
used in this study to analyze P&P air emissions considering that there are no standards or
regulations to compare with annual emissions in tonnes. This absence of regulation shows
the need for a standard that could be used to inform how hazardous air emissions from
different sources can be and to identify when action is needed to reduce the impact on
human health and the environment.
When the releases are compared to the threshold suggested on CPMAPPF, the behav￾iors of pulp and paper mills do not follow a clear pattern. Instead, emissions depend on the
total production of the facility more than on the type of process carried out in the mill. Even
though the CPMAPPF threshold is more permissive for SO2 releases than for TPM, the
mills are closer to the SO2 threshold and surpass it more frequently. In contrast, most of the
mills emit TPM well below the limit, with NP being the exception exceeding the threshold
with a mean of ~100% over the threshold during the entire period. The emission limits
and best practices recommended in CPMAPPF are still voluntary. As chemical facilities
produce more pollution than the mechanical facilities due to the nature of the processes,
they are ‘allowed’ to emit more, i.e., four times more for TPM and almost three times more
for SO2 emissions. However, the lack of enforcement can deter chemical facilities from
adopting cleaner technologies, which can seem unfair to mechanical facilities that have a
more stringent recommendation.
One strategy to regulate high emissions is applying fines or incentives. Incentives
could include emission reductions through discounts on CO2 taxes or the ability to draw
from specific funds for upgrading technology. Although historically fines have not been
consistently imposed on facilities that exceed thresholds, they can be an effective tool when
implemented properly [49]. It has been suggested that “fines must be higher than the
cost to the most outdated mill of installing the technology necessary to reach compliance
levels” [33] and that to “achieve emissions reductions, threats of monitoring and actual
enforcement have proven to be most effective” [15]. Both suggestions support the idea of
strongly disincentivize high emissions (if not voluntary) by making it impossible financially;
it would be more affordable to update the equipment and the facility’s technology rather
than paying fees for not complying with emission limits. Another important suggestion
made by [33] is to increase the stringency on ‘hot spots’, sites where many mills are close to
one another and were limiting each one independently may not be enough to protect human
and environmental health. This type of regulation could be extremely important for some
sites in Atlantic Canada where different industries are located close to each other and near
populated centers. For example, in Saint John, New Brunswick, there are two P&P mills
as well as a refinery within the city. Moreover, in the cities Nackawic-Madawaska, there
are two P&P mills, one on either side of the Canada–United States border, located within
2 km of each other. As facilities are under different regulations, it seems that sometimes an
exceedance in the emission rate regulation is not enforced [56]. 

Pollutants 2022, 2 150
In summary, the existence of limits in air emissions is confusing and too flexible.
Industries that do not follow recommendations or that are high emitters are not punished
in most of the cases. The lack of annual compliance standards reduces the utility of NPRI,
as this single database is not enough to determine how industries are performing towards
health environmental protection.
5. Conclusions
The air releases of CO, NOx, TPM, PM2.5, PM10, SO2, and VOCs were compared for
the three provinces in Atlantic Canada with pulp and paper mills in a 30-years period
(the longest period of APEI data available) and from the nine mills operating in Atlantic
Canada from 2002 to 2019 (the longest period of NPRI data available). Annual releases
were compared to reporting thresholds established by ECCC, but neither mills nor ECCC
provide a precise quantity released to the atmosphere, as the reports are annual estimates.
As NPRI reports in tonnes/year, a regulation or threshold in this unit of measure seems
necessary to compare with industrial emissions, as NPRI has a lower threshold for report
emissions but lacks an upper threshold to limit emissions. While the lower threshold is
surpassed most of the time (often by thousands of times), the lack of an upper limit results
in misinformation about when those releases are harmful and may be considered a threat
to human and environmental health. The recommended emission limit in the code for best
practices for P&P, CPMAPPF, is not always followed by the mills as it is not compulsory.
Thus, even when there are inventories accessible to the population and recommendations
for industries to follow, there is no enforcement nor penalty for the facilities that emit above
the safe recommended limit. A more detailed analysis using other sources of data with an
hourly measurement, such as the National Air Pollution Surveillance program from ECCC,
would be valuable to determine how the pollutants are emitted throughout the year. As
the only air pollutants that are regulated by federal legislation through CAAQS are O3,
NO2, SO2, and PM2.5, a future analysis could only evaluate compliance with regulation for
those parameters.
Author Contributions: Conceptualization and methodology, G.G. and T.R.W.; formal analysis, G.G.;
writing—original draft preparation, G.G.; writing—review and editing, T.R.W., D.G.R. and C.B.;
visualization, G.G.; supervision, T.R.W.; funding acquisition, G.G. All authors have read and agreed
to the published version of the manuscript.
Funding: This research was funded through graduate scholarships by Agencia Nacional de Inno￾vación e Investigación (ANII) and by the Canadian Standards Association (CSA).
Institutional Review Board Statement: Not applicable.
Informed Consent Statement: Not applicable.
Data Availability Statement: All primary data can be found on the publicly accessible NPRI web￾site at https://www.canada.ca/en/services/environment/pollution-waste-management/national￾pollutant-release-inventory.html and on the publicly accessible APEI website at https://data-donnees.
ec.gc.ca/data/substances/monitor/canada-s-air-pollutant-emissions-inventory/.
Conflicts of Interest: The authors declare no conflict of interest.
Appendix A
Appendix A.1. Pulp Mills
Appendix A.1.1. Northern Pulp
In New Glasgow, NS, a Kraft pulp mill operated from 1967 to 2020. The closure
occurred on January 2020 due to a lack of Ministerial approval of the Environmental
Assessment for a proposed new effluent treatment facility [57]. The mill operator claimed
that they did not have enough time to compile an adequate environmental assessment prior
to the closure, as the measures they initially proposed were not accepted by the provincial
government [45,58]. Scott Paper first owned and operated the mill in 1967. In 1995, it was 

Pollutants 2022, 2 151
acquired for Kimberley-Clark and nine years later for Neenah Paper. In 2008, the mill was
acquired by Northern Resources and was renamed Northern Pulp. Finally, it has been a
property of Paper Excellence since 2011 [59,60]. Even though technology advances very
quickly, the basis in elaborating paper have not changed significantly in the last century [61].
Before its closure, NP employed 330 fulltime workers and around 2000 indirect jobs across
NS [62]. Annually, it produced 280,000 tonnes of Bleached softwood Kraft. On the north
shore of the Pictou Harbour and 1 km away, NP is Pictou, a town of 3107 inhabitants [63].
Ten kilometres south of NP is New Glasgow, a town of 9471 people [63].
Appendix A.1.2. Irving Pulp & Paper Limited
Irving Pulp & Paper, a kraft pulp mill in Saint John, NB, is managed by Irving Ltd. [64].
The products are bleached softwood and hardwood kraft for premium tissue products. The
mill opened in 1851 as The Cushing Sulphite Fibre Company, and in 1910, it became the
Edward Partington Pulp and Paper Company. In 1932, the mill became Port Royal Pulp.
Finally, 14 years later, in 1946, K.C. Irving purchased the mill, making some modernizations
to increase the capacity of production [64]. The mill employs more than 330 workers and
produces 335,000 tonnes per year. It is located near the Bay of Fundy within the city of
Saint John of 69,895 inhabitants [63].
Appendix A.1.3. Twin Rivers
The pulp mill located in Edmundston, NB, built in 1916, has operated for more than
100 years. Twin Rivers was acquired in 2013 by Atlas Holdings and Blue Wolf Capital
Partners. Apart from the pulp facility, the company owns a lumber mill in NB and three
paper mills in the United States. The pulp mill in Edmundston produces bleached softwood
sulphite and bleached groundwood pulp as well as 45 MK of biomass cogeneration of
electricity sold to New Brunswick Power [65]. Its production capacity is 370,000 tonnes per
year and employs more than 280 workers. The mill is located in the shore of the St John
River in the city of Edmundston, of 16,437inhabitants [63]. Across the river and the United
States–Canada border, a paper mill also operated by Twin Rivers company is installed in
Madawaska, a city with a population estimated at 3735 for 2019 [66].
Appendix A.1.4. Nackawic and Atholville
Both pulp mills have operated in NB for around 19 years and are owned by AV Group
NB, a company established in 1977. The cellulose pulp produced in both mills is used
in the manufacture of textile. The final products are home and apparel textile made of
viscose staple fibre as well as non-woven textiles [67]. The company manages 1.6 million
acres of company-owned and Crown land. In total, they employed around 1200 people
directly and many more indirectly [68]. The Nackawic mill is located at northeast in the
town of Nackawic, which has a population of 962 [63]. The Atholville mill is on the shore
of Atholville village, within the town of Campbellton with a population of 7047 [63].
Appendix A.2. Paper Mills
Appendix A.2.1. Port Hawkesbury Paper
Initiated in 1962 in NS as a sulphate pulp mill owned by Stora, it was sold to NewPage
in 2007. After its closure four years later, it reopened as the property of Stern Partners and
Wayne Nystrom as a paper mill in 2012 [69,70]. Located 2 km south of Port Hawkesbury,
a town of 3210 inhabitants [63], it employs around 300 people directly and near 400 as
contractors across the province and manages around 523,000 ha of public land. The mill can
produce 400,000 tonnes of paper annually to be used in catalogs, magazines, retail inserts,
and wrapping paper [71]. 

Pollutants 2022, 2 152
Appendix A.2.2. Lake Utopia Paper and Irving Pulp and Paper
Both paper mills are operated by Irving Ltd. Lake Utopia Paper in NB produces
high-quality corrugated medium since 1972. Their product comprises around two-thirds of
virgin hardwood fibre and one-third of recycled cardboard [72]. The final consumers for
box packaging are food, beverage, agriculture, and electronic sector. Its annual capacity
is 185,000 tonnes, and it employs around 140 workers directly. They designed a biomass
boiler project and a new effluent treatment plant to improve environmental impact due
to emissions [73]. Irving paper produces specialty grade papers for flyers and magazines.
They also supply rotogravure for commercial printing [74]. Irving paper can produce
420,000 tonnes per year and has about 310 employees. Only 5 km away from Irving Paper,
Irving Pulp and Paper is also located within the city near the shore of the Bay of Fundy, but
on the west side of the St John River. Lake Utopia Paper is around 65 km east from Saint
John city. The nearest towns are Pennfield, of 2222 inhabitants, around 5 km south of the
mill and Saint George with a population of 2495 and around 7 km southeast of the mill [63].
Appendix A.3. Pulp and Paper Mill
Corner Brook Pulp & Paper Limited
In NL, paper began to be produced almost a century ago in 1923. After a couple of
owners at the end of 1984, the Kruger organization acquired the mill, naming it as Corner
Brook [75]. The company manages 1.4 ha of forest land but only half of it is a productive
forest. They are constantly performing surveillance audits, have made some upgrades
in the technology, and have a detailed environmental and commitment plan. Around
1750 workers are employed in the woodland department [76]. The mill is located in the
north coast of the city Corner Brook, a city of 19,333 inhabitants [63].
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