Doping Metal Organic Frameworks with Ionic Liquids for
Adsorption of Tetracyclines from Water Samples
Yohannes Alula, Jie Tang and Shun Yao
*
College of Chemical Engineering, Sichuan University, Chengdu,610065, China
Keywords: Metal Organic Frameworks, Ionic Liquids, Tetracyclines, Adsorption.
Abstract: Ionic liquids (ILs) were supported on metal organic frameworks (MOFs) for adsorption of tetracyclines
(TCNs) from water samples. Benzothiazolium haxafluorophosphate IL when combined with Zeolitic
imidazolate framework-8 MOF ([HBth][PF
6
] @ZIF-8) demonstrated successful adsorption performance.
1 INTRODUCTION
The tetracyclines (TCs), including tetracycline,
chlorotetracycline and oxytetracycline, are a
chemically related group of bacteriostatic
antibiotics. They exhibit a broad spectrum of
antimicrobial activity, being effective against gram
positive and gram-negative aerobic and anaerobic
bacteria. Despite their introduction more than 50
years ago, tetracyclines are still widely popular for
human medicines (Katrin et al., 2016). Although
exposure to tetracyclines is well tolerated, they do
produce several adverse effects including
gastrointestinal irritation, phototoxicity and teeth
staining. They can also be introduced in surface
waters due to their veterinary use for livestock,
which have been ubiquitously available in the
aquatic environment via manure dispersion and
animal excretion. Their presence in natural waters
inevitably yields the spread of antibiotic resistance
in microorganisms. Therefore, there is a need to
bring effective method for the decontamination of
these drugs from water bodies.
The aim of this study is to enhance the efficiency
of potential adsorbents such as Metal Organic
Frameworks (MOFs), which have attracted
considerable attention for adsorption technology
owing to their high porosity, in removing TCs from
aquatic system. Metal–organic frameworks are a
class of crystalline porous hybrid materials
constructed after infinite connectivity of metal ions
or nodes and organic molecules called linkers via
self-assembly mechanism. MOFs have superior
adsorption properties compared to other porous
materials due to their large surface areas as well
tunable pore sizes varied from microporous to
mesoporous scale. Hence, the reported MOFs
(Rocío-Bautista et al., 2015) with various structural
topologies and unique functionalities is increasing
rapidly. Recently, MOFs have been studied for
adsorption of TCs from environmental waters. Wang
and coworkers (Wang et al., 2018) employed Fe-
based MOFs in removal of TCs by adsorption and
photocatalytic degradation simultaneously.
Moreover, some active species like metal
nanoparticles were also incorporated into the pores
of MOFs for better adsorption of TCs. Yang group
(Yang et al., 2019) reported an increase in
adsorption capacity of Cu and Co nanoparticles co-
doped MIL-101 (Cr) (Material Institute Lavoisier)
for TCs compared with the pristine MOF.
MOFs could be further customized by combining
with ionic liquids (denoted as IL@MOFs) which
could be able to overcome the drawbacks of parent
MOFs related to their poor dispersion in water. Ionic
liquids (ILs) are salts consist of positive and
negative charges bound together by electrostatic
interactions with melting points below 100
o
C. The
chemical and structural versatility of ILs make them
suitable guest molecule candidates for the facile
post-modification of MOFs as a host materials
(Kitagawa et al., 2015). As a consequence of the
coalition with MOFs, the ILs lose their liquid nature
but they still maintain their thermal stability and
chemical properties. Despite its great potential,
limited studies have been conducted on IL@ MOF
composite for adsorption applications. Jhung and
coworkers (Jhung et al., 2014) incorporated 1-butyl-
3-methylimidazolium chloride into the pores of
Alula, Y., Tang, J. and Yao, S.
Doping Metal Organic Frameworks with Ionic Liquids for Adsorption of Tetracyclines from Water Samples.
DOI: 10.5220/0008185700690072
In The Second International Conference on Materials Chemistry and Environmental Protection (MEEP 2018), pages 69-72
ISBN: 978-989-758-360-5
Copyright
c
2019 by SCITEPRESS – Science and Technology Publications, Lda. All rights reserved
69
MIL-101 by means of simple impregnation for the
adsorptive removal of benzothiophene from liquid
fuel. Later on, the same research group synthesized
the IL inside inside MIL-101 porous cavities via a
ship-in-bottle (SIB) technique for similar objectives
(Jhung et al., 2016). In this work, we explored
several ILs and MOFs when combined produces
synergetic effect for successful adsorptive
elimination of TCs from water samples. To the best
of our knowledge, no other published work
attempted to investigate IL@MOF for the same
application.
2 EXPERIMENTAL
2.1 Chemicals
Terephthalic acid (TPA, 98%), Chromium chloride
(CrCl
3
.6H
2
O, 96%), Zinc nitrate hexahydrate
(Zn(NO
3
)
2
.6H
2
O, 99%), 2-Methylimidazole (H-
MIM, 99%), Benzene- 1,3,5-tricarboxylicacid
(H
3
btc, 95%), Cu(NO
3
)
2
.2.5H
2
O, Chlorotetracycline,
Oxytetracycline and Tetracycline were supplied by
Kelong Chemicals (Chengdu, China). Ultrapure
water was obtained by a water purification system
A10 MilliPore (Bedford, MA). The ten ionic liquids
were chosen for this study, which included 1-butyl-
3-methylimidazolium chloride ([C
6
MIM][Cl
-
]), 1-
hexyl-3-methylimidazolium chloride ([C
4
MIM][Cl
-
]), 1-butyl-3-methylimidazolium tetrafluoroborate
([C
4
MIM][BF
4
]), 1-hexyl-3-methylimidazolium
tetrafluoroborate ([C
6
MIM][BF
4
]), 1-butyl-3-
methylimidazolium hexafluorophosphate
([C
4
MIM][PF
6
]), 1-hexyl-3-methylimidazolium
hexafluorophosphate ([C
6
MIM][PF
6
]),
benzothiazolium tetrafluoroborate ([HBth][BF
4
]),
benzothiazolium hexafluorophosphate
([HBth][PF
6
]), 8-hydroxyquinolinephosphate
([HOQu][H
2
PO
4
]), 8-hydroxyquinolinesulfate
([HOQu][HSO
4
]) and were synthesized in our lab
according to reported methods.
2.2 Synthesis of MOFs
2.2.1 Synthesis of ZIF-8
ZIF-8 (Zeolitic Imidazolate Framework) was
synthesized according to the procedure of Kitagawa
group (Kitagawa et al., 2015). A methanol solution
(75 mL) of Zn(NO
3
)2•6H
2
O (1.10 g, 3.70 mmol)
was added to a methanol solution (75 mL) of
H(MeIM) (1.22 g, 14.8 mmol) and triethylamine
(3.00 g, 29.7 mmol) at ambient temperature. The
mixture was stirred vigorously for a period of 1 h at
room temperature. The resultant white-colored
precipitate was collected using centrifugation, and
washed five times by methanol followed by drying
at 150
o
C.
2.2.2 Synthesis of MIL-101
MIL-101(Cr) was synthesized according to Jhung
(Jhung et al., 2016) group. In a typical synthesis,
MIL-101 was prepared from CrCl
3
•6H
2
O, TPA and
deionized water with reactants composition 1.0
CrCl
3
•6H
2
O : 1.0 TPA : 300 H
2
O. The precursor of
30 g was loaded in a Teflon-lined autoclave and put
in a preheated electric oven at 210
o
C for 8 hours.
After the reaction, the autoclave was cooled to room
temperature and solid green-colored products were
recovered by filtration. The MOF obtained was
purified in three steps. In the first step, 1.0 g MIL-
101 was added to 300 mL water and stirred
magnetically for 5 hours at 70
o
C. Then the MOF
was filtered and dried overnight. In the second step,
the dried MOF was added to 250 mL ethanol; stirred
magnetically at 60
o
C for 3 hours and then filtered.
In the third step, the MOF from the second step was
added to 150 mL 30 mM NH
4
F solution and stirred
for 10 hours at 60
o
C. Finally, it was filtered, washed
five times and then dried at 150
o
C.
2.2.3 Synthesis of HKUST-1
HKUST-1 was synthesized according to the
literature (Rocío-Bautista et al., 2015). Typically,
H
3
btc (0.630 gram, 3 mmol) was dissolved in 15 mL
of ethanol. Secondly, Cu(NO
3
)
2
•2.5H
2
O (1.255
gram, 5.4 mmol) was dissolved in 15 mL of
deionized water and then added dropwise to the
ethanolic solution of H
3
btc while stirring for 10 min.
The resultant solution mixture was transferred into a
45 mL Teflon lined stainless steel autoclave and
kept at 110
o
C for 24h. Then, the autoclave was
cooled down to room temperature and the crystalline
powder was isolated by filtration, washed with
ethanol several times and air dried at 50
o
C. Finally,
the purified MIL-101 was dehydrated at 150
o
C
overnight.
2.3 Synthesis of IL@MOF Composites
Wet impregnation method (Henni et al., 2018) was
used for synthesizing the IL/MOF composites. The
specified amount of IL was weighed out in a
scintillation vial. Then 3 mL of methanol was added
to the specified amount of IL, and the vial was
gently mixed until the IL was dissolved. The total
MEEP 2018 - The Second International Conference on Materials Chemistry and Environmental Protection
70
amount of ionic liquid used for the impregnation
varied depending on the maximum value of IL
desired in the resulting composite. The solution was
added dropwise to the preweighted ZIF-8 material,
and the composite was dried at 70 °C overnight to
remove any remaining solvent and stored in a
desiccator.
2.4 Characterization
The size and image of microcrystals was observed
with JSM-7001F scanning electron microscopy
(SEM) (JEOL Co., Ltd., Tokyo, Japan) and X-ray
diffraction (XRD) patterns were recorded on a D8
X-ray diffractometer equipped with accessional
analytical system (Bruke, Karlsruhe, Deutschland).
Thermogravimetric analysis (TGA) was performed
on a TG 209 Fl Iris instrument (NETZSCH-
Gerätebau GmbH, Selb, Deutschland) with a heating
rate of 10
o
C min
-
1 from 30 to 800
o
C under
nitrogen.
2.5 Adsorption Experiment
All the IL@MOFs were heated at 150
o
C for 12
hours in a vacuum oven before being used as an
adsorbent. The adsorption study was carried out as
follows: 5 mg IL@MOF mixed with 20 mL sample
solution of 10 ppm in 50 mL Erlenmeyer flask. The
mixture was shaken in a water-bath oscillator (100
rpm) for 35 min 25
o
C. After full adsorption, the
flask was centrifuged at 6000 rpm for 5 min, and
then the UV-visible absorbance of the supernatant
was measured at 355 nm.
Table 1: Data for adsorption efficiency of Oxytetracycline
over ZIF-8 and [HBth][PF
6
]@ZIF-8.
Adsorbent
E (%)
ZIF-8
49
10% IL@ZIF-8
62
20% IL@ZIF-8
71
25% IL@ZIF-8
77
30% IL@ZIF-8
75
Table 2: Data for adsorption efficiency of TCNs over
[HBth][PF
6
]@ZIF-8 in 0.30 to 1 molar ratio.
TCNs
E(%)
chlorotetracycline
82.2
oxytetracycline
89.8
tetracycline
91.5
E % = ((C
0
– C
1
) × 100%)/C
0
(1)
3 RESULTS AND DISCUSSION
3.1 Properties of Adsorbents
The SEM images presented in Figure 1 and 2 show
that the surface morphology of ZIF-8 changed after
incorporation of ILs which indicates the existence of
guests inside the pores of MOFs. The XRD
experiment illustrated that the crystal phases of
pristine and modified MOFs have remarkable
similarity, which is confirming successful synthesis
and stability of the MOFs even after decorated with
ionic liquids. TGA analysis revealed the synthesized
adsorbents are stable up to nearly 400
o
C.
Figure 1: SEM image of ZIF-8 before incorporation of IL.
Figure 2: SEM image of [HBth][PF
6
]@ZIF-8 composite.
3.2 Adsorption Efficiency of MOFs
An initial investigation was carried out to identify
the appropriate MOF as an adsorbent based on
calculation of adsorption efficiency (E %) for each
MOF according to equation 1, where, C
0
and C
1
(mgL
-1
) are Concentrations of TCs before and after
adsorption respectively. Considering that the
adsorption is performed in aqueous solution, the
potential adsorbents needs to be water stable. Three
Metal Organic frame works specifically, MIL-101,
HKUST-1 and ZIF-8 were chosen and examined for
adsorptive removal of one type of TCs (named
oxytetracycline, OTC) from aqueous solution.
Parameters that affect the adsorption condition such
as, initial concentration of adsorbent and adsorption
time were optimized for each of the three MOFs
before the study of their adsorptive performances.
Doping Metal Organic Frameworks with Ionic Liquids for Adsorption of Tetracyclines from Water Samples
71
The results reveal that E (%) is 58.2%, 55.6%, 49.3
% for MIL-101, HKUST-1 and ZIF-8, respectively.
This trend could be attributed to the complex
formation reaction between TCNs and
coordinatively unsaturated (CUS) sites in MIL-101
and HKUST-1. The absence of open metal site may
have an impact in the case of ZIF-8 for its relatively
lowered adsorption performance.
3.3 Effect of Ionic Liquids
One of the alternatives considered to upgrade the
adsorption properties of those MOFs was to decorate
with ILs following a post-synthetic modification. It
was expected to lead to a higher performance for
adsorption than the pristine MOFs. Ten ionic liquids
were tested as potential guests, introduced into the
pores of virgin MOFs targeted for TCs adsorption.
Tetracyclines are complex hydrophilic drugs having
high solubility in water and can exist both in acidic
and basic form. The highest adsorption efficiency of
77.4% were obtained for the three TCs during the
combination of [HBth][PF6] with ZIF-8. The best
result was specifically obtained when [HBth][PF6]
to ZIF-8 ratio was increased to 25 % as depicted on
Table 1. The high adsorption efficiency of the
IL@MOFs could be due to the capability of ILs to
create complex interaction of columbic forces and π-
π interaction with TCs. Generally the ILs improves
the adsorption efficiency of all the studied MOFs to
a greater extent.
3.4 Doping by Capillary Action
Once [HBth][PF6] @ZIF-8 was selected as the best
adsorbent, improving the stability of the hybrid
composite, in order to keep the ILs inside the pores
of MOF was considered. The effect of capillary
action was studied as an alternative synthesis
strategy, since ZIF-8 has no open metal sites. The
[HBth][PF
6
] was mixed with activated ZIF-8 powder
using mortar and pestle in a molar ratio of 0.20:1,
0.25:1, 0.30:1 and 0.35:1. The mixture was heated
and stored overnight to enhance the diffusion of the
IL through pores of ZIF-8. As shown in Table 2, the
adsorbed quantities of TCNs increased to a
significant extent until the IL to MOF ratio became
0.30 to 1. The capillary action improves the
confinement of IL inside ZIF-8 pores and hence, the
stability of the resulting composite, which brought
great potential in the way of increasing the
adsorption efficiency of TCNs.
4 CONCLUSIONS
In summary, imidazolium, hydroxyquinolium and
benzothiazolium ionic liquids were impregnated on
water stable metal organic frameworks and
investigated for adsorption of TCNs. ZIF-8 when
combined with one type of benthothiazolium IL
showed highest adsorption efficiency, especially
after doping by capillary action. The result proves
that the adsorption properties of MOFs could be well
improved by using appropriate ILs.
ACKNOWLEDGEMENTS
The authors thank the National Natural Science
Foundation of China (No. 81373284, 81673316).
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