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Environmental Processes
Nonnegligible Generation of Hydroxyl Radicals from UVC Photolysis of Aqueous Nitrous Oxide Guoyang Zhang, Shijie Wei, Bingdang Wu, Zhihao Chen, and Shujuan Zhang Environ. Sci. Technol., Just Accepted Manuscript • DOI: 10.1021/acs.est.8b02145 • Publication Date (Web): 03 Aug 2018 Downloaded from http://pubs.acs.org on August 4, 2018
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Nonnegligible Generation of Hydroxyl Radicals from UVC Photolysis of Aqueous Nitrous Oxide Guoyang Zhang, Shijie Wei, Bingdang Wu, Zhihao Chen, Shujuan Zhang*
State Key Laboratory of Pollution Control and Resource Reuse, School of the
Environment, Nanjing University, 163 Xianlin Avenue, Nanjing, 210023, China
*Correspondence author. Phone: +86 25 89690389, E-mail:
[email protected] Submitted to: Environmental Science & Technology
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Table of Contents (TOC) Art
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ABSTRACT
2
Nitrous oxide (N2O) is widely used in radiation-chemistry and photochemistry as a scavenger to
3
convert hydrated electron (eaq-) to hydroxyl radical (·OH). However, few investigation pays
4
attention to the photochemistry of dissolved N2O itself. The effects of purged N2O on
5
photochemical processes are unclear and neglected. In the present work, the effects of N2O on the
6
hydroxylation of terephthalic acid (TPA) were investigated with both medium-pressure and low-
7
pressure mercury lamps as the light sources. Under short-wavelength UV (200-300 nm) irradiation,
8
N2O accelerated the decay of TPA and the formation of 2-hydroxylterephthalic acid (hTPA). The
9
effective quantum yield of ·OH from the photolysis of dissolved N2O at 254 nm was determined
10
as 1.15-1.63, which was far larger than those of NO3- (0.09) and NO2- (0.046). Based on kinetic
11
analysis in N2 and N2O purged solutions, isotope fractionation with heavy oxygen water, and ·OH
12
scavenging experiments with tert-butyl alcohol, the contribution of the ·OH radicals generated
13
from photolysis of N2O to the formation of hTPA (61.7%) was determined to be one order of
14
magnitude higher than that from the converted eaq- (6.5%). These results demonstrate that using
15
N2O and ·OH probes to quantify photogenerated eaq- in UVC irradiation might lead to false results.
16
The work here is helpful for the proper design of scavenging and probing experiments by the
17
combination of N2O and ·OH probes.
18
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INTRODUCTION
20
Nitrous oxide (N2O) is widely used as a scavenger of hydrated electron (eaq-) in radiation-chemistry
21
and photochemistry studies.1-4 For example, a highly sensitive approach was developed to quantify
22
the photoproduction of eaq- from humic substances by purging N2O into the solution.5 Based on
23
the rationale that eaq- can be efficiently transformed to hydroxyl radical (·OH) by N2O (Reaction
24
1), the combination of N2O with some typical ·OH probes, such as coumarin (COU) and benzene,
25
was used to assess whether eaq- was formed as a primary photolysis product of NO2-.6,7 The above
26
photolysis experiments were conducted with light sources containing UVC (200-280 nm) photons.
27
The photochemistry of gaseous N2O in the wavelength (l) range of 185-230 nm (denoted as s-UV)
28
has been studied extensively.8-11 However, few investigation has paid attention to the
29
photochemistry of the dissolved N2O.
30
eaq - + N2O + H2O ® × OH + OH- + N2
31
Under s-UV irradiation, N2O can decompose into either dinitrogen and atomic oxygen or nitric
32
oxide and atomic nitrogen (Reactions 2-5).12 The generated atomic oxygen can then react with
33
N2O to produce nitric oxide or molecular oxygen/nitrogen (Reactions 6 and 7).9 hv
34
N2O ® N2 (1Σ) + O( 3 P)
35
N2O ® N2 (1Σ) + O( 1 D)
36
N2O ® N2 (1Σ) + O( 1S)
37 38
k2 = 9.1 × 109 M-1 s-1
(1)
l ≤ 742 nm
(2)
l ≤ 341 nm
(3)
l ≤ 212 nm
(4)
N2O ® NO(2P) + N( 4 S)
l ≤ 252 nm
(5)
N 2 O + O( 1 D) ® 2NO
k2 = 6.7 × 10-11 cm3 molecule-1 s-1
(6)
hv
hv
hv
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N 2O + O( 1 D) ® N 2 + O 2
40
Reaction 3 has a quantum yield near 1 and has been considered as the primary pathway in the
41
photolysis of gaseous N2O.11-13 Once dissolved into water or complexed with a H2O molecule, the
42
electronic absorption spectrum of N2O was changed.14-16 However, the generation of O(1D) was
43
still regarded as a key step in the photolysis of aqueous N2O under s-UV irradiation.17 The O(1D)
44
inserted into a H2O molecule to form H2O2 (Reaction 8) or directly to ·OH (Reaction 9).
k2 = 4.9 × 10-11 cm3 molecule-1 s-1
(7)
45
O(1D) + H 2O ® H 2O 2
(8)
46
O(1D) + H 2 O ® 2 × OH
(9)
47
Another possible pathway in the photolysis of water-bounded N2O was proposed as the
48
decomposition of excited H2O·N2O complex to either H2O2 (Reaction 10) or ·OH (Reaction 11).18 hv
49
[ N 2O × H 2O]
® N 2 + H 2O 2
50
[ N 2O × H 2O]
® N 2 + 2 × OH
51
H2O2 ® 2 × OH
52
The photolysis of H2O2 (Reaction 12) is known as a typical way for the generation of ·OH
53
with a quantum yield around 1.19 Taking Reactions 8-12 into account, no matter decomposed
54
through which way, the final products of aqueous N2O under s-UV irradiation would be ·OH.
(10)
hv
(11)
hv
(12)
55
In most photochemical studies for water treatment, low-pressure (LP) and medium-pressure
56
(MP) mercury lamps are widely used as light sources. The main effective emission is in the range
57
of 250-405 nm. To the best of our knowledge, the photochemistry of aqueous N2O in the UV range
58
of 250-405 nm is unclear yet. Considering the known photodissociation reactions of the H2O·N2O
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complex or the dissolved N2O, N2O-purging is applicable to quench eaq-, but might lead to artifacts
60
if the quantification of eaq- was conducted with ·OH probes.
61
To clarify the suitability of using N2O as a scavenger for reductive species in photochemical
62
systems, the photo-degradation of terephthalic acid (TPA), a widely used ·OH probe,20-23 in
63
aqueous solutions with and without N2O purging were investigated. The main objectives of this
64
work are to investigate the effects of N2O on the hydroxylation of TPA and consequently to
65
evaluate the applicability of using N2O and ·OH probes as an approach to quantify photogenerated
66
eaq- in UVC irradiation.
67 68
EXPERIMENTAL
69
Material. H2O2 of analytical grade was purchased from Shanghai Reagent Station, China.
70
NaOH, HCl, KI, KIO3, Na2B4O7, NaH2PO4·2H2O and Na2HPO4·12H2O of analytical grade were
71
obtained from Nanjing Reagent Station, China. NaNO3, NaNO2 and H3PO4 of analytical grade
72
were purchased from Sinopharm Chemical Reagent Co., Ltd., China. N, N-diethyl-p-
73
phenylenediamine (DPD), methanol and formic acid of chromatographic grade were purchased
74
from Sigma-Aldrich, China. Tert-butyl alcohol (TBA) (99.5%), peroxidase (POD) (≥ 3000 u mg-
75
1
76
TPA (99%, CAS number: 100-21-0) and heavy oxygen water (H218O) (99.99%) were purchased
77
from Macklin, China. 2-hydroxylterephthalic acid (hTPA) (98%, CAS number: 636-94-2) were
78
purchased from Aladdin, China. COU (99%, CAS number: 91-64-5) and 7-hydroxycoumarin
79
(hCOU) (99%, CAS number: 93-35-6) were obtained from J&K, China. Benzoic acid (BA) (99%,
) from horseradish were purchased from Shanghai Yuanye Biology Technology Co., Ltd., China.
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CAS number: 65-85-0) and 2-hydroxybenzoic acid (2hBA) (99%, CAS number: 69-72-7) were
81
purchased from Sigma-Aldrich, China. More detailed information about the tested probes is listed
82
in Table S1.
83
High purity N2 (99.999%) and N2O (99.95%) were purchased from Nanjing Tianze Gas Co.,
84
Ltd., China. Ultrapure water (18.25 MW cm) was made with a water purification system (Shanghai
85
Ulupure Industrial Co., Ltd., China) and used for the preparation of sample solutions.
86
Prior to use, 10 g L-1 DPD (in 0.05 M H2SO4) and 1 g L-1 POD stock solutions were prepared
87
according to the literature24 and were stored in the dark at 4oC. TPA stock solution of 1 mM was
88
prepared in a diluted NaOH solution (5 mM) to ensure its full dissolution. Prior to irradiation, all
89
the solutions were adjusted with NaOH or HClO4 solutions to pH 9.0.
90
Irradiation Experiments. UV irradiation experiments were carried out in a rotating disk
91
photoreactor (Nanjing StoneTech Electric Equipment, China) with a 300 W medium-pressure
92
mercury lamp (MP-Hg, Shanghai Hongguang Tungsten & Molybdenum Technology Co., Ltd.) or
93
with a 10 W low-pressure mercury lamp (LP-Hg, GPH212T5L, Heraeus Noblelight) as the light
94
sources (Figure S1). The MP-Hg lamp was polychromatic with a maximum light emission at 365
95
nm and the LP-Hg lamp was monochromatic at 254 nm. The light intensity was measured with a
96
radiometer (Photoelectric Instrument Factory of Beijing Normal University, China) equipped with
97
two sensors of peak sensitivity at 365 nm for MP-Hg lamp and 254 nm for LP-Hg lamp. Unless
98
otherwise stated, the irradiation experiments in this work were conducted with the MP-Hg lamp.
99
In purging experiments, the sample solutions were firstly purged with the corresponding gas
100
for 30 min prior to irradiation and then continuously purged during photo-irradiation (Figure S1). 6
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In order to control the concentration of N2O, a series of N2O and N2 mixtures of different volume
102
percentage (v/v%) was inflated with variable-area flow meters (Kede Thermos-Technical
103
Instrument Co., Ltd., China) and the flow rate of the mixed gas was about 25 L h-1. The dissolution
104
of N2O conformed to the Henry’s law (Figure S2a). The concentrations of N2O were 3.3, 7.9, 12.3,
105
16.8, 19.3, and 24.1 mM when the volume fractions of N2O were 16.7%, 31.4%, 40.0%, 50.0%,
106
60.0%, and 70.1%, respectively. A glove box system (Mikrouna Co., Ltd., China) was used to
107
prepare solutions free of dissolved O2 (DO).
108
Analytical Methods. UV-Vis spectra were recorded with a double beam spectrophotometer
109
(UV-2700, Shimadzu, Japan). Total organic carbon (TOC) was determined with a Multi N/C TOC
110
apparatus (TOC-L, Shimadzu, Japan). DO was determined with an HQ30d apparatus (HACH,
111
USA). The concentrations of TPA, COU, hTPA, hCOU, BZ and 2hBZ were determined with a
112
high performance liquid chromatography (HPLC) system (Waters 1525, USA) equipped with an
113
Agilent C18 reversed phase column (150 mm × 4.6 mm, 5 µm) at 25oC. The injection volume was
114
5 µL. The detailed HPLC conditions are listed in Table S1.
115
16
O-hTPA and
18
O-hTPA were identified with a Thermo Scientific Q ExactiveTM Focus
116
Orbitrap LC-MS/MS System (Thermo, USA) without separation and were detected in a negative
117
ion mode with an electrospray ionization (ESI) source. The settings for ESI were: capillary
118
temperature: 350oC, spray voltage: 3.0 kV, sheath gas flow: 35, auxiliary gas flow: 20 (arbitrary
119
units), capillary voltage: 25 V, and tube lens offset: 100 V.
120
H2O2 could oxidize POD to a higher valent state, which in turn oxidized DPD to a pink colored
121
radical cation DPD·+ with a maximum absorption at 551 nm.24 Other organic hydroperoxides could 7
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also oxidize POD. According to the stoichiometric ratio, the overall peroxides could be
123
approximately estimated with the DPD/POD method based on the standard curve of H2O2 (Figure
124
S2b).
125
The concentration of dissolved N2O was determined using the headspace method with a gas
126
chromatograph (GC, Thermo Scientific Fisher Trace 1310, USA).25, 26 The GC was equipped with
127
an electron capture detector (ECD) and a 5 Å molecular sieve column (30 m × 0.32 mm × 30 µm).
128
The carrier gas was N2 at a flow rate of 5 mL min-1. The injector, oven, and detector temperatures
129
were 110, 200, and 250oC, respectively. Sample solutions of 1 mL were equilibrated in 20 mL
130
serum vials at 25oC for 24 h prior to injection for GC analysis. The injection volume of headspace
131
gas was 100 µL. Total N2O concentration, including gaseous and dissolved N2O, was calculated
132
based on the solubility constant.
133
Quantum Yield Determination. In order to obtain the effective quantum yield of ·OH (Φ·OH)
134
from N2O photolysis in aqueous solution, a monochromatic LP-Hg lamp was used as the light
135
source with the formation of hTPA as an index. Since N2O-purging can reduce DO, N2-purging
136
experiments were conducted and employed as the background reference, which will be revisited
137
later.
138
hTPA is a primary product in the photolysis of TPA and in the reaction of TPA with ·OH. The
139
interaction of ·OH with TPA will not exclusively generate hTPA, but also some other products.27
140
Therefore, the hydroxylation yield of TPA into hTPA is defined as YhTPA, which is the ratio between
141
the initial formation rate of hTPA (k’0hTPA) and the initial degradation rate of TPA ([TPA]0 k’1TPA).
142
YhTPA = k’0hTPA / ([TPA]0 k’1TPA)
(13) 8
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k’0hTPA = k0, N2OhTPA – k0, N2hTPA
(14)
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k’1TPA = k1, N2OTPA – k1, N2TPA
(15)
145
where k0, N2OhTPA and k0, N2hTPA are the initial pseudo-zero-order formation rate constants of hTPA
146
in N2O-purged and N2-purged solutions, respectively. k1, N2OTPA and k1, N2hTPA are the pseudo-first-
147
order degradation rate constants of TPA in N2O-purged and N2-purged solutions, respectively.
148
[TPA]0 is the initial concentration of TPA.
149
The deduction in Equations 14 and 15 ensures that the k’0hTPA and [TPA]0 k’1TPA come
150
exclusively from the reaction of TPA with ·OH that is produced from the photolysis of N2O. In
151
this case, the formation and decay of ·OH follows the steady-state assumption, i.e., the
152
concentration of ·OH remains constant over time and is the ratio of ·OH formation rate to ·OH
153
quenching rate. Therefore, k’0hTPA can be expressed as:
154
k '0 hTPA = k2 [TPA]0 [ × OH]ss YhTPA
(16)
155
where [·OH]ss is the steady-state concentration of ·OH, k2 is the second-order reaction rate
156
constants of TPA and ·OH, which is reported to be 4.4 × 109 M-1 s-1.21
157
In the literature, YhTPA is reported as 0.35 in the UV/NO2- systems.21 In the N2O-purged
158
solution, YhTPA was calculated to be 0.36 ± 0.07 (Table S2). With k’0hTPA and YhTPA, the Φ·OH in the
159
photolysis of N2O could be obtained as28:
160
F×OH =
k '0 hTPA ´ V I 0 ´ (1 - 10-e CL ) ´ YhTPA
(17)
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where I0 is the photon flux entering the solution (einstein s-1), L is the effective path length (cm),
162
V is solution volume (L), ε is the molar absorption coefficient of N2O, and C is the concentration
163
of N2O (M).
164
The I0 at 254 nm was determined to be 5.08 ± 0.01 × 10-8 einstein s-1 by the KI/KIO3 method
165
(Text S1 and Figure S3).29,30 The effective path length (L) was obtained to be 2.22 ± 0.02 cm from
166
the photolysis kinetics of a diluted H2O2 solution (Text S2 and Figure S4).30,31
167 168
RESULTS AND DISCUSSION
169
Effects of Dissolved N2O on the Photolysis of TPA. The photodegradation of TPA was
170
conducted side-by-side in ambient, N2-purged, and N2O-purged aqueous solutions. After N2 or
171
N2O-purging, the residual DO in the TPA solution was reduced from 8.56 mg L-1 (ambient) to
172
0.26-0.30 mg L-1 (N2-purged) or 0.45-0.46 mg L-1 (N2O-purged). As shown in Figure 1a, the
173
photodegradation of TPA was enhanced by N2 or N2O-purging. This was consistent with the
174
observed DO effect on the photodegradation of some pharmaceuticals.32 The pseudo-first-order
175
degradation rate constant (k1) of TPA in the N2O-purged solution was 2.7 times to that in N2-purged
176
solution, indicating that the effects of N2O-purging were not merely the elimination of DO. The
177
contribution of other reactive species in the photochemical process of N2O could not be ignored.
178
There was a linear relationship between the N2O concentration and the k1 of TPA (k1 = 0.0048 ×
179
[N2O] + 0.7843, R2 = 0.96) (Figure 1b). As the N2O dosage was increased from 3.2 to 24.1 mM,
180
the k1 of TPA was increased from 0.088 to 0.185 min-1.
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The formation of hTPA in the irradiated TPA solutions followed the pseudo-zero-order kinetics
182
(Figure S5). The k0 of hTPA in the N2O-purged solution (0.255 µM min-1) was 11.1 times to the
183
ambient counterpart (0.023 µM min-1) and was 4.5 times to that in the N2-purged solution (0.057
184
µM min-1), indicating that more ·OH radicals were generated in the N2O-purged solutions (Figure
185
S5). This was also evidenced by the larger TOC reduction in the N2O-purged solutions (Figure S6).
186
Enhanced generation of hydroxylation products in N2O-purged solutions was also observed for the
187
irradiated systems with COU and BA as the target molecules, which are also widely used ·OH
188
probes in photochemical studies (Figure S7).6,33-35
189
The [·OH]ss in N2O-purged solution was calculated to be 5.50 × 10-15 M (Table 1). Based on
190
the k values, the Φ·OH of hydrated N2O at 254 nm was determined as 1.15-1.63, indicating the
191
occurrence of Reaction 11. To verify the reliability of the determination method, NO3- was
192
employed as a reference.
193
It is well known that the photolysis of nitrate (NO3-) and nitrite (NO2-) can generate ·OH with
194
quantum yields of 0.090 and 0.046, respectively.36, 37 The Φ·OH of NO3- at 254 nm was calculated
195
as 0.06, which is close to the reported value. The photolysis of TPA in the N2O-purged solution
196
was compared with those in the UV/NO2- and UV/NO3- systems. The addition of NO2- or NO3- in
197
the concentration range of 5-100 µM slightly increased the k1 of TPA (Figure 2a). Correspondingly,
198
the k0 of hTPA formation was increased by the addition of NO2- or NO3-, but was still much lower
199
than that in the N2O-purged solution (Figure 2b).
200 201
It should be noted that a further increase of NO2- or NO3- would not necessarily increase the k0 of hTPA, because the unfavorable inner filter effect of NO2- or NO3-. 11
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hv
202
NO3- + H+ ® × OH + × NO2
203
NO2- + H+ ® × OH + × NO
204
Effective Wavelength Range. According to the Grotthuss-Draper law, only the absorbed light
205
can cause a photochemical change. The absorption of dissolved N2O was very weak above 200
206
nm. This might be the reason why the previous reports on the photochemistry of N2O were limited
207
in the short wavelength range. From 200 nm to 300 nm, the molar extinction coefficient (e) of
208
aqueous N2O gradually reduces from 11.6 to 0.001 M-1 cm-1. The e of aqueous N2O at 254 nm is
209
in the range of 0.0012-0.0017 M-1 cm-1 (Table S3).
(18)
hv
(19)
210
All the above kinetic experiments were conducted with a MP-Hg lamp as the light source. Its
211
emission spectrum is shown in Figure S8. To distinguish which fraction of the emission spectrum
212
played the key role in the photolysis of N2O aqueous solution, two filters were inserted individually
213
into the light path between the MP-Hg lamp and the sample tubes. The 365 nm filter (BP365) and
214
420 nm filter (CF420) allow the penetration of photons in the wavelength range of 300-365 nm
215
and > 420 nm, respectively. The use of filters also suppressed the intensity of the light (Figure S8).
216
In the presence of the CF420 filter, hTPA was not detected in the N2O-purged solution, even
217
irradiated for a much longer time (80 min). With the use of the BP365 filter, the formation rate
218
constant of hTPA in the N2O-purged solution was decreased from 0.255 µM min-1 to 0.0007 µM
219
min-1 (Table S4). Compared with the N2-purged solution, no more hTPA was formed in the N2O-
220
purged solution (Table S4). All the above results demonstrate that the photons with wavelength
221
longer than 300 nm took no effect on N2O. Similar results have been reported in the literature.6, 38
222
For example, with a Xenon lamp as the light source equipped with a 305 nm high-pass filter, the 12
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purging of N2O had no effect on the photoionization of anthracene, benz[a]anthracene and 9-
224
methylanthracene.38
225
Role of N2O in hTPA Formation. There are at least two routes for the formation of hTPA in
226
the irradiated TPA solution: ·OH-independent (the direct photolysis of TPA to TPA˙+, which then
227
reacts with H2O to form hTPA) and ·OH-dependent (formation of ·OH first, followed with the
228
electrophilic addition of ·OH to TPA). In the photoionization of TPA, a hydrated electron (eaq-)
229
was ejected, accompanying with the formation of TPA˙+. The photo-ejected eaq- could react with
230
N2O to form ·OH (in N2O-purged solution) or react with O2 to form O2˙- (in ambient and N2-purged
231
solution). The O2˙- could then disproportionate to H2O2 and consequently photo-dissociate to ·OH.
232
As shown in Figure 3a, after UV irradiation, a considerable amount of H2O2 was detected in
233
the N2O-purged ultrapure water (in the absence of any organic matter, H2O2 was the only possible
234
peroxide), whereas there was no H2O2 formation in the ambient water. These results indicate that
235
N2O is the only source for the formation of H2O2 in the irradiated ultrapure water. The detected
236
peroxide concentration in the N2O-purged solution was decreased by the presence of 20 µM TPA
237
(Figure 3b). There were negligible peroxides in the N2-purged TPA solution. However, a
238
considerable amount of peroxides was formed in the ambient TPA solution. This is reasonable,
239
because the formation of organic peroxides from TPA needs the involvement of DO. The organic
240
peroxides might also serve as a source of ·OH23 and account for the formation of hTPA.
241
For clarity, all the possible pathways for the formation of hTPA are illustrated in Scheme 1.
242
Route 1 (·OH-independent):
13
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H2 O
hv
243
(I) TPA ® TPA* ® TPA×+ ® hTPA
244
Route 2 (·OH-dependent):
245
® × OH ® hTPA (II) TPA ® TPA* ® eaq - ¾¾
246
(III) N2O + H2O ® H2O2 or × OH ® hTPA
247
(IV) TPA ® TPA* ® Organic peroxides ® × OH ® hTPA
248
Path I occurred in all the systems, whereas the other pathways were highly dependent on the
249
gas conditions. Theoretically, in N2-purged solution, Path I is the only one accounting for the
250
formation of hTPA. Since a H2O molecule was involved in this pathway, if H218O was used as the
251
solvent, all the formed hTPA should be 18O-hTPA. As shown in Table 2, the generation of 18O-
252
hTPA in the N2-purged solution was negligible as the solvent was H216O (0.7%), whereas the
253
fraction of 18O-hTPA was significantly increased as H218O was used as the solvent (16.8%) (Table
254
2 and Figure S9). The abundance of 18O in H216O was 0.2%.39 The detected fraction of 18O-hTPA
255
in the H216O solution was reasonable. However, considering the fraction of
256
solution (99%), the fraction of 18O-hTPA in the H218O solution (16.8%) was significantly lower
257
than the expected value (99%), indicating that about 83.2% of the hTPA was generated through
258
other pathways.
N2 O or O2
hv
hv
hv
(20)
TPA
(21)
TPA
O2
hv
(22) TPA
(23)
18
O in the H218O
259
We speculate that the residual DO in the N2-purged solution (0.26 mg L-1) was attributable to
260
the unexpected formation of hTPA. To check this speculation, an O2-free TPA solution was
261
prepared in a glove box system. The DO in this O2-free TPA solution was below the detection limit
262
(DO < 0.01 mg L-1). As shown in Figure 4, the k0 values of hTPA in the O2-free solution were 19%
263
and 17% of those in the N2-purged solution with the MP-Hg lamp and the LP-Hg lamp as the light 14
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264
sources, respectively. These results fully demonstrate the role of the residual DO in the formation
265
of hTPA. It should be noted that the DO had a dual-effect on the formation of hTPA. On the one
266
hand, the DO could enhance the formation of hTPA through the generation of peroxides (Path IV).
267
On the other hand, the DO could quench the excited TPA, leading to reduced formation of hTPA
268
through Path I. When the concentration of DO was high, the quenching effect dominated, which
269
is evidenced by the lower k0 values of hTPA in the ambient solution as compared with those in the
270
N2-purged solution (Figure 4, Tables 2 and 3). The positive effect of DO on hTPA formation
271
dominated over the quenching effect in the N2-purged and N2O-purged solutions, and its
272
contributions in the two purged systems should be similar.
273
Besides Path I, Path III was also related with H2O molecules. The fraction of 18O-hTPA in the
274
N2O-purged solution (38.6%) was significantly higher than that in the N2-purged solution (16.8%)
275
(Table 2), because the photo-ejected eaq- was converted to ·OH by N2O. The N2O-purged and N2-
276
purged solutions had similar residual DO. Therefore, it is reasonable to infer that the contributions
277
of Paths I, II, and IV in the N2O-purged solution were identical to those in the N2-purged solution.
278
Thus, the difference in k0
279
contribution of Path III. The stoichiometric ratios of the 18O-hTPA to the total hTPA formed in
280
Path I and Path III were 1 and 2, respectively. Based on the k0
281
contribution of Path III in the N2O-purged solution (fN2O, III) could be calculated as:
18O-hTPA
18O-hTPA
between the N2O-purged and N2-purged solutions reflected the
- k0, N2
18O-hTPA
) / ( k0, N2O
18OH
18O-hTPA
+ k0, N2O
16OH
values in Table 1, the
282
fN2O, III = 2 × (k0, N2O
283
The contribution of ·OH to the formation of hTPA was further evaluated by using TBA as
284
a ·OH scavenger. The formation of hTPA was significantly inhibited by the addition of TBA (Table 15
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3). Based on the rate constants with ·OH (6.0 × 108 M-1 s-1 for TBA4 and 4.4 × 109 M-1 s-1 for
286
TPA21) and the concentrations of TBA and TPA used in the scavenging experiments (100 mM TBA
287
and 20 µM TPA), theoretically, more than 99% of ·OH radicals could be scavenged by TBA.
288
Calculated with a previously reported approach,25 the inner filter effect caused by TBA to the tested
289
solutions were negligible. The scavenging effects might be exclusively attributed to the scavenging
290
reaction between TBA and ·OH.
291
In the N2-purged solution, the inhibition of TBA on hTPA formation (Table 3) was derived
292
from Path II and Path IV, which (fN2, II + fN2, IV) account for 26.1% of the total yield. Except the
293
contribution of Path III, the contributions of the other pathways in the N2O-purged solution, as
294
aforementioned, should be the same as those in the N2-purged solution. In the N2O-purged solution,
295
the ·OH radicals came from Paths II, III and IV. The fN2O, III has been quantified as 61.7% in the
296
H218O experiments. Therefore, the contributions of Path II and Path IV in the N2O-purged solution
297
(fN2O, II + fN2O, IV) could be calculated as:
298
fN2O, II + fN2O, IV = (1 - fN2O, III) × (fN2, II + fN2, IV) = 10.0%
299
Thus, the sum of the contributions of Paths II, III and IV in the N2O-purged solution (fN2O, II +
300
fN2O, III + fN2O, IV) was 71.7%, which was consistent with the inhibition rate caused by TBA (71.3%
301
in Table 3).
302 303 304
(25)
The contribution of Path I in the N2-purged solution (fN2, I) was obtained as 16.8% (Table 2). Thus, the contribution of Path I in the N2O-purged solution (fN2O, I) could be calculated as: fN2O, I = (1 - fN2O, III) × fN2, I = 6.5%
(26)
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305
The stoichiometric ratio of eaq- to TPA˙+ was 1. Therefore, the contribution of Path II in the
306
N2O-purged solution (fN2O, II) should be identical to fN2O, I (6.5%). Thus, the contribution of Path
307
IV in the N2O-purged solution (fN2O, IV) accounted for 3.5%:
308
fN2O, IV = (fN2O, II + fN2O, IV) - fN2O, II = 3.5%
(27)
309
Now, the sum of the known contributions (Paths I, II, III, and IV) in the N2O-purged solution
310
was totally 78.2%. The pathways for the remaining part (21.8%) were unclear yet. As shown in
311
Reactions 1, 10, and 11, N2 was the main N-containing product in the photolysis of N2O. Neither
312
NO3- nor NO2- was detectable in the irradiated N2O solution.
313
Environmental Implication. The generated ·OH radicals from the photolysis of dissolved
314
N2O in the natural aquatic environment might be not important for the following reasons: (a) In
315
estuaries, rivers or sea water, the concentrations of dissolved N2O typically ranges from 5 to 50
316
nM,40 (b) The UVC light accounts for only a small fraction of the solar energy (less than 5%), and
317
(c) N2O aqueous solution has a low absorption cross section in the UVC band. However, the work
318
here is of great significance in photochemical studies for the following reasons:
319
(1) In photochemical systems, N2O-purging has been widely used as an experimental approach
320
to detect the formation of eaq-. The work here found that the dissolved N2O could produce
321
nonnegligible ·OH under UVC irradiation despite of its extremely low absorption cross section.
322
The effective quantum yield of ·OH from the photolysis of hydrated N2O at 254 nm was
323
determined to be 1.15-1.63, which was far larger than those of NO3- and NO2-. These results
324
demonstrate that using N2O and ·OH probes as an approach to quantify photogenerated eaq- in
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UVC irradiation might lead to false data, because N2O could not only convert eaq- to ·OH, but also
326
directly generate ·OH from UVC photolysis.
327
(2) TPA is one of the most widely used ·OH probes in photochemical studies. By careful
328
calculation of the k values, the ·OH radicals generated from the photolysis of N2O accounted for
329
more than half of the generated hTPA and the contribution of the N2O-derived ·OH was more than
330
9 times to that of eaq-. Some unnoticed pathways in the hydroxylation of TPA were actually
331
noneligible. The misuse of TPA and N2O might lead to false mechanism analysis. Close attention
332
should be paid to the combination of N2O and ·OH probes in the determination of reactive species
333
in UVC systems.
334 335
Considering the above facts, this work is helpful for the proper design of scavenging and probing experiments in photochemical systems.
336 337
ASSOCIATED CONTENT
338
Supporting Information
339
Determination of photon flux and effective path length of light (Texts S1 and S2), analytical
340
conditions for the studied probe (Table S1), the yield of hTPA in N2O-purged solution (Table S2),
341
molar extinction coefficient of N2O (Table S3), the k0 of hTPA formation under different irradiation
342
conditions (Table S4), the diagrammatic sketch of the photo-reactor (Figure S1), the standard
343
curves of dissolved N2O and H2O2 (Figure S2), formation of I3- in the KI/KIO3 chemical
344
actinometer under irradiation at 254 nm (Figure S3), photolysis of a diluted H2O2 solution (Figure
345
S4), the formation of hTPA over time under various gas conditions (Figure S5), the reduction of 18
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346
TOC (Figure S6), the time profiles of hCOU and 2hBA (Figure S7), emission spectra of the light
347
sources (Figure S8), ESI-MS spectrum of a UV treated TPA solution (Figure S9).
348
This material is available free of charge via the Internet at http://pubs.acs.org.
349 350
AUTHOR INFORMATION
351
Corresponding Author
352
*Correspondence author. Phone: +86 25 8968 0389, E-mail:
[email protected] 353
Notes
354
The authors declare no competing financial interests.
355 356 357 358
ACKNOWLEDGMENTS This work was financially supported by the National Natural Science Foundation of China (21522702, 21677070).
359 360
REFERENCES
361
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(2) Jortner, J.; Ottolenghi, M.; Stein, G. The effect of nitrous oxide and the nature of intermediates
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2037-2042.
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Lyman-α radiation: scientific basis for a chemical actinometer. J. Phys. Chem. A 2010, 114
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(11) Hanisco, T. F.; Kummel, A. C. State-resolved photodissociation of nitrous oxide. J. Phys. Chem. 1993, 97 (28), 7242-7246.
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(13) Nakayama, T.; Takahashi, K.; Matsumi, Y.; Taniguchi, N.; Hayashida, S. Quantum yield for
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N(4S) production in the ultraviolet photolysis of N2O. J. Geophys. Res. 2003, 108 (D21), 4668.
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phase reaction of sulfur trioxide with water vapor. J. Am. Chem. Soc. 1994, 116 (22), 10314-
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phase reaction SO3 + H2O: importance of the second water molecule. J. Am. Chem. Soc. 1994,
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(17) Dainton, F. S.; Fowles, P. The photolysis of aqueous systems at 1849 Å. I. Solutions containing nitrous oxide. Proc. R. Soc. Lond. A 1965, 287, 295-311.
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(18) Tanaka, N.; Nagashima, U.; Takayanagi, M.; Kim, H. L.; Hanazaki, I. Photochemical reaction
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dynamics of the N2O·H218O van der Waals complex. J. Phys. Chem. A 1997, 101 (4), 507-
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512.
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(19) Zellner, R.; Exner, M.; Herrmann, H. Absolute ·OH quantum yields in the laser photolysis of
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nitrate, nitrite and dissolved H2O2 at 308 and 351 nm in the temperature range 278-353 K. J.
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Atmos. Chem. 1990, 10 (4), 411-425.
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(20) Charbouillot, T.; Brigante, M.; Mailhot, G.; Maddigapu, P. R.; Minero, C.; Vione, D.
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Performance and selectivity of the terephthalic acid probe for ·OH as a function of
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temperature, pH and composition of atmospherically relevant aqueous media. J. Photochem.
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Photobiol. A 2011, 222 (1), 70-76.
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(21) Page, S. E.; Arnold, W. A.; McNeill, K. Terephthalate as a probe for photochemically generated hydroxyl radical. J. Environ. Monit. 2010, 12 (9), 1658-1665.
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(22) Kwon, B. G.; Kim, J. O.; Kwon, J. K. An advanced kinetic method for HO2·/O2·-
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determination by using terephthalate in the aqueous solution. Environ. Eng. Res. 2012, 17 (4),
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205-210.
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(23) Tafer, R.; Sleiman, M.; Boulkamh, A.; Richard, C. Photomineralization of aqueous salicylic
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acids. Photoproducts characterization and formation of light induced secondary ·OH
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precursors (LIS-OH). Water Res. 2016, 106, 496-506.
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(24) Bader, H.; Sturzenegger, V.; Hoigne, J. Photometric method for the determination of low
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concentrations of hydrogen peroxide by the peroxidase catalyzed oxidation of N, N-diethyl-
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p-phenylenediamine (DPD). Water Res. 1988, 22 (9), 1109-1115.
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(25) Xiong, Z. Q.; Xing, G. X.; Zhu, Z. L. Water dissolved nitrous oxide from paddy agroecosystem in China. Geoderma 2006, 136 (3-4), 524-532.
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(26) Ma, T.; Chen, Q.; Gui, M. Y.; Li, C.; Ni, J. R. Simultaneous denitrification and phosphorus
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removal by Agrobacterium sp. LAD9 under varying oxygen concentration. Appl. Microbiol.
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Biotechnol. 2016, 100 (7), 3337-3346.
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(27) Fang, X.; Mark, G.; von Sonntag, C. ·OH radical formation by ultrasound in aqueous solutions
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Part I: the chemistry underlying the terephthalate dosimeter. Ultrason. Sonochem. 1996, 3 (1),
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(28) Herrmann, H. On the photolysis of simple anions and neutral molecules as sources of ·O-/·OH, SOx- and Cl in aqueous solution. Phys. Chem. Chem. Phys. 2007, 9 (30), 3935-3964. (29) Rahn, R. O. Potassium iodide as a chemical actinometer for 254 nm radiation: use of iodate as an electron scavenger. Photochem. Photobiol. 1997, 66 (4), 450-455.
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(30) Li, X. C.; Ma, J.; Liu, G. F.; Fang, J. Y.; Yue, S. Y.; Guan, Y. H.; Chen, L. W.; Liu, X. W.
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Efficient reductive dechlorination of monochloroacetic acid by sulfite/UV process. Environ.
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Sci. Technol. 2012, 46 (13), 7342-7349.
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(31) Beltran, F. J.; Ovejero, G.; Garcia-Araya, J. F.; Rivas, J. Oxidation of polynuclear aromatic
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hydrocarbons in water. 2. UV radiation and ozonation in the presence of UV radiation. Ind.
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Eng. Chem. Res. 1995, 34 (5), 1607-1615.
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(32) Zhang, G. Y.; Wu, B. D.; Zhang, S. J. Effects of acetylacetone on the photoconversion of pharmaceuticals in natural and pure waters. Environ. Pollut. 2017, 225, 691-699. (33) Xiang, Q.; Yu, J.; Wong, P. K. Quantitative characterization of hydroxyl radicals produced by various photocatalysts. J. Colloid Interface Sci. 2011, 357 (1), 163-167.
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(34) Rosario-Ortiz, F. L.; Canonica, S. Probe compounds to assess the photochemical activity of
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dissolved organic matter. Environ. Sci. Technol. 2016, 50 (23), 12532-12547.
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(35) Page, S. E.; Arnold, W. A.; McNeill, K. Assessing the contribution of free hydroxyl radical
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in organic matter-sensitized photohydroxylation reactions. Environ. Sci. Technol. 2011, 45 (7),
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2818-2825.
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(36) Thorn, K. A.; Cox, L. G. Ultraviolet irradiation effects incorporation of nitrate and nitrite nitrogen into aquatic natural organic matter. J. Environ. Qual. 2012, 41 (3), 865-881. (37) Mack, J.; Bolton, J. R. Photochemistry of nitrite and nitrate in aqueous solution: a review. J. Photochem. Photobiol. A 1999, 128 (1), 1-13. (38) Fasnacht, M. P.; Blough, N. V. Mechanisms of the aqueous photodegradation of polycyclic aromatic hydrocarbons. Environ. Sci. Technol. 2003, 37 (24), 5767-5772.
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(39) Water with heavy oxygen; Nature 1935, 135, 575. www.nature.com/articles/135575d0.pdf.
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(40) Karl, D. M.; Michaels, A.F. Nitrogen cycle. In Encyclopedia of Ocean Sciences (Second
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Edition); Steele, J. H.; Turekian, K. K.; Thorpe, S. A., Eds.; Academic Press: Oxford 2001;
460
pp 32-39.
461
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Figure, Scheme and Table Captions
462 463
Table 1.
466
The effective quantum yields and the steady-state concentrations of ·OH in UVC irradiated N2O and NO3- solutions.
464 465
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Table 2.
The pseudo-zero-order formation rate constants (k0) of
18
O-hTPA and 16O-hTPA in
photochemical processes with H216O or H218O as the solvent.
467
Table 3. The inhibition effect of TBA on the pseudo-zero-order formation rate constant of hTPA.
468
Scheme 1. The proposed pathways for the formation of hTPA in UV irradiated TPA solutions.
469
Figure 1. (a) The evolution of TPA (20 µM) under UV irradiation in ambient, N2-purged and
470
N2O-purged solutions. k1 (min-1): the pseudo-first-order degradation rate constant. (b)
471
The k1 of TPA as a function of N2O concentration. [TPA]0 = 20 µM, light intensity: 7.89
472
mW cm-2. Error bars represent the standard deviation from at least duplicate
473
experiments.
474
Figure 2. (a) The k1 of TPA degradation and (b) the k0 of hTPA formation in photochemical
475
processes with the addition of nitrogen oxide. [TPA]0 = 20 µM, [NO2-]0 = [NO3-]0
476
= 5-100 µM, [N2O] = 24.1 mM. The dashed line represents the k1 and k0 in the
477
absence of nitrogen oxide.
478
Figure 3. The generation of H2O2 in UV irradiated ultrapure water (pH 6.0) and (b) the
479
generation of peroxides in UV irradiated TPA solutions (20 µM, pH: 9.0) under
480
various gas conditions.
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481
Figure 4. The k0 of hTPA formation under different irradiation and gas conditions. [TPA]0
482
= 20 µM, light intensity: 4.72 mW cm-2 (MP-Hg at 365 nm) and 0.40 mW cm-2
483
(LP-Hg at 254 nm).
484
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485
Table 1. The effective quantum yields and the steady-state concentrations of ·OH in UVC
486
irradiated N2O and NO3- solutions. k’0hTPA
C0
ε254 × 10-2
Φ·OH
(nM min-1)
(mM)
(M-1 cm-1)
moles/einstein (fM)
N2O
10.45 ± 0.85
24.10
0.12-0.17
1.15-1.63
5.50
NO3-
1.97 ± 0.15
0.05
300
0.06
1.07
Solution
487
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488
Table 2. The pseudo-zero-order formation rate constants (k0) of
489
photochemical processes with H216O or H218O as the solvent.
18
O-hTPA and
16
O-hTPA in
k0hTPA (nM min-1) Solution a H216O (0.2%b) k0
16O-hTPA
k0
18O-hTPA
H218O (99%b) f
18O-hTPA c
k0
16O-hTPA
k0
18O-hTPA
f
18O-hTPA c
Ambient
30.26
0.20
0.6%
NAd
NA
NA
N2-purged
39.85
0.28
0.7%
27.56
5.50
16.8%
N2O-purged
214.23
2.18
1.0%
46.38
28.62
38.6%
490
a
[TPA]0 = 10 µM, light intensity: 4.35 mW cm-2 (365 nm).
491
b
The fraction of 18O in the solvent.
492
c
The fraction of 18O-hTPA: f
493
d
“NA” represents “not available”
18O-hTPA
= k0
18O-hTPA
/ (k0
16O-hTPA
18O-hTPA
+ k0
494
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Table 3. The inhibition effect of TBA on the pseudo-zero-order formation rate constant of hTPA. Solution a
k0hTPA (µM min-1) × 10-2
Inhibition Rate b
w/ TBA
w/o TBA
Ambient
0.13 ± 0.00
1.44 ± 0.09
91.0%
N2-purged
2.26 ± 0.37
3.06 ± 0.09
26.1%
N2O-purged
3.96 ± 0.10
13.82 ± 0.19
71.3%
496
a
[TPA]0 = 20 µM, [TBA]0 = 100 mM, light intensity: 4.72 mW cm-2 (365 nm).
497
b
Inhibition rate = 1- k0, w/ TBA/k0, w/o TBA.
498
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Scheme 1. The proposed pathways for the formation of hTPA in UV irradiated TPA solutions
500 501
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502
503 504
Figure 1. (a) The evolution of TPA (20 µM) under UV irradiation in ambient, N2-purged and N2O-
505
purged solutions. k1 (min-1): the pseudo-first-order degradation rate constant. (b) The k1 of TPA as
506
a function of N2O concentration. [TPA]0 = 20 µM, light intensity: 7.89 mW cm-2. Error bars
507
represent the standard deviation from at least duplicate experiments.
508
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509 510
Figure 2. (a) The k1 of TPA degradation and (b) the k0 of hTPA formation in photochemical
511
processes with the addition of nitrogen oxide. [TPA]0 = 20 µM, [NO2-]0 = [NO3-]0 = 5-100
512
µM, [N2O] = 24.1 mM. The dashed line represents the k1 and k0 in the absence of nitrogen
513
oxide.
514
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515 516
Figure 3. (a) The generation of H2O2 in UV irradiated ultrapure water (pH 6.0) and (b) the
517
generation of peroxides in UV irradiated TPA solutions (20 µM, pH: 9.0) under various gas
518
conditions.
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519 520
Figure 4. The k0 of hTPA formation under different irradiation and gas conditions. [TPA]0
521
= 20 µM, light intensity: 4.72 mW cm-2 (MP-Hg at 365 nm) and 0.40 mW cm-2 (LP-Hg at
522
254 nm).
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