Science of the Total Environment 644 (2018) 675–682

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Polycyclic Aromatic Hydrocarbons (PAHs) and nitrated analogs
associated to particulate matter emission from a Euro V-SCR engine
fuelled with diesel/biodiesel blends
Guilherme C. Borillo a, Yara S. Tadano b, Ana Flavia L. Godoi a, Theotonio Pauliquevis c, Hugo Sarmiento a,
Dennis Rempel d, Carlos I. Yamamoto e, Mary R.R. Marchi f, Sanja Potgieter-Vermaak g,h, Ricardo H.M. Godoi a,⁎
a Environmental Engineering Department, Federal University of Paraná, Curitiba, PR, Brazil
b Mathematics Department, Federal University of Technology Paraná, Ponta Grossa, PR, Brazil
c Federal University of São Paulo, Diadema, Brazil
d Institute of Technology for Development, Lactec, Curitiba, PR, Brazil
e Chemical Engineering Department, Federal University of Paraná, Curitiba, PR, Brazil
f Analytical Chemistry Department, Institute of Chemistry, São Paulo State University - UNESP, Araraquara, SP, Brazil
g Division of Chemistry and Environmental Science, School of Science and the Environment, Manchester Metropolitan University, Manchester M15 6HB, United Kingdom
h Molecular Science Institute, School of Chemistry, University of the Witwatersrand, Johannesburg 2000, South Africa
H I G H L I G H T S G R A P H I C A L A B S T R A C T
• Unregulated carcinogenic emission
from heavy-duty engine with SCR
aftertreatment

• PM sampling using Biodiesel blends and
13 steady-state engine operation cycle

• The synergic effect of biodiesel/SCR re-
duces PAHs and Nitro-PAHs particle
emission.

• The tested SCR system does not appear
to promote PAHs nitration.

• Biodiesel additionmay reduce the emis-
sion toxicity and the risk to human
health.
⁎ Corresponding author at: Environmental Engineering
E-mail address: rhmgodoi@ufpr.br (R.H.M. Godoi).

https://doi.org/10.1016/j.scitotenv.2018.07.007
0048-9697/© 2018 Elsevier B.V. All rights reserved.
a b s t r a c t
a r t i c l e i n f o
Article history:
Received 3 June 2018
Received in revised form 28 June 2018
Accepted 1 July 2018
Available online 11 July 2018

Editor: Jianmin Chen
Among the new technologies developed for the heavy-duty fleet, the use of Selective Catalytic Reduction (SCR)
aftertreatment system in standard Diesel engines associated with biodiesel/diesel mixtures is an alternative in
use to control the legislated pollutants emission. Nevertheless, there is an absence of knowledge about the syn-
ergic behaviour of these devices and biodiesel blends regarding the emissions of unregulated substances as the
Polycyclic Aromatic Hydrocarbons (PAHs) andNitro-PAHs, both recognized for their carcinogenic andmutagenic
effects on humans. Therefore, the goal of this study is the quantification of PAHs and Nitro-PAHs present to total
particulate matter (PM) emitted from the Euro V engine fuelled with ultra-low sulphur diesel and soybean bio-
diesel in different percentages, B5 and B20. PM samplingwas performed using a Euro V – SCR engine operating in
European Stationary Cycle (ESC). The PAHs andNitro-PAHswere extracted fromPMusing anAccelerated Solvent
Extractor and quantified by GC–MS. The results indicated that the use of SCR and the largest fraction of biodiesel
studied may suppress the emission of total PAHs. The Toxic Equivalent (TEQ)was lower when using 20% biodie-
sel, in comparison with 5% biodiesel on the SCR system, reaffirming the low toxicity emission using higher per-
centage biodiesel. The data also reveal that use of SCR, on its own, suppress the Nitro-PAHs compounds. In
Keywords:
Selective Catalytic Reduction (SCR)
Diesel emissions
Biodiesel
Polycyclic Aromatic Hydrocarbons (PAHs)
Department, Federal University of Parana, 210 Francisco H. dos Santos St., Curitiba, PR 81531-980, Brazil.

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676 G.C. Borillo et al. / Science of the Total Environment 644 (2018) 675–682
general, the use of larger fractions of biodiesel (B20) coupled with the SCR aftertreatment showed the lowest
PAHs and Nitro-PAHs emissions, meaning lower toxicity and, consequently, a potential lower risk to human
health. From the emission point of view, the results of this work also demonstrated the viability of the Biodiesel
programs, in combination with the SCR systems, which does not require any engine adaptation and is an eco-
nomical alternative for the countries (Brazil, China, Russia, India) that have not adopted Euro VI emission
standards.

© 2018 Elsevier B.V. All rights reserved.
Nitro-PAHs
Toxic Equivalent (TEQ)
1. Introduction

Diesel engine exhaust emissions were classified as a carcinogen by
the International Agency for Research on Cancer (IARC) in 2013, thereby
increasing the prior challenges that policymakers in several countries
face (Diaz-Sanchez et al., 1994; Lighty et al., 2000; Ravindra et al.,
2008; Reşitoğlu et al., 2015; Zielinska et al., 2004). Polycyclic Aromatic
Hydrocarbons (PAHs) and Nitro-PAHs (nitrated PAHs) are the most
toxic compounds among the complex mixture of gases and particles
that comprise Diesel engine exhaust aerosols (Hu et al., 2013; HHS
USA, 2004; Slezakova et al., 2013; Wang et al., 2013; Yilmaz and Davis,
2016). Composed of two or more fused aromatic rings, these organic
compounds have been tested for their carcinogenic activity by the
IARC, with benzo[a]pyrene being classified as group 1 (carcinogenic to
humans), by this agency. Dibenzo[a,l]pyrene is considered as probably
carcinogenic to humans (group 2A) and dibenzo[a,i]pyrene and
dibenzo[a,h]pyrene as possibly carcinogenic to humans (group 2B)
(IARC, 2018; Zielinska et al., 2004). When these compounds are associ-
ated with diesel/biodiesel blends exhaust particle-phase emissions,
which are characterized by high concentrations of fine particulate mat-
ter (PM2.5) (Guan et al., 2017; He, 2016), there is an intensification of
many acute and chronic cardiopulmonary diseases, including asthma,
respiratory system inflammation and lung cancer (Martin et al., 2017;
HHS USA, 2004; Ravindra et al., 2008).

Current emission regulations implemented in the United States of
America (U.S.) and European Union (EU), US 2010 and Euro VI, respec-
tively, adopt a limit for NOx and PM emission that is ten times lower
than the levels allowed in 2000. Countries where these emission limits
are enforced and implemented (U.S., EU, Canada, Japan and South
Korea) project a 26-fold reduction in PM emissions by 2045 (Posada
et al., 2016). On the other hand, Brazil, Russia, India, China, Australia
and Mexico whose gross domestic product heavily depends on heavy-
duty vehicle transport, have yet to fully implement the equivalent emis-
sion standards, even though the increased risks are acknowledged.
These regulations require extensive deployment of advanced engine
tuning, the addition of two or more aftertreatment devices and the
use of low sulphur diesel content, therefore potentially fleet renova-
tions. Instead, these countries still enforce the Euro V and equivalent
regulations where Selective Catalytic Reduction (SCR) or Exhaust Gas
Recirculation (EGR) aftertreatment systems remain the main strategies
to reduce NOx and PM emission (Du and Miller, 2017).

As an additional strategy to reduce pollutants from Diesel vehicles,
many countries like Canada, Australia, Brazil, China and Germany are
promoting the development, production and use of alternative fuels
(biofuels and natural gas) seeking a better balance to fuel economy
and thereby improving green freight programs in the long term (Du
and Miller, 2017). Biodiesel is already used in several countries and
seems to be a promising alternative, as it can be used in diesel engines
without major modifications. Despite the high cost of production
when compared to diesel, biodiesel can qualitatively and quantitatively
reduce regulated pollutant emissions (He et al., 2010; Ratcliff et al.,
2010; Sadiktsis et al., 2014). Several researches successfully demon-
strated a consistent reduction for hydrocarbons (HC), PM and carbon
monoxide (CO) emissions while recognizing an increase in nitrogen di-
oxide (NOx) when biodiesel is used (He, 2016; Ravindra et al., 2008;
Sadiktsis et al., 2014). On theother hand, there is no agreementwhether
the biodiesel promote or not a reduction on PAHs and Nitro-PAHs emis-
sions. Guarieiro et al. (2014) concluded that the biodiesel additions de-
crease PAHs emissions, which is in agreement with the conclusions
made by He et al. (2010), Lim et al. (2014) and Yilmaz and Davis
(2016). Westphal et al. (2013) tested PAHs emissions using a turbo-
intercooled engine with 6 cylinders operating in the European Station-
ary Cycle (ESC) fuelled with hydrotreated vegetable oil and jatropha
methyl ester. The authors also demonstrated a slight reduction in
PAHs emission when low percentages of biodiesel were added and
showed that toxicological effects depend on the biodiesel origin. Casal
et al. (2014) tested a Euro III engine fuelled with standard diesel (B0),
B5 (5% biodiesel) and B20 (20% biodiesel) and concluded that biodiesel
mixed with diesel increases the production of PAHs and Alkyl PAHs in
the engine exhaust emissions.

Changes in fuel alone are however not sufficient to meet the new or
the old standards and use of aftertreatment systems is crucial. The SCR
system is still the most widely used in many countries, due to its selec-
tivity to reduce NOx emissions (Tadano et al., 2014). The injection of
urea and a catalyst ensures reductions of up to 90% in NOx emissions,
through a reduction reaction of NOx and NH3 resulting in nitrogen and
water (Amanatidis et al., 2014; Bacher et al., 2015). Nevertheless, SCR
technology is not without its challenges, such as the emission of NH3,
stoichiometric disproportion of urea consumption, cost, and deactiva-
tion of the catalyst by deposition (Cheruiyot et al., 2017). The best re-
ported SCR efficiency is achieved at high engine loads and
temperatures (approximately 400 °C) (Cheruiyot et al., 2017). However,
the added urea increases the probability of unintended formation of
Nitro-PAHs through PAHs nitration (Liu et al., 2015).

The combination of low sulphur fuels (ultra-low sulphur diesel-
ULSD), new engine technologies, aftertreatment systems (SCR, EGR,
DOC – Diesel oxidation catalyst, DPF – Diesel particulate filter) and the
use of biofuels are the current strategy to achieve the regulatory reduc-
tions worldwide (Wang et al., 2009; Ratcliff et al., 2010; Carrara and
Niessner, 2011; Hu et al., 2013; Sadiktsis et al., 2014; Reşitoğlu et al.,
2015; He, 2016). However, there is insufficient knowledge and some
disagreement in open literaturewith regards to the potential synergistic
effect on unregulated emissions by vehicles equipped with SCR and the
use of different biodiesel blends.

This paper describes the PAHs and Nitro-PAHs emission concentra-
tions from a Diesel engine, which is in compliance with the standard
emissions determined in PROCONVE P7/Euro V. Furthermore, the po-
tential synergistic effect of the SCR after-treatment and the use of differ-
ent soybean biodiesel blends (B5 and B20) on emissions have been
investigated. Those pollutants are not regulated worldwide, even
though they are proven to present several harmful effects on human
health.

2. Material and methods

2.1. Sampling and engine parameters

The engine emission tests were performed at the Lactec Institute's
Laboratory for Vehicular Emissions in partnership with the Federal Uni-
versity of Paraná, Curitiba, Brazil. The tested engine is currently used in
trucks andbuses around theworld, and has an individual four-valve cyl-
inder head, cross-flow arrangement, common rail injection and SCR



677G.C. Borillo et al. / Science of the Total Environment 644 (2018) 675–682
aftertreatment system. The test engine fulfils the European Union Reg-
ulation (Directive 2005/55/EC of the European Parliament and of the
Council of 28 September 2005) requirements for Euro V emission stan-
dards with a urea-SCR system and is in accordance with the P7 phase of
the PROCONVE (Vehicular Air Pollution Control Program) in Brazil. The
engine details are specified in Table 1.

The engineworks in conjunctionwith a dynamometer and a data ac-
quisition system, both fromAVL (Graz, Austria) to perform the emission
and engine parameters measurements. The dynamometer can absorb
power up to 440 kW at 6000 rpm and a torque of 2334 Nm at
1200–1600 rpm. The European Steady Cycle (ESC)was selected as driv-
ing cycle for the dynamometer operation to allow PM sampling. It was
designed to achieve high load factors and very high temperature on
the exhaust gas (Ericsson, 2001; Mock et al., 2012). The PM emission
is collected over a sequence of 13 steady-statemodes of load and engine
speed. The sampling time was 28 min per cycle. In each mode the ex-
haust flow and the power are also measured, which are used as
weighting parameters for the conversion of the results to g kWh−1.
Sixty-five percent of the calculated emission responds to load and en-
gine speed above 50%. That is conservative and captures most of the
stop-and-go conditions of the drive cycle experienced by urban buses
in rush hours (Tadano et al., 2014).

The PM sampling was performed using an AVL dilution system
(Smart Sampler SPC 472 - Graz, Austria). This systemprevents filter sat-
uration, reduces the exhaust temperature and adjusts the dilution ratio.
The sampling equipment has two filter supports, arranged in sequence,
to achieve higher PM retention. The sampling flow rate collected into
PM sampler from the engine exhaust was 1.5 g s−1 and the dilution
air was adjusted to obtain a diluted exhaust gas temperature, measured
just before the primary filter, of 325 K (52 °C) in eachmode. The dilution
ratio should not be b4.

For PAHs andNitro-PAHs analysis, total PMwas collected on two bo-
rosilicate glass fiber filters, 70 mm of diameter, coated with fluorocar-
bon (Pallflex T60A20 fiberfilm). The filters were weighted prior and
after the sampling using a Sartorius micro-balance (MSA2.7S-000-DF -
Goettingen, Germany) following the NIOSH method 5000 and were
stored below−18 °C in cleaned glass containers until analysis. To certify
the correct function of SCR system, the NOx emissions were measured
in-line by a SESAM i60 FT, Fourier transform infrared (FTIR) multi-
component measurement system from AVL (Graz, Austria). In addition,
the catalyst temperature was monitored to archive the best operation
condition. Table S.1 shows the experimental conditions set for the
FTIR analysis.

2.2. Fuels

Ultra-Low Sulphur Diesel (ULSD –maximum of 10 ppm or mg kg−1

of sulphur) and soybean biodiesel were used to prepare two mixtures:
B5 (ULSD with 5% of biodiesel) and B20 (ULSD with 20% of biodiesel).
The B5 and B20 fuels were collected in amber glass bottles and stored
protected from light at 25 °C. The fuel samples were previously charac-
terized according tomethods and essays described on American Society
Table 1
Engine specifications.

Specifications

Emission Euro V “heavy duty”/PROCONVE P7
Configuration 4 cylinders, inline
Displacement 4.8 liters
Bore × stroke 105 × 137 mm
Combustion system Direct injection
Injection system Common rail electronic
Aspiration TGV intercooler
Power output 187 hp (139.7 kW) 2200 rpm
Peak torque 720 Nm (73 kgf·m) 1200–1600 rpm
Aftertreatment SCR
for Testing and Materials (ASTM) in Lacaut – Automotive Fuels Labora-
tory (certified on ISO 9001, ISO 14001 and ISO 17025) of the Federal
University of Paraná, Curitiba, Brazil. Table 2 shows the fuel properties
of the biodiesel blend used in this research, tested according with Stan-
dard ASTM Test Methods.

2.3. Extraction

All the 27 sampled filters were extracted, using an Accelerated Sol-
vent Extractor (ASE – Dionex, USA), with dichloromethane and metha-
nol (4:1) at a pressure of 1500 psi and temperature of 120 °C in three
static extraction cycles of 5 min each. The total extracted volume was
concentrated to near dryness with a slight nitrogen flow and recovered
with 1.5 ml of dichloromethane. This procedure has been optimized,
using different temperatures (100, 120, 150 and 180 °C) and extraction
cycles (1, 2 and 3 cycles), based on the ‘EPA’ Standard Operation Proce-
dure (California Standard Operation Procedure - SOP No. 144/2006) for
the determination of PAH in particulate matter using Gas Chromatogra-
phy with Mass Spectrometry (GC–MS). To assess the extraction effi-
ciency, Naphthalene d8 and Benz[a]anthracene-d12 were used as
recovery standards. The recovery, in percentage, of Naphtalene d8 was
slightly lower (65–80%) than the recovery of Benz[a]anthracene-d12
(84–114%).

2.4. Analysis

Samples and standards were analysed in triplicate, using a gas chro-
matograph (Perkin Elmer Clarus 680) coupled to a mass spectrometer
(Perkin Elmer Clarus SQ 8 T Perkin Elmer -Waltham, USA). A fused silica
capillary column (MS-5 30 m × 0.25 mm × 0.25 mm) from Sigma Al-
drich (St. Louis, USA) was used to separate the PAHs and Nitro-PAHs.
Helium was used as carrier gas at a constant flow rate of
1.0 ml min−1. The volume injected was 1.5 μl in splitless mode with a
pressure pulse. The oven temperature was programmed as follows:
1min at 40 °C, heated at a rate of 10 °Cmin−1 to 200 °C andmaintained
for 5min, heated in sequence at a rate of 6 °Cmin−1 to 240 °C andmain-
tained for 10 min and, finally heated to 300 °C at a rate of 10 °C min−1

and maintained for 5 min. The injector temperature, GC–MS interface
and detectorweremaintained at 300 °C, 270 °C and 260 °C, respectively.
Themass spectrometer emission current was set at 350 μA, the electron
energy at 70 eV (nominal) and analysis occurredwith SIM (selected-ion
monitoring) mode.

Acenaphthene-D10, Phenanthrene-D10 and Perylene-D12 (Sulpeco
Analytical - Bellefonte, USA) were used as internal standards. Sixteen
PAHs recognized by USEPA (United States Environmental Protection
Agency) as priority pollutants were analysed: Naphthalene,
Acenaphthene, Acenaphthylene, Anthracene, Phenanthrene, Fluorene,
Fluoranthene, Benzo[a]anthracene, Chrysene, Pyrene, Benzo[a]pyrene,
Benzo[b]fluoranthene, Benzo[k]fluoranthene, Dibenzo[a,h]anthracene,
Benzo[g,h,i]perylene, Indeno[1,2,3-c,d]pyrene. In addition, Benzo[e]
pyrene, Perylene, 1-Nitronaphtalene, 2-Nitrofluorene, 3-
Nitrofluoranthene, 1-Nitropirene and 7-Nitrobenz[a]anthracene were
also analysed (standards solutions supplied by Dr. Ehrenstorfer - Augs-
burg, Germany). The list with all investigated compounds with their re-
spective molecular mass, quantification ion and quantification limits
(LoQ) can be found in Table S.2 of the Supplementary material. Four
Table 2
Fuel properties of B5 and B20 blends.

Property B5 B20 Method

Sulphur, mg kg−1 4 6 ASTM D5453
Cetane number 53.8 51.0 ASTM D6890
Flash point (°C) 45.5 70.5 ASTM D93
Viscosity at 40 °C (mm2 s−1) 3.0 3.2 ASTM D445
Specific mass at 20 °C (kg m−3) 830.5 848.1 ASTM D4052

https://www.google.com.br/search?client=firefox-b&sa=X&biw=1366&bih=604&q=Waltham+assachusetts&stick=H4sIAAAAAOPgE-LUz9U3MMuNLzBS4gAxM6qMTbW0spOt9POL0hPzMqsSSzLz81A4VhmpiSmFpYlFJalFxQApgQyfQwAAAA&ved=0ahUKEwiTpuOwn4DOAhXCC5AKHc9ACNIQmxMIpAEoATAR


678 G.C. Borillo et al. / Science of the Total Environment 644 (2018) 675–682
blank filters were analysed to determine possible interferents. The
method accuracy was verified using the reference material SRM 1650b
from NIST (National Institute of Standards and Technology).

The PAHs and Nitro-PAHs concentrations were tested for significant
differences using Analysis of Variance (ANOVA). For this purpose, “R”
software was used, and significance was determined at a 95% confi-
dence level. The uncertaintieswere calculated using theGuide to the ex-
pression of uncertainty in measurement from the BIPM is an
international organization (JCGM, 2008).

3. Results and discussion

Particle emissions from a Euro V engine, operatingwith andwithout
Selective Catalytic Reduction aftertreatment (SCR-on and SCR-off), and
testing ULSD with 5% of biodiesel (B5) and ULSD with 20% of biodiesel
(B20), were analysed for their PAHs and Nitro-PAHs content. The com-
pounds average concentrations are presented together with their ex-
panded uncertainties at the 95% of confidence level. To the
experiential condition with number of valid samples (n) equal to 1
the uncertainties were estimated using the standard deviation (SD) of
other conditions to the same compound. Which respect to number of
samples, the differentiation between groups of data is connected to dif-
ference in group's mean and the corresponding uncertainties. The best
number of samples (n) is determined by a commitment between
mean, SD and SD of the mean. Consequently, a minimum of 5 samples
were collected for each experimental condition.

3.1. Particle-phase PAHs

Table 3 displays the PAHs emitted from a Euro V engine operating
with an ESC cycle, using two different fuels and after treatment condi-
tions, as well as their respective concentrations (in μg kWh−1).

Only 8 of the 23 quantified PAHs were not detected or were found
below the quantification limit (Anthracene, Chrysene, Benzo[k]fluoran-
thene, Benzo[e]pyrene, Benzo[a]pyrene, Perylene, Indeno[1,2,3-cd]
pyrene, Dibenzo[a,h]anthracene - Table S.2).

Considering the sum of all PAHs, the B5 SCR-off condition had the
highest value among the sampling conditions (3.37 ± 0.56
μg kWh−1), followed by B5 SCR-on (3.13 ± 0.40 μg kWh−1), B20 SCR-
off (2.54 ± 0.28 μg kWh−1) and the B20 SCR-on (2.12 ± 0.15
μg kWh−1). The results indicate therefore a slight reduction (7% and
16% respectively for B5 and B20) in total PAHs emissions when the
aftertreatment technology is applied. The reason for this slight reduc-
tion may be because of a moderate decrease in total particulate emis-
sions when SCR technology is applied as indicated by Mayer et al.
(2007), Czerwinski et al. (2011) and Lee et al. (2015). These reductions
Table 3
PAHs concentrations associated to PM exhaust emissions, in μg kWh−1.

PAHs (μg kWh−1) B5 SCR-off

Average ± u n Aver

Naphthalenea 0.076 ± 0.014 1 0.036
Acenaphthylene 0.047 ± 0.006 1
Acenaphthene 0.138 ± 0.020 1 0.075
Fluorene 0.841 ± 0.064 2 0.845
Phenanthrene 0.786 ± 0.064 5 0.642
Fluoranthene 0.317 ± 0.221 5 0.319
Pyrene 0.738 ± 0.500 5 0.724
Benzo[a]anthracenea 0.085 ± 0.016 1 0.081
Benzo[b]fluoranthenea 0.152 ± 0.021 4 0.229
Benzo[g.h.i]perylene 0.188 ± 0.014 3 0.183
∑PAHs (particles) 3.37 ± 0.56b

PAHsC - possibly carcinogenic for humansa 0.313 (9.2%)

u – expanded uncertainties (95% level of confidence); n – number of valid samples; bLoQ – be
a IARC – group 2B (possibly carcinogenic to humans).
b Uncertainties propagation for PAHs sum.
for Euro V engines have been reported, by the cited authors, to be in the
same order of magnitude as observed here.

What is more noticeable, however, is that the addition of 20% of bio-
diesel in the fuel mixture resulted in a decrease of 25% in PAHs emis-
sions in the particle-phase for SCR-off and 32% for SCR-on. Similar
results were found by previous studies (Turrio-Baldassarri et al., 2004;
He et al., 2010; He, 2016; Yilmaz and Davis, 2016; Martin et al., 2017),
however without test the simultaneous effect of biodiesel blends and
SCR aftertreatment system. Our results concur with the findings of He
et al. (2010), who compared several studies, concluding that, on aver-
age, a reduction of 23% in PAHs emissions can be expected with a 20%
addition of biodiesel to the fuel. Therefore, our results demonstrated
that SCR and Biodiesel, when combined, can be more efficient on
PAHs reduction. Additionally, He et al. (2010) showed that PAHs emis-
sions from Euro II engines were two orders of magnitude higher than
those reported in the present research, therefore enlightening a de-
crease in PAHs emissions due to the engine technology evolution. Sim-
ilarly, the possibly carcinogenic to humans PAHs (PAHsC)were reduced
by when B5 was replaced by B20 with and without the SCR system.
These results demonstrate the beneficial influence on PAHs emissions
if biodiesel additions to fuel are made in conjunction to SCR system.

These results indicate a difference in combustion products between
diesel and biodiesel, as highlighted byRavindra et al. (2008), who stated
that the pyrolysis and pyro synthesis processes that diesel undergoes
during combustion (in reduced oxygen conditions), will result in the
formation of aromatic rings through condensation products. The gas-
eous hydrocarbons radicals can rapidly reorganize participating on
PAHs formation and growth. Through alkyl PAHs formationmechanism,
the addition of hydrocarbon radicals to lower molecular weight PAHs,
present in diesel, can form higher molecular PAHs. In the case of biodie-
sel combustion, PAHs formation involves the thermal polymerization of
the fatty acid methyl esters forming cyclohexane (Ratcliff et al., 2010),
as there are no aromatic organic compounds present. Therefore, the in-
corporation of biodiesel in the mixture can lead to a reduction in PAHs
emissions due to the natural absence of PAH in biodiesel, and to its
higher oxygen content. The observed result represents the different
chemistry path of biodiesel combustion in relation to diesel and an im-
provement of the combustion process, reducing the PAHs generated by
incomplete combustion of fuel and lubricant oils.

The average and uncertainties for the individual PAHs associated
with PM emission are presented in Fig. 1. The major compound quanti-
fied in all the experimental conditions was Fluorene followed by Phen-
anthrene, Pyrene, Fluoranthene, Benzo[b]fluoranthene and Benzo[g,h,i]
perylene. The latter compound presented concentrations below the
LoQ for B20 during the SCR-on condition. The high molecular weight
PAHs with three or more aromatic rings, recognized for their toxicity,
contributed more to the total particle PAHs emission, as they have a
B5 SCR-on B20 SCR-off B20 SCR-on

age ± u n Average ± u n Average ± u n

± 0.014 2 bLoQ bLoQ
bLoQ bLoQ 0.043 ± 0.006 2

± 0.020 2 bLoQ bLoQ
± 0.215 5 0.759 ± 0.129 5 0.867 ± 0.085 2
± 0.081 4 0.669 ± 0.088 8 0.658 ± 0.107 2
± 0.111 5 0.225 ± 0.085 9 0.128 ± 0.016 4
± 0.253 5 0.587 ± 0.209 9 0.307 ± 0.043 4
± 0.016 2 bLoQ bLoQ
± 0.173 2 0.128 ± 0.009 9 0.121 ± 0.016 3
± 0.003 2 0.176 ± 0.002 3 bLoQ
3.13 ± 0.40b 2.54 ± 0.28b 2.12 ± 0.15b

0.347 (11.1%) 0.128 (5.0%) 0.121 (5.7%)

low quantification limit.



Fig. 1. Average concentrations in μg kWh−1 (columns) and standard deviation (bars) for individual PAHs associated with total PM emission for all experimental conditions.

679G.C. Borillo et al. / Science of the Total Environment 644 (2018) 675–682
higher probability to condense during the combustion process
(Ballesteros et al., 2010). Benzo[a]pyrene, the most toxic among PAHs
species, was not quantified for any of the conditions (LoQ =
3.36 ng ml−1).

The ANOVA test was performed for the substances that presented
two or more valid samples: Fluorene, Phenanthrene, Fluoranthene,
Pyrene and Benzo[b]fluoranthene, to identify if the differences between
tested conditions are significant. No statistical difference (95% confi-
dence level) was found for the tested conditions, except for Benzo[b]
fluoranthene when comparing B5 SCR-off to B20 SCR-off and B5 SCR-
on to B20 SCR-off. A similar result was obtained by Shah et al.(Shah
et al., 2012) who found no significant difference in PAHs emissions con-
sidering the use of the SCR system and a low sulphur diesel. The more
noticeable reduction on average emission was observed to Fluoran-
thene and Pyrene when B20 and the SCR system were tested, 60% and
58% respectively, comparing to B5 SCR-off.

Considering biodiesel, Ballesteros et al. (2010) studied the particle-
associated PAHs emission using three diesel (ULSD)/biodiesel mixtures
(B30, B70 and B100) with a 4-cylinder, 4-stroke, turbocharged,
intercooled, 2.2 l Nissan diesel engine without any aftertreatment sys-
tem operating in a transient cycle. The authors showed that the biodie-
sel addition decreased the low molecular weight PAHs concentration
(three aromatic rings) in relation to pure diesel and concluded that
these emissions depend on the biodiesel origin. In agreement to
Ballesteros et al. (2010), in present study, no significant difference was
found in the individual PAHs emission and a decrease was observed to
low molecular weight PAHs when biodiesel and SCR were tested at
once. The same results were reported by Rojas et al. (2011) for 10 out
the 16 priority PAHs (as proposed by US EPA) when they monitored
the particle emissions from a 20-year-old engine fuelled with pure die-
sel (1000 ppm of sulphur) and B15. The authors also quantified high
concentrations of Pyrene, Benzo[k]fluoranthene and Benzo[g,h,i]
perylene when B15 was used. Despite the results similarities, theses re-
searches did not test the effect of biodiesel and SCR simultaneously.

Total PAHs emission reductions were observed (up to 28%) with
the replacement of diesel fuel with biodiesel, which has been
ascribed to the different chemistry pathway during the pyrolysis of
the biodiesel. These reductions were more pronounced if the SCR
aftertreatment system was used. In addition, the fuel composition
also played a significant role in the amount of carcinogens PAH
emitted.

The individual PAHs results (Fig. 1) also reveal a reduction on con-
centration of Naphthalene, Acenaphthylene, Acenaphthene and Benzo
[a]anthracene when B20 was tested without the SCR system. Consider-
ing the B20with SCR Benzo[g,h,i]Perylene similarly have reduced to low
concentrations being above the quantification limit. The beneficial ef-
fects of the biodiesel/SCR system equally can be confirmed by the
Toxic Equivalent (TEQ) values.

The Toxic Equivalency Factors (TEFs) for each PAHs and the TEQ
calculation procedure were the same as those proposed by Nisbet
and LaGoy (1992) and US EPA (United States Environmental Protec-
tion Agency, 2006). The results indicate that the highest TEQ was
found for the B5 SCR-on combination (0.036 μg kWh−1), followed
by the B5 SCR-off (0.029 μg kWh−1), B20 SCR-off (0.017 μg kWh−1)
and the lowest for the B20 SCR-on combination (0.014 μg kWh−1).
The highest TEQ value, 0.036 μg kWh−1, match the highest PAHsC,
0.347 μg kWh−1 (Table 3), for the B5 SCR-on condition, suggesting
that Benzo[b]fluoranthene was mostly responsible for the increased
toxicity. Shah et al. (2012) tested the influence of the SCR system on
the TEQ values and concluded that the aftertreatment increased the
quotient value due to the increase in PAHs with high TEFs.

The preponderant factor leading to the reduction of the TEQwas the
fuel variation. The reduction from B5 SCR-off to B20 SCR-off was 41%
and B5 SCR-on to B20 SCR-on was 60%. Yilmaz and Davis (2016)
found low particle-bound PAHs TEQ values in the same order of magni-
tude for B10 and B20 mixture, using waste oil biodiesel and no
aftertreatment. The authors also reported that B10 reduced toxicity by
49% and B20 by 46%, compared to B100. In addition to the discussion
about the biodiesel life cycle and the economical/environment sustain-
ability, this biofuel is an alternative to reduce PAHs in particle-phase of
Diesel engine emissions and toxicity, when the proportions are limited
to 20% on diesel mixture.



Fig. 2. Average (columns) and standard deviation (bars) for individual Nitro-PAHs
associated to total PM emission to all experimental conditions in μg kWh−1.

680 G.C. Borillo et al. / Science of the Total Environment 644 (2018) 675–682
3.2. Particle-phase Nitro-PAHs

The concentration of five Nitro-PAHs associated with PM emissions
from a Euro V (SCR) engine using diesel/biodiesel blends (B5 and B20)
as fuels were assessed in this research and the results are shown in
Table 4 and Fig. 2. The 1-Nitropyrene was quantified in one sample of
each experimental condition. 2-Nitrofluoranthene and 7-Nitrobenzo
[a]anthracene were below the quantification limit for all conditions.
The Nitro-PAHs that were present in quantifiable amounts were 1-
Nitronaphthalene and 2-Nitrofluorene. It is observed that 2-
Nitrofluorene was up to 8.5 times higher than the other Nitro-PAHs
quantified and in general higher than any other individual PAHs identi-
fied and quantified as indicated in Table 3. According to the World
Health Organization (Kielhorn et al., 2003) both 2-Nitrofluorene and
1-Nitropyrene are found in diesel combustion particulate emissions
and are the major contributors to the increase in mutagenic emission
potential. When considering the Nitro-PAHsC sum (Table 4), it is ob-
served that these compounds represents 87–92% of the total Nitro-
PAHs emissions and are therefore of concern, since they are currently
classified as group 2B and 2A by the IARC.

Unlike the results obtained in the PAHs analysis, in which the fuel
had the greatest reduction influence on the total emissions, the deter-
mining factor is a combination of fuel composition and the use of the
SCR aftertreatment system. The SCR aftertreatment resulted in a 48% re-
duction when the B20 fuel was used and 5% in the case of B5. This sug-
gests that the SCR aftertreatment was more effective when larger
biodiesel additions are made. The only substantial reduction was ob-
served for B20 with aftertreatment in comparison to the other experi-
mental conditions. It seems therefore that only in the case of a
combination of increased biodiesel additions and aftertreatment use, a
reduction of Nitro-PAHs emissions was observed. This contrasts with
Martin et al. (2017) who found that B20 can reduce overall Nitro-
PAHs concentrations in particle phase emissions in comparison to die-
sel, without aftertreatment.

The analysis of variances for 1-Nitronaphthalene and 2-
Nitrofluorene showed no significant difference (95% confidence level)
among the different experimental conditions (B5 SCR on, B5 SCR off,
B20 SCR on and B20 SCR off). The same outcome was determined for
its precursor PAHs, Naphthalene and Fluorene, that presented no signif-
icant difference (95% confidence level) in fuel and aftertreatment varia-
tion. These two precursors PAHs also have high emission values
comparing to the other PAHs.

The formationmechanism of Nitro-PAHs through the nitration reac-
tion during the combustion process in the cylinder has been investi-
gated by several researches. Nevertheless, the knowledge about this
process remains inconclusive (Kielhorn et al., 2003; Heeb et al., 2008;
Liu et al., 2015). During the combustion, Nitro-PAHs can be formed by
electrophilic substitution reactions in the presence of NOx and the com-
bination of high temperatures. The presence of precursor PAHs and long
residence time inside the aftertreatment system also can promote the
formation of these compounds (Heeb et al., 2008). During the tests
the SCR system reduced NOx emission in 69% to B5 and 78% to B20;
Table 4
Nitro-PAHs concentrations associated to PM exhaust emissions, in μg kWh−1.

Nitro-PAHs (μg kWh−1) B5 SCR-off B5

Average ± u n Average

1-Nitronaphthalene 0.270 ± 0.233 2 0.161 ±
2-Nitrofluorenea 1.339 ± 0.689 5 1.223 ±
1-Nitropyreneb 0.408 ± 0.177 1 0.542 ±
∑Nitro-PAHs (particles) 2.02 ± 0.75c 1.9
Nitro-PAHsC - IARC group 2A and 2B 1.75 (87%) 1.

u – expanded uncertainties (95% level of confidence); n – number of valid samples.
a IARC – group 2B (possibly carcinogenic to humans).
b IARC – group 2A (probably carcinogenic to humans).
c Uncertainties propagation for PAH sum (estimative).
and showed an increase on NH3 and N2O emission when the SCR was
used for both fuels. These results are detailed presented in a previous
publication (Borillo et al., 2015). In the present study, 1-
Nitronaphthalene and 1-Nitropyrene did not show any trends due fuel
and aftertreatment changes, considering the average value. On the
other hand, 2-Nitrofluorene shows an increase trend when SCR was
function with B5 and when B20 was tested without SCR system. As
theNOx emission decrease about 69% and 78%when SCR aftertreatment
is used and no correlated decrease was observed in Nitro-PAHs emis-
sion, is unlikely that SCR system promote Nitro-PAHs formation in
large scale.

In a recent study, Liu et al. (2015) examined the emission of Nitro-
PAHs using various types of aftertreatment systems in different config-
urations. When testing DOC + SCR, the emissions of PAHs increased
compared to the results of the engine without any after-treatment sys-
tem.When studying only the SCR system, a reduction in the emission of
Nitro-HPAswas observed by Liu et al. (2015). However, the authors also
concluded that the formation of Nitro-PAHs by the SCR system is ques-
tionable, since this system significantly reduces NO2 concentrations, de-
creasing their availability for the conversion of PAHs into their nitrated
forms. In addition, the pores of the SCR system exclude large molecules
such as PAHs, reducing their residence time and their interaction with
NOx. Hu et al. (2013) evaluated the use of two SCR systems' composition
(vanadium and copper) after a DOC + DPF system and none appeared
to promote the nitration of PAH as awhole, butmay lead to the selective
nitration of some PAHs, such as Phenanthrene. Inomata et al. (2015)
studying 4-Nitrophenol, 1-Nitropyerene and 9-Nitroanthracene com-
pounds from 3 different Diesel vehicles emission with DOC, DPF and
SCR as aftertreatment systems, concluded that the SCR aftertreatment
suppress Nitro-PAHs emission.

Considering the biodiesel effect on theNitro-PAHs emissions, Ratcliff
et al. (2010) and Guan et al. (2017) observed that the use of biodiesel
SCR-on B20 SCR-off B20 SCR-on

± u n Average ± u n Average ± u n

0.020 3 0.193 ± 0.051 2 0.146 ± 0.013 2
0.276 5 1.624 ± 0.596 5 0.624 ± 0.314 2
0.177 1 0.360 ± 0.177 1 0.350 ± 0.177 1
3 ± 0.33c 2.17 ± 0.62c 1.12 ± 0.36c

76 (92%) 1,98 (91%) 0.974 (87%)



681G.C. Borillo et al. / Science of the Total Environment 644 (2018) 675–682
and oxygenated fuels, respectively, significantly reduces the emission of
Nitro-PAHs associated to PM with proportions above 20%. Sharp et al.
(2000) studied the effects of biodiesel on unregulated emissions in 3
different heavy-duty vehicles (119, 205 and 176 kW) operating with a
transient cycle. Their results showed that Nitro-PAHs emissions associ-
ated with PM were lower for biodiesel (B100) compared to the S500
diesel. This result was expected since biodiesel has low concentrations
of aromatic compounds, the precursor PAHs in its composition. He
(2016) described an increase in Nitro- and Oxy-PAHs when using soy-
bean biodiesel, palm biodiesel and oxidized biodiesel from used fried
oil. 1-Nitropyrenehas been reported by other studies and can be consid-
ered as a diesel emission marker (Bagley et al., 1998; Karavalakis et al.,
2010; He, 2016; Guan et al., 2017).

Evenwith the injection of a urea solution and the consequent reduc-
tion onNOx emission andNH3 formation, there is no favouring of the ni-
tration process in the SCR aftertreatment system when using biodiesel
blends. The results suggest that the opposite occurs: the SCR system
combined with biodiesel addition above 20% helps to reduce Nitro-
HPAs formation in the aftertreatment by suppressing NOx and improv-
ing the combustion process due to the higher oxygen concentration in
biodiesel. However, there is indications that SCR and biodiesel, sepa-
rately, can increase the emission of some individual Nitro-PAHs, as 2-
Nitrofluorene.

In brief, the combination of B20 and SCR after-treatment systems re-
sulted in a consistent reduction of Nitro-PAHs emissions. However,
there is evidence that the SCR system selectively promotes the forma-
tion of some individual Nitro-PAHs, as 2-Nitrofluorene. Therefore, the
higher oxygen content and the absence of aromatic compounds in bio-
diesel together with PM emission reduction by the SCR system seem to
be able to reduce human health risks associated with PAHs and Nitro-
PAHs exposure.
4. Conclusion

This study brings an important contribution to a better under-
standing regarding the synergistic effects of new engine technolo-
gies, after-treatment systems and biofuels, on the unregulated
PAHs and nitro-PAHs emissions from heavy-duty diesel engines
still in use in most developing countries. Total PAHs emission reduc-
tions were observed (up to 28%) with the replacement of diesel fuel
with biodiesel, which has been ascribed to the different chemistry
pathway during the pyrolysis of the biodiesel. These reductions
were more pronounced if the SCR aftertreatment system was used.
In addition, the fuel composition also played a significant role in
the amount of carcinogens PAH emitted. The results were tested
against the Toxic Equivalent (TEQ) and the lowest toxicity values
were observed with the B20 SCR-on condition, followed by B20
SCR-off, B5 SCR-off and B5 SCR-on. The combination of B20 and SCR
after-treatment systems resulted in a consistent reduction of total
Nitro-PAHs emissions. Due no correlation between the decrease in
NOx and Nitro-PAHs emission it is unlikely that the SCR system pro-
mote PAHs nitration. However, there is evidence that the SCR system
selectively promotes the formation of some individual Nitro-PAHs,
as 2-Nitrofluorene. Therefore, the higher oxygen content and the ab-
sence of aromatic compounds in biodiesel together with the SCR sys-
tem seem to be able to reduce human health risks associated with
PAHs and Nitro-PAHs exposure. These findings can assist in policy
making, especially setting new emission standards that include
limits for persistent organic pollutants such as PAHs and nitro-
PAHs. In addition, the authors recognise that the reduction of tailpipe
emissions from diesel-type fuels is a challenging task and therefore
hope that the data from this study could help planning the best path-
way to assess and reduce vehicular emissions since it depends on
fuel type, experimental approaches, engines size and technologies,
operating cycles, and aftertreatment systems.
Acknowledgement

This work was financially supported by the Brazilian National Coun-
cil for Scientific and Technological Development (CNPq) [projects
402391/2009-8 and 558697/2012-0].

Appendix A. Supplementary data

Supplementary data to this article can be found online at https://doi.
org/10.1016/j.scitotenv.2018.07.007.
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	Polycyclic Aromatic Hydrocarbons (PAHs) and nitrated analogs associated to particulate matter emission from a Euro V-�SCR e...
	1. Introduction
	2. Material and methods
	2.1. Sampling and engine parameters
	2.2. Fuels
	2.3. Extraction
	2.4. Analysis

	3. Results and discussion
	3.1. Particle-phase PAHs
	3.2. Particle-phase Nitro-PAHs

	4. Conclusion
	Acknowledgement
	Appendix A. Supplementary data
	References