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Insight into the dispersive mechanism of Carboxylated Nanofibrilllated cellulose for individual montmorillonite in water
Journal Pre-proof Insight into the dispersive mechanism of Carboxylated Nanofibrilllated cellulose for individual montmorillonite in water Chuan Sun, Zhiqiang Fang, Famei Qin, Kaihuang Chen, Jingyu Wang, Zixian Ding, Xueqing Qiu PII:
S1359-8368(19)33238-X
DOI:
https://doi.org/10.1016/j.compositesb.2019.107399
Reference:
JCOMB 107399
To appear in:
Composites Part B
Received Date: 8 July 2019 Revised Date:
26 August 2019
Accepted Date: 27 August 2019
Please cite this article as: Sun C, Fang Z, Qin F, Chen K, Wang J, Ding Z, Qiu X, Insight into the dispersive mechanism of Carboxylated Nanofibrilllated cellulose for individual montmorillonite in water, Composites Part B (2019), doi: https://doi.org/10.1016/j.compositesb.2019.107399. This is a PDF file of an article that has undergone enhancements after acceptance, such as the addition of a cover page and metadata, and formatting for readability, but it is not yet the definitive version of record. This version will undergo additional copyediting, typesetting and review before it is published in its final form, but we are providing this version to give early visibility of the article. Please note that, during the production process, errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain. © 2019 Published by Elsevier Ltd.
SYNOPSIS: Illuminate the disperse mechanism of Carboxylated Nanofibrilllated as a green dispersant dispersing individual Montmorillonite at different dosage by AFM.
Insight into the Dispersive Mechanism of Carboxylated Nanofibrilllated Cellulose for Individual Montmorillonite in Water Chuan Suna, Zhiqiang Fangb,c,*, Famei Qina, Kaihuang Chena, Jingyu Wanga, Zixian Dinga, Xueqing Qiua,b,* a
School of Chemistry and Chemical Engineering, South China University of Technology, Guangzhou 510640, China
b
State Key Laboratory of Pulp and Paper Engineering, South China University of Technology, Guangzhou 510640, China c Laboratory of Pulp and Paper Science & Technology of Ministry of Education/Shandong Province, Qilu University of Technology (Shandong Academy of Sciences), Jinan 250353, China
Abstract: Carboxylated nanofibrillated cellulose (CNFC) has emerged as a promising green dispersant to prepare stable aqueous individual montmorillonite (MMT) suspensions. Nevertheless, its underlying dispersive mechanism remains elusive. Herein, we attempt to unveil the dispersive mechanism of CNFC for individual MMTs in water by characterizing the interfacial interactions between the two components using a quartz crystal microbalance with dissipation monitoring (QCM-D) and an atomic force microscopy (AFM). Both electrostatic repulsion and steric hindrance contribute to the excellent stability of homogeneous individual MMT suspensions, and their individual contributions are dependent upon the dosage of CNFC dispersant. The electrostatic repulsive forces dominate over the van der Waals forces that trigger the aggregation of aqueous individual MMTs when the dosage of CNFCs is 2 wt% (based on individual MMTs). With increasing dosage of CNFC dispersant, the electrostatic repulsive forces between individual MMTs tend to be level off while the steric hindrance gradually becomes a dominant factor that influences the dispersion stability of aqueous individual MMT suspensions. Finally, the effect of the CNFC dispersant’s dosage on the optical and mechanical properties of nanocomposite film made with CNFCs and CNFC-dispersed individual MMTs is investigated. Understanding the dispersing principle of CNFCs for individual MMTs
1
in water could pave the way to extend the applications of MMT in numerous value-added fields such as high-performance nanocomposites and flexible electronics.
Keywords: Carboxylated nanofibrillated cellulose; Individual montmorillonite; Dispersive mechanism; Interfacial interactions; Green dispersant
2
1
1. Introduction
2
Montmorillonite (MMT) has considered an environmentally friendly natural
3
material for numerous high-tech applications (e.g., high-performance nanocomposites,
4
catalysis, water treatment, electronic devices, and biomedicine) due to its earth
5
abundance, geometric platelet shape, ionic exchange character, and biocompatibility
6
[1-3]. Exfoliating layered MMTs into their fundamental units (individual MMTs) with
7
an average thickness of 1 nm is a viable approach to completely unlock their potential
8
capability such as catalytic and adsorption efficiency, and superior mechanical
9
properties [4-6]. However, individual MMTs are prone to aggregate in aqueous
10
solutions because of inherent van der Waals, and/or ionic bond interactions etc.,[7]
11
which significantly limits the utilization of their unique physical properties.
12
An effective dispersion strategy to suppress the strong self-aggregation tendency
13
of individual MMTs in water involves the use of low cost and easy processing
14
dispersants (e.g., sodium hexametaphosphate [8], sodium polyacrylate [9] and sodium
15
polyphosphate [10]). Nevertheless, there are several issues raised by those dispersants:
16
(1) some dispersants derived from petroleum-based chemicals are hazardous to
17
environment and human’s healthcare; (2) the introduction of dispersants may
18
deteriorate the interfacial interactions between MMTs and other substances in some
19
cases [8-10].
20
Thanks to amphiphilic characteristics and tunable surface chemistry and fibril
21
morphology [11], carboxylated nanofibirllated cellulose (CNFC) derived from 2, 2, 6,
22
6-tetramethylpiperidine-1-oxyl radical (TEMPO)-mediated oxidization has recently
23
emerged as an effective and green dispersant to disperse inorganic nanomaterial (e. g.
24
carbon nanomaterials [12-14], clay nanoplatelets [15], hexagonal boron nitride (BN) 3
25
[16,17] and molybdenum disulfide (MoS2))[16] in water. As a consequence,
26
homogeneous dispersions with superior colloidal stability were prepared to use in the
27
design of advanced functional materials for electronics and energy storage devices.
28
Our group previously demonstrated a homogeneous and stable individual MMT
29
suspension in an aqueous solution by using CNFC as a dispersant, assisted by
30
ultrasonic treatment. Such stable colloidal suspension enabled the formation of highly
31
ordered structure of CNFC-individual MMT films that presented a total light
32
transmittance of 90% at 600 nm even when the loading weight of MMTs reached 50
33
wt %.
34
Although CNFC confers aqueous individual MMT suspension with excellent
35
colloidal stability, seldom endeavor has been devoted to exploring its dispersive
36
mechanism for individual MMT suspensions. In this work, CNFC derived from
37
TEMPO-oxidized system was used as an effective and green dispersant to promote
38
the colloidal stability of aqueous individual MMT suspension and its underlying
39
dispersive mechanism was comprehensively explored by characterizing the interfacial
40
interactions between CNFC and MMTs using a quartz crystal microbalance with
41
dissipation monitoring (QCM-D) and an atomic force microscopy (AFM).
42
2. Materials and methods
43
2.1. Materials
44
Hardwood pulp (Hongta paper Co,.Ltd, Zhuhai) was used as raw material for the
45
preparation of carboxylated nanofibrillated cellulose (CNFC) by TEMPO oxidization
46
system. MMT powder was purchased from Nanocor Co,. Ltd, USA. TEMPO (98%,
47
AR) was purchased from Macklin Inc., Sodium hypochlorite solution (active chlorine
48
≥7.5%,AR) and sodium bromide were purchased from GuangZhou chemical reagent 4
49
co. Ltd, China, and DaMao (Tianjin) chemical reagent co. Ltd, China, respectively.
50
2.2. Preparation of CNFC and aqueous individual MMT suspensions
51
CNFC was prepared according to our previous publication [18]. Aqueous
52
individual MMT suspensions were prepared as follows: 1g MMT powder was
53
blended with CNFC at different dosage using 100 mL deionized water as solvent.
54
After that, the MMT suspension was stirred at 1000 rpm for 10 min, followed by
55
ultrasonification using an ultrasonic Cell Crusher (Ningbo Scientz Biotechnology Co,.
56
Ltd) for 10 min. finally, the treated MMT suspension was centrifuged at 5000 rpm for
57
20 min immediately to obtain aqueous individual MMT suspensions.
58
2.3. Characterization of aqueous individual MMT suspensions
59
The yield of individual MMT suspensions was measured by ash method. Firstly,
60
the CNFC-dispersed individual MMT suspension (m0) was dried at 105
for 4 h to
61
oven dry weight (m1), which was then burned in Muffle Furnace at 800
for 2 h to
62
remove the mass of CNFC, the weight of the residual mass of MMT was denoted as
63
m2. Finally, the yield was calculated according to equation 1:
64
୫
y = 100 ୫భ × మ × 100% బ
(1)
భ
65
The colloidal stability of aqueous individual MMT suspensions was measured by
66
a Turbiscan Lab analyzer (Formulaction Co., L’Union, France) for 5 h, where the
67
final Turbiscan stability index (TSI) was calculated by the light passed through and
68
back scattered of the suspension.
69
The size and thickness of the individual MMT were characterized by an atomic
70
force microscope imaging (XE-100, Park Systems, Korea).
71
2.4. AFM colloidal probe technique and substrate modification
72
The modified CNFC-coating SiO2 and MMT-coating SiO2 spheres were
73
prepared by layer-by-layer self-assembly as follows: SiO2 standard spheres (23µm) 5
74
were used as base spheres, CNFCs and individual MMTs were adhered to the surface
75
of SiO2 by silane coupling agent and poly dimethyl diallyl ammonium chloride
76
(PDAC)respectively. Then, the modified spheres were attached on the tipless probe
77
at the end of cantilever by using hot-melt adhesive. (AFM tipless probe (NP-O10,
78
Bruker Inc., Germany) with nominal cantilever spring constant of 0.12 N/m was used
79
in our experiment.
80
The force measurement substrate was obtained by layer-by-layer self-assembly
81
of PDAC-MMT on SiO2 substrate, and its morphology and roughness were
82
characterized by AFM imaging. The specific AFM force measurement and calculation
83
details were shown in supporting information.
84
2.5. QCM-D measurement
85
The adsorption behavior between CNFC and individual MMTs was further
86
confirmed by using a QCM-D (Q-Sense E1 instrument, Biolin Scientific, Sweden).
87
QCM-D crystal sensor was modified by layer-by-layer self-assembly of PADC and
88
individual MMTs, and its morphology was characterized by AFM imaging. The
89
specific QCM-D measurement and calculation details were shown in supporting
90
information.
91
3. Result and discussion
92
3.1. The dispersion capability of CNFC for MMTs
93
To understand the dispersion capability of CNFC for MMTs in water, three
94
samples with/without a dispersant were prepared. Note that the dispersion capability
95
of CNFC for MMTs is evaluated in terms of the yield of individual MMTs in water
96
and its colloidal stability. Control sample means dispersant-free individual MMT
97
suspension, while CNFC or carboxymethyl cellulose (CMC) was used as a dispersant
98
in the other two samples. Fig. 1a and b show the visual appearance of three prepared 6
99
samples before and after sitting for one week. In comparison to control sample with a
100
yield of 48.5%, both CMC and CNFC have a positive effect on the yield of individual
101
MMTs, showing a higher dispersion yield of 58.1% and 56.3%, respectively. After
102
sitting for 1 week, the yield of control sample decreases from 48.5% to 40.8%.
103
However, for CNFC-dispersed suspension, only a slight change in dispersion yield is
104
observed, decreasing from 56.3% to 54.8%. There is an obvious phase separation for
105
CMC-dispersed suspension due to the aggregate of individual MMTs in water (Fig.
106
1b). CNFC is, therefore, an effective dispersant for the preparation of individual
107
MMT suspension with desired dispersion yield and colloidal stability.
108
Additionally, the effect of the CNFC’s dosages on the colloidal stability of
109
aqueous individual MMT suspensions is quantified by a turbiscan lab analyzer. As the
110
dosage of CNFCs increases from 0 wt % to 50 wt %, the TSI (turbiscan stability index)
111
of aqueous individual MMT suspensions presents a declining tendency, which
112
indicates an increase in colloidal stability (Fig. 1c). Specifically, the CNFC has a
113
negligible effect on the stability of individual MMT suspension when its dosage is 2
114
wt %. An enhanced stability is achieved for aqueous suspensions with CNFC dosages
115
of 6 wt%, 10 wt%, and 15 wt%, but their corresponding TSI-time curves are almost
116
overlapping. When the CNFCs reach 50 wt%, the individual MMT suspension
117
exhibits the best colloidal stability. Interestingly, the growth trend in yields and
118
colloidal stability of aqueous individual MMT suspensions is quite similar with
119
increasing amount of CNFCs (Fig. 1d).
7
120 121
Fig. 1. Visual appearance of aqueous individual MMT dispersions with/without a
122
dispersant (CMC or CNFC) before (a) and after (b) sitting for 1 week. Note that the
123
dosage of CNFC or CMC is approximately 10 wt% (based on raw MMTs), the
124
number in pictures indicates the yield of individual MMT suspensions.
125
CNFC-dispersed individual MMT suspension exhibits better colloidal stability over
126
sample with CMC dispersant and control sample. (c) TSI-time curves and (d) yields
127
of individual MMT suspensions at different dosages (based on raw MMTs) of CNFC
128
dispersant.
129 130
In addition to improving the dispersion yield and colloidal stability, the addition
131
of CNFCs has the ability to protect individual MMT from dramatic fragmentation
132
during ultrasonic treatment. As we can see from the atomic force microscopy (AFM)
133
images in Fig. 2, CNFC-dispersed individual MMTs show a larger size than
134
dispersant-free control sample. The average size of individual MMTs without CNFCs
135
was approximately 85.4 nm measured by particle diameter analysis (Fig. 2a).
136
However, the individual MMTs with 6 wt% and 15 wt% CNFC dispersant exhibit an
137
average size of 181.3 nm (Fig. 2b) and 228.3 nm (Fig. 2c), respectively. The 8
138
improved average size of CNFC-dispersed individual MMTs is primarily ascribed to
139
the effective absorption of ultrasonication power by CNFCs.
140 141
Fig. 2. AFM height images of individual MMTs prepared with different dosage of
142
CNFC. (a) 0 wt%, (b) 6 wt%, and (c) 15 wt%.
143 144
3.2. Interfacial interaction between MMTs and CNFCs
145
To understand the underlying mechanism for the excellent dispersing capacity of
146
CNFCs for individual MMTs, the interfacial interactions between the CNFCs and the
147
individual MMTs were characterized comprehensively by using a QCM-D and an
148
AFM.
149
We initially investigated the affinity between the CNFCs and the individual
150
MMTs. Fig. 3a displays the AFM image of CNFC-dispersed individual MMTs. As we
151
can see from the AFM image that a small part of CNFCs could adsorb on the surface
152
of individual MMTs (yellow circles), and their affinity is further determined by a
153
QCM-D. Fig. 3b shows the adsorption behaviors of CNFC suspensions with different
154
concentrations on MMT film. As the concentration of CNFC dispersion increases 9
155
from 0.1 g/L to 0.75 g/L, an increase in adsorption capacity of CNFC on MMT (from
156
3.33 mg/cm2 to 4.20 mg/cm2) is observed. There is a strong adsorption between the
157
two components and increasing with the concentration of CNFC, indicating that Van
158
der Waals force and hydrogen bonds are stronger than repulsion interaction.
159
The adsorption and desorption behaviors of individual MMTs on CNFC film
160
were also performed by QCM-D analysis to further characterize the affinity between
161
the two components. We can see from Fig. 3c that △F2 (the change in frequency
162
after desorption) is almost equal to 1/2 △ F1 (the change in frequency after
163
adsorption). However, the change in frequency of MMTs adsorbed on CMC is equal
164
to its desorption change (Fig. S1). The difference between the △F1 and the △F2
165
suggests that there are stronger interfacial interactions between the individual MMTs
166
and the CNFCs in water.
167
An AFM was then utilized to investigate the surface morphology and roughness
168
of crystal sensor with an active top thin Au film for QCM-D analysis before and after
169
adsorption. Fig. 3d displays the surface morphology of thin Au film on crystal sensor,
170
with a surface roughness (Rq) of approximately 0.9 nm. After grafting individual
171
MMTs to PDAC-modified Au film, a uniform thin layer of individual MMT film was
172
deposited on the thin Au film (Fig. 3e), showing a Rq of lower than 5 nm over a 5 × 5
173
µm2 scanning area. After a saturation adsorption process using CNFC dispersion as a
174
flowing phase, a dense CNFC film fully covers on the individual MMT film (Fig. 3f).
175
And the dense structure of the CNFCs adsorbed on MMT film is similar to that of the
176
neat CNFC film (Fig. S2), suggesting a thin film of CNFC film was formed on MMT
177
film due to their strong interfacial interaction.
10
178 179
Fig. 3. The characterizations of the affinity between CNFCs and MMTs by QCM-D
180
and AFM analysis. (a) AFM height image of CNFC-dispersed individual MMTs.
181
Yellow circles suggest the adsorption of CNFC on the surface of MMTs. (b)
182
Adsorption behaviors of CNFC suspensions with different concentrations on MMT
183
film. (c) Adsorption and desorption of individual MMT suspension (0.1g/L) on CNFC
184
film. AFM images of (d) bare Au surface on crystal sensor, (e) individual MMT film
185
deposited on PDAC-modified Au surface, and (f) CNFC film adsorbed on the
186
aforementioned individual MMT film.
187 188
The strong adsorption of CNFCs by the individual MMTs in water is primarily
189
due to the hydrogen bonds formed between the hydroxyl groups in CNFC and the
190
negatively charged O atoms in MMT. To verify our hypothesis, QCM-D test and AFM
191
colloidal technique were adopted to investigate the interfacial interactions between the
192
CNFCs and the MMTs in pure water or urea solution.
193
Fig. 4a is a schematic drawing of the AFM measurement instrument including a
194
colloidal sphere probe modified with RSiX3 and CNFCs and a flat SiO2 substrate
195
modified with monolayer MMT surface. Urea is a well-known hydrogen-bond
196
breaker that has the ability to shield the hydrogen bonds between the CNFCs and the 11
197
individual MMTs. Herein, urea (1 mol/L) was added in CNFC suspension to reduce
198
the hydrogen bonds between the CNFCs and the individual MMTs. According to the
199
QCM-D characterization in Fig. 4b, the adsorption capacity of CNFC by individual
200
MMTs in urea solution is much smaller than that of CNFCs by individual MMTs in
201
pure water. In addition, AFM force measurement was applied to measure the
202
hydrogen bonding interaction between the two components. The adhesive force
203
between the CNFCs and the individual MMTs in 1 mol/L urea solution declines from
204
1.21 mN/m to 0.44 mN/m (Fig. 4c).
205
In conclusion, according to QCM-D analysis and AFM force measurements, the
206
hydrogen bonding interactions significantly contribute to the strong adsorption
207
between the individual MMTs and the CNFCs. The adsorption of CNFCs on MMTs
208
increases the electrostatic repulsive forces among individual MMTs, which lays the
209
foundation for obtaining stable colloidal suspensions of individual MMTs in water.
210 211
Fig. 4. (a) Schematic drawing (not to scale) of the colloidal sphere probe covered with
212
bilayer of RSiX3 and CNFCs and the flat MMT surface used for AFM force
213
measurements. (b) Adsorption of CNFCs on MMTs with/without urea. (c) 12
214
Force-distance curves between the CNFCs and the individual MMTs in pure water
215
and 1mol/L urea solution.
216 217
3.3. Dispersive mechanism of CNFCs for individual MMTs in water
218
To the best of our knowledge, the underlying mechanism for stabilizing
219
individual MMTs in water by CNFC dispersant remains ambiguous. Herein AFM
220
force measurement with colloidal probe technique was adopted to explore the
221
interaction mechanism from the molecular perspective [19-23]. Fig. 5a shows the
222
schematic of AFM for the measurement of force/distance (F/D) curves, which
223
includes a colloidal sphere probe first decorated with a thin layer of cationic PDAC,
224
followed by depositing individual MMTs, and an individual MMT modified substrate.
225
Generally, the AFM F/D curve contains trace curve and retrace curve. Fig. 5b is
226
a typical F/D curve between a MMT decorated probe and a MMT modified substrate.
227
In trace process, the total repulsive force increases gradually and then achieves the
228
maximum value when the MMT decorated probe approaches to the MMT modified
229
substrate. Herein we measured the approaching F/D curves in CNFC dispersions.
230
To explore the dispersion mechanism of CNFCs for individual MMTs,the
231
electrostatic and steric repulsions should be analyzed separately and individually.
232
Commonly, if just electrostatic force and van der Waals force exist in the dispersion
233
system,
234
Derjaguin-Landau-Verwey-Overbeek (DLVO) theory ( F(D)ୈ = F(D)ୈ +
235
F(D)ୈ; Where D represents the distance between colloidal probe and measurement
236
substrate, F(D)DLVO denotes DLVO force, F(D)VDW is van der Waals attraction force
237
while F(D)EDL represents electrostatic double layer repulsion force. As shown in Fig.
238
5c, the F/D curve is well agreement with DLVO theory fitting as the probe is
239
approaching the substrate. Nevertheless, a notable derivation between the measured
F/D
curve
could
be
13
well
fitted
by
classic
240
data and the fitting curves appears as the distance between the probe and the substrate
241
is less than 15 nm (Fig. 5c), which is ascribed to steric repulsion that is not considered
242
in DLVO theory.
243
After considering the influence of steric repulsion, the DLVO theory is modified
244
to DLVO-s theory ( F(D)ୈିୗ = F(D)ୈ + F(D)ୈ + F(D)ୗ (where F(D)S
245
represents steric repulsion force), and the DLVO-S fitting curve coincides well to
246
experiment data in the whole range. The individual proportion of electrostatic and
247
steric repulsion is as a function of distance (Fig. 5d). The electrostatic repulsion
248
belongs to long-range force that gradually decreases with the increase of distance
249
between the individual MMTs, while the steric resistance is the dominant repulsion at
250
shorter range, which rapidly decreases with increasing distance.
251 252
Fig. 5. (a) Schematic drawing (not to scale) of the colloidal sphere probe covered with
253
bilayer of PDAC and MMTs and the flat MMT surface used for AFM force
254
measurements in aqueous CNFC. (b) Typical AFM F/D curve between MMT
255
colloidal probe and MMT substrate. (c) F/D curve and corresponding DLVO and
256
DLVO-s fitting curves between the MMTs in 0.3g/L CNFC. (d) Proportion and
257
magnitude of electrostatic and steric repulsions at different distances.
258 14
259
As we presented above, the yield and stability of individual MMT suspension are
260
highly dependent on the dosage of CNFC dispersant. To understand the underlying
261
mechanism, we try to study the surface interactions between the MMTs through
262
measurements of approaching F/D curves in CNFC dispersions with varying
263
concentrations. Fig. 6a indicates the approaching F/D curves measured between the
264
individual MMTs in pure water and CNFC dispersions with different solid contents.
265
In pure water, attractive forces dominate the interfacial interaction between the
266
individual MMTs, which leads to the aggregation of aqueous individual MMT
267
suspensions. With increasing solid contents of CNFC dispersion, the interfacial
268
interactions between the individual MMTs change from attractive force to repulsive
269
force, and the intensity and range of repulsion increase as well.
270
To explain the individual contribution of electrostatic repulsion and steric
271
hindrance on the repulsive force between the individual MMTs in different CNFC
272
dispersions, the approaching F/D curves are fitted by the DLVO and DLVO-s models
273
(Fig. S3). According to the fitting results, several parameters are obtained to directly
274
determine the interaction intensity and range of repulsive forces between the
275
individual MMTs. Debye length and electrostatic interaction constant are for
276
electrostatic repulsion while characteristic length and steric interaction constant are
277
for steric repulsion. The Debye and characteristic lengths indicate the interaction
278
range of electrostatic repulsion and steric hindrance, respectively, while the
279
electrostatic and steric interaction constants relate to the interaction intensity of
280
electrostatic repulsion and steric hindrance, respectively, the larger the interaction
281
constant, the stronger the interaction intensity.
282
As shown in Fig. 6b, the Debye length and interaction constant of electrostatic
283
repulsion increases gradually and finally tends to be stable. The strong adsorption of 15
284
highly negative CNFCs (Fig. S4) on the surface of individual MMTs by hydrogen
285
bonding significantly improves their charge density, thus rendering the increase of
286
both Debye length (interaction length) and electrostatic interaction constant (intensity).
287
As the adsorption capacity of the individual MMTs reaches saturation point, the
288
electrostatic repulsion between the individual MMTs will be stable.
289
However, an obvious different phenomenon is observed for steric hindrance with
290
increasing concentrations of CNFC dispersion. The characteristic length demonstrates
291
an increasing tendency while a declining trend is observed for the steric interaction
292
constant (Fig. 6c). When the concentration of CNFC dispersion is low, the interaction
293
range of repulsive force is limited to the surface of the individual MMTs,but its
294
interaction constant is large due to the dense structure of the adsorption layer. As the
295
concentration of CNFC suspension continues to rise, the thickness of adsorbed CNFC
296
layer grows and more free CNFCs are presented, which lead to larger accessible
297
distance between the individual MMTs that finally renders the increasing interaction
298
range of steric repulsion. Moreover, the dense structure of the adsorbed CNFC layer
299
on the surface of MMTs tends to be loose with the growing thickness of adsorption
300
layer, thus resulting in the decrease of interaction constant of steric repulsion. Despite
301
the decrease of the steric interaction constant with the increasing concentrations of
302
CNFC suspension, the total steric repulsion demonstrates an increasing trend and
303
eventually become a dominant repulsion interaction.
16
304 305
Fig. 6. (a) F/D curves between individual MMTs in CNFC dispersions with varying
306
solid contents. (b) Electrostatic and (c) steric parameters in various CNFC dispersions
307
system.
308 309
In sum, the colloidal stability of individual MMTs suspensions enhances with
310
increasing concentrations of CNFC suspension. The electrostatic repulsion dominates
311
the interfacial interactions between the individual MMTs at long range while the
312
steric hindrance is a predominant factor at short range. As the increase of CNFC
313
concentration, the individual MMT suspension tends to be more stable due to the
314
increase of total repulsion. More significantly, the role of electrostatic repulsion and
315
steric resistance in the colloidal stability of individual MMT suspensions is highly
316
dependent on the concentrations of CNFC suspension. When the CNFCs’
317
concentration reaches 0.1 g/L, the colloidal stability of individual MMTs suspension
318
is mainly due to electrostatic repulsive forces, but the steric hindrance gradually
319
become a predominant repulsion as the concentration increases continuously.
320 17
321
3.4. CNFC-dispersed individual MMTs for nanocomposite films with excellent
322
properties
323
Normally, the addition of individual MMTs into pure CNFC films will inevitably
324
deteriorate their excellent optical and mechanical properties due to the easy
325
aggregation of sheet-like MMTs. However, incorporating CNFC-dispersed individual
326
MMTs into CNFC dispersion could address above challenge and obtain
327
nanocomposite films with optical and mechanical properties comparable to pure
328
CNFC films.
329
Fig. 7a and b shows the optically transparent appearance of nanocomposite films
330
containing 30 wt% individual MMTs obtained by using 0 wt% or 50 wt% CNFC
331
dispersant. Pure CNFC film presents a transmittance of 90.4% at 550 nm and a tensile
332
strength of 128 MPa. However, nanocomposite film demonstrates a decrease in the
333
optical transparency (88.0% at 550 nm) and tensile strength (118 Mpa) when
334
individual MMTs are added (Fig. 7c and d). When individual MMTs with 50 wt %
335
CNFC dispersant were blended with CNFC to prepare nanocomposite film, the
336
resulting nanocomposite film presents a similar transparency (90.3% at 550 nm) and a
337
better tensile strength (143 MPa) compared to pure CNFC films.
338
The reason behind the enhanced transparency is mainly due to the superior
339
colloidal stability of individual MMT suspension using 50 wt% CNFCs as a
340
dispersant that significantly contributes to the formation of ordered structure within
341
film during self-assembly [24-25]. In addition, with increasing CNFC dispersant’s
342
dosage, larger planar size is obtained for individual MMTs, which enables the
343
enhancement in tensile strength.
18
344 345
Fig.7. Visual appearances of nanocomposite films with 30 wt% individual MMTs
346
obtained by using (a) 0 wt% or (b) 50 wt% CNFC dispersant. (c) Total light
347
transmission and (d) tensile strength of pure CNFC film and nanocomposite films
348
with 30 wt% individual MMTs obtained by using 0 wt% or 50 wt% CNFC
349
dispersant .
350 351
4. Conclusions
352
In summary, a comprehensive understanding of the dispersive mechanism of
353
CNFCs for individual MMTs is unveiled by AFM colloidal technique and QCM-D.
354
There is a strong affinity between the two components primarily resulting from the
355
hydrogen bonding interaction, which lays the foundation for preparing stable colloidal
356
suspensions of individual MMTs. Moreover, both the long-range electrostatic
357
repulsion and short-range steric resistance contribute to the colloidal stability of
358
individual MMTs in water and their individual contributions are dependent on the
359
dosage of CNFC dispersant. When the concentration of CNFC dispersant is lower
360
than 2 wt%, the electrostatic repulsion is the dominant interaction for the colloidal
361
stability of individual MMTs. As the CNFC’s dosage continues to increase, the role of
362
steric hindrance in the interfacial interactions grows gradually and eventually
363
becomes a predominant repulsion. Finally, the addition of CNFC-dispersed individual
364
MMTs into pure CNFC film will not deteriorate their optical and mechanical 19
365
properties. When the dosage of CNFC dispersant is 50 wt%, the resulting
366
nanocomposite film with 30 wt% individual MMTs demonstrated a similar
367
transparency (90.3%) at 550 nm and a better strength (143 MPa) compared to pure
368
CNFC film. This work gives a comprehensive insight on the dispersive mechanism of
369
CNFCs for individual MMTs in water and may extend the use of MMTs in numerous
370
value-added fields, such as high-performance nanocomposites and flexible
371
electronics.
372 373
Author information
374
*Corresponding author: [email protected] (Z. Fang), [email protected] (X. Qiu),
375 376
Acknowledge
377
We appreciate the Pearl River S&T Nova Program of Guangzhou (grant no.
378
201806010141), the National Natural Science Foundation of China (grant no.
379
21978103, 31700508), the Natural Science Foundation of Guangdong Province,
380
China (grant no. 2017A030310635), Science and Technology Program of Guangdong
381
Province (grant no. 2017B090903003), and the Foundation (grant no. KF201812) of
382
Key Laboratory of Pulp and Paper Science and Technology of Ministry of
383
Education/Shandong Province of China.
384 385 386 387 388 389 390 391 392 393 394 395 396 397
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carboxylated cellulose nanofibrils. Adv. Funct. Mater 2017; 28(27): 1703277-1703288. (6) Jeffrey G, Hatsuo I. A review on the very high nanofiller-content nanocomposites: their preparation methods and properties with high aspect ratio fillers. Prog. Ploym. Sci 2019; 89: 1-39. (7) Chiu CW, Huang TK, Wang YC, Alamani BG, Lin JJ. Intercalation strategies in clay/polymer hybrids. Prog. Ploym. Sci 2014; 39(3): 443-485. (8) Morsy FA, El-Sherbiny S, Hassan MS, Mohammed H. Modification and evaluation of egyptian kaolinite as pigment for paper coating. Powder Technol 2014; 264(3): 430-438. (9) Loginov M, Larue O, Lebovka N, Vorobiev E. Fluidity of highly concentrated kaolin suspensions: influence of particle concentration and presence of dispersant. Colloid Aurface A 2008; 325(1): 64-71. (10) Papo A, Piani L, Ricceri R. Sodium tripolyphosphate and polyphosphate as dispersing agents for kaolin Suspensions: rheological characterization. Colloid Aurface A 2013; 6(1): 219-230. (11) Zhu H, Luo W, Ciesielski PN, Fang ZQ, Zhu JY, Henriksson G, Himmel ME, Hu LB. Wood-derived materials for green electronics, biological devices, and energy applications. Chem. Rev 2016; 116(16): 9305-9374. (12) Hajian A, Lindstrom SB, Pettersson T, Hamedi MM, Wågberg L. Understanding the dispersive action of nanocellulose for carbon nanomaterials. Nano Lett 2017; 17(3): 1439-1447. (13) Song N, Jiao J, Cui S, Hou X, Ding P, Shi L. Highly anisotropic thermal conductivity of layer-by-layer assembled nanofibrillated cellulose/graphene nanosheets hybrid films for thermal management. Acs Appl. Mater. Interfaces 2017; 9(3): 2924- 2932. (14) Yang W, Yu Z, Liu T, Huang R. A completely green approach for the preparation of strong and highly conductive graphene composite film by using nanocellulose as dispersing agent and mechanical compression. Acs Sustainable Chem. Eng. 2017; 5(10): 9102–9113. (15) Ming SY, Chen G, He J, Kuang Y, Liu Y, Tao R, Ning H, Zhu P, Liu Y, Fang ZQ. Highly transparent and self-extinguishing nanofibrillated cellulose-monolayer clay nanoplatelet hybrid films. Langmuir 2017; 33(34): 8455-8462. (16) Li Y, Zhu H, Shen F, Wang JY, Laceya S, Fang Z, Dai H, Hu L. Nanocellulose as green dispersant for two-dimensional energy materials. Nano Energy 2015; 13: 346-354. (17) Zeng X, Sun J, Yao Y, Sun R. A combination of boron nitride nanotubes and cellulose nanofibers for the preparation of a nanocomposite with high thermal conductivity. Acs Nano 2017; 11(5): 5167–5178. (18) Fang ZQ, Zhu HL, Colin P, Han XG. Highly transparent and writable wood all-cellulose hybrid nanostructured paper. J. Mater. Chem. C 2013; 1: 6191-6197. (19) Sinha P, Szilagyi I. Montes Ruiz-Cabello FJ, Maroni P, Borkovec M. Attractive forces between charged colloidal particles induced by multivalent ions revealed by confronting aggregation and direct force measurements. J. Phys. Chem. Lett 2013; 4(4): 648-652. (20) Ferrari L, Kaufmann J, Winnefeld F, Plank J. Impact of particle size on interaction forces between ettringite and dispersing comb-polymers in various electrolyte solutions. J. Colloid Interface Sci 2014; 419(419): 17-24. (21) Ferrari L, Kaufmann J, Winnefeld F, Plank J, Interaction of cement model systems with superplasticizers investigated by atomic force microscopy, zeta potential, and adsorption measurements. J. Colloid Interface Sci 2010; 347(1): 15-24. (22) Wang J, Li J, Lei X, Shi C, Liu QX, Zeng HB. Interactions between elemental selenium and hydrophilic/hydrophobic surfaces: direct force measurements using AFM. Chem. Eng. J 2016; 21
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S1359-8368(19)33238-X
DOI:
https://doi.org/10.1016/j.compositesb.2019.107399
Reference:
JCOMB 107399
To appear in:
Composites Part B
Received Date: 8 July 2019 Revised Date:
26 August 2019
Accepted Date: 27 August 2019
Please cite this article as: Sun C, Fang Z, Qin F, Chen K, Wang J, Ding Z, Qiu X, Insight into the dispersive mechanism of Carboxylated Nanofibrilllated cellulose for individual montmorillonite in water, Composites Part B (2019), doi: https://doi.org/10.1016/j.compositesb.2019.107399. This is a PDF file of an article that has undergone enhancements after acceptance, such as the addition of a cover page and metadata, and formatting for readability, but it is not yet the definitive version of record. This version will undergo additional copyediting, typesetting and review before it is published in its final form, but we are providing this version to give early visibility of the article. Please note that, during the production process, errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain. © 2019 Published by Elsevier Ltd.
SYNOPSIS: Illuminate the disperse mechanism of Carboxylated Nanofibrilllated as a green dispersant dispersing individual Montmorillonite at different dosage by AFM.
Insight into the Dispersive Mechanism of Carboxylated Nanofibrilllated Cellulose for Individual Montmorillonite in Water Chuan Suna, Zhiqiang Fangb,c,*, Famei Qina, Kaihuang Chena, Jingyu Wanga, Zixian Dinga, Xueqing Qiua,b,* a
School of Chemistry and Chemical Engineering, South China University of Technology, Guangzhou 510640, China
b
State Key Laboratory of Pulp and Paper Engineering, South China University of Technology, Guangzhou 510640, China c Laboratory of Pulp and Paper Science & Technology of Ministry of Education/Shandong Province, Qilu University of Technology (Shandong Academy of Sciences), Jinan 250353, China
Abstract: Carboxylated nanofibrillated cellulose (CNFC) has emerged as a promising green dispersant to prepare stable aqueous individual montmorillonite (MMT) suspensions. Nevertheless, its underlying dispersive mechanism remains elusive. Herein, we attempt to unveil the dispersive mechanism of CNFC for individual MMTs in water by characterizing the interfacial interactions between the two components using a quartz crystal microbalance with dissipation monitoring (QCM-D) and an atomic force microscopy (AFM). Both electrostatic repulsion and steric hindrance contribute to the excellent stability of homogeneous individual MMT suspensions, and their individual contributions are dependent upon the dosage of CNFC dispersant. The electrostatic repulsive forces dominate over the van der Waals forces that trigger the aggregation of aqueous individual MMTs when the dosage of CNFCs is 2 wt% (based on individual MMTs). With increasing dosage of CNFC dispersant, the electrostatic repulsive forces between individual MMTs tend to be level off while the steric hindrance gradually becomes a dominant factor that influences the dispersion stability of aqueous individual MMT suspensions. Finally, the effect of the CNFC dispersant’s dosage on the optical and mechanical properties of nanocomposite film made with CNFCs and CNFC-dispersed individual MMTs is investigated. Understanding the dispersing principle of CNFCs for individual MMTs
1
in water could pave the way to extend the applications of MMT in numerous value-added fields such as high-performance nanocomposites and flexible electronics.
Keywords: Carboxylated nanofibrillated cellulose; Individual montmorillonite; Dispersive mechanism; Interfacial interactions; Green dispersant
2
1
1. Introduction
2
Montmorillonite (MMT) has considered an environmentally friendly natural
3
material for numerous high-tech applications (e.g., high-performance nanocomposites,
4
catalysis, water treatment, electronic devices, and biomedicine) due to its earth
5
abundance, geometric platelet shape, ionic exchange character, and biocompatibility
6
[1-3]. Exfoliating layered MMTs into their fundamental units (individual MMTs) with
7
an average thickness of 1 nm is a viable approach to completely unlock their potential
8
capability such as catalytic and adsorption efficiency, and superior mechanical
9
properties [4-6]. However, individual MMTs are prone to aggregate in aqueous
10
solutions because of inherent van der Waals, and/or ionic bond interactions etc.,[7]
11
which significantly limits the utilization of their unique physical properties.
12
An effective dispersion strategy to suppress the strong self-aggregation tendency
13
of individual MMTs in water involves the use of low cost and easy processing
14
dispersants (e.g., sodium hexametaphosphate [8], sodium polyacrylate [9] and sodium
15
polyphosphate [10]). Nevertheless, there are several issues raised by those dispersants:
16
(1) some dispersants derived from petroleum-based chemicals are hazardous to
17
environment and human’s healthcare; (2) the introduction of dispersants may
18
deteriorate the interfacial interactions between MMTs and other substances in some
19
cases [8-10].
20
Thanks to amphiphilic characteristics and tunable surface chemistry and fibril
21
morphology [11], carboxylated nanofibirllated cellulose (CNFC) derived from 2, 2, 6,
22
6-tetramethylpiperidine-1-oxyl radical (TEMPO)-mediated oxidization has recently
23
emerged as an effective and green dispersant to disperse inorganic nanomaterial (e. g.
24
carbon nanomaterials [12-14], clay nanoplatelets [15], hexagonal boron nitride (BN) 3
25
[16,17] and molybdenum disulfide (MoS2))[16] in water. As a consequence,
26
homogeneous dispersions with superior colloidal stability were prepared to use in the
27
design of advanced functional materials for electronics and energy storage devices.
28
Our group previously demonstrated a homogeneous and stable individual MMT
29
suspension in an aqueous solution by using CNFC as a dispersant, assisted by
30
ultrasonic treatment. Such stable colloidal suspension enabled the formation of highly
31
ordered structure of CNFC-individual MMT films that presented a total light
32
transmittance of 90% at 600 nm even when the loading weight of MMTs reached 50
33
wt %.
34
Although CNFC confers aqueous individual MMT suspension with excellent
35
colloidal stability, seldom endeavor has been devoted to exploring its dispersive
36
mechanism for individual MMT suspensions. In this work, CNFC derived from
37
TEMPO-oxidized system was used as an effective and green dispersant to promote
38
the colloidal stability of aqueous individual MMT suspension and its underlying
39
dispersive mechanism was comprehensively explored by characterizing the interfacial
40
interactions between CNFC and MMTs using a quartz crystal microbalance with
41
dissipation monitoring (QCM-D) and an atomic force microscopy (AFM).
42
2. Materials and methods
43
2.1. Materials
44
Hardwood pulp (Hongta paper Co,.Ltd, Zhuhai) was used as raw material for the
45
preparation of carboxylated nanofibrillated cellulose (CNFC) by TEMPO oxidization
46
system. MMT powder was purchased from Nanocor Co,. Ltd, USA. TEMPO (98%,
47
AR) was purchased from Macklin Inc., Sodium hypochlorite solution (active chlorine
48
≥7.5%,AR) and sodium bromide were purchased from GuangZhou chemical reagent 4
49
co. Ltd, China, and DaMao (Tianjin) chemical reagent co. Ltd, China, respectively.
50
2.2. Preparation of CNFC and aqueous individual MMT suspensions
51
CNFC was prepared according to our previous publication [18]. Aqueous
52
individual MMT suspensions were prepared as follows: 1g MMT powder was
53
blended with CNFC at different dosage using 100 mL deionized water as solvent.
54
After that, the MMT suspension was stirred at 1000 rpm for 10 min, followed by
55
ultrasonification using an ultrasonic Cell Crusher (Ningbo Scientz Biotechnology Co,.
56
Ltd) for 10 min. finally, the treated MMT suspension was centrifuged at 5000 rpm for
57
20 min immediately to obtain aqueous individual MMT suspensions.
58
2.3. Characterization of aqueous individual MMT suspensions
59
The yield of individual MMT suspensions was measured by ash method. Firstly,
60
the CNFC-dispersed individual MMT suspension (m0) was dried at 105
for 4 h to
61
oven dry weight (m1), which was then burned in Muffle Furnace at 800
for 2 h to
62
remove the mass of CNFC, the weight of the residual mass of MMT was denoted as
63
m2. Finally, the yield was calculated according to equation 1:
64
୫
y = 100 ୫భ × మ × 100% బ
(1)
భ
65
The colloidal stability of aqueous individual MMT suspensions was measured by
66
a Turbiscan Lab analyzer (Formulaction Co., L’Union, France) for 5 h, where the
67
final Turbiscan stability index (TSI) was calculated by the light passed through and
68
back scattered of the suspension.
69
The size and thickness of the individual MMT were characterized by an atomic
70
force microscope imaging (XE-100, Park Systems, Korea).
71
2.4. AFM colloidal probe technique and substrate modification
72
The modified CNFC-coating SiO2 and MMT-coating SiO2 spheres were
73
prepared by layer-by-layer self-assembly as follows: SiO2 standard spheres (23µm) 5
74
were used as base spheres, CNFCs and individual MMTs were adhered to the surface
75
of SiO2 by silane coupling agent and poly dimethyl diallyl ammonium chloride
76
(PDAC)respectively. Then, the modified spheres were attached on the tipless probe
77
at the end of cantilever by using hot-melt adhesive. (AFM tipless probe (NP-O10,
78
Bruker Inc., Germany) with nominal cantilever spring constant of 0.12 N/m was used
79
in our experiment.
80
The force measurement substrate was obtained by layer-by-layer self-assembly
81
of PDAC-MMT on SiO2 substrate, and its morphology and roughness were
82
characterized by AFM imaging. The specific AFM force measurement and calculation
83
details were shown in supporting information.
84
2.5. QCM-D measurement
85
The adsorption behavior between CNFC and individual MMTs was further
86
confirmed by using a QCM-D (Q-Sense E1 instrument, Biolin Scientific, Sweden).
87
QCM-D crystal sensor was modified by layer-by-layer self-assembly of PADC and
88
individual MMTs, and its morphology was characterized by AFM imaging. The
89
specific QCM-D measurement and calculation details were shown in supporting
90
information.
91
3. Result and discussion
92
3.1. The dispersion capability of CNFC for MMTs
93
To understand the dispersion capability of CNFC for MMTs in water, three
94
samples with/without a dispersant were prepared. Note that the dispersion capability
95
of CNFC for MMTs is evaluated in terms of the yield of individual MMTs in water
96
and its colloidal stability. Control sample means dispersant-free individual MMT
97
suspension, while CNFC or carboxymethyl cellulose (CMC) was used as a dispersant
98
in the other two samples. Fig. 1a and b show the visual appearance of three prepared 6
99
samples before and after sitting for one week. In comparison to control sample with a
100
yield of 48.5%, both CMC and CNFC have a positive effect on the yield of individual
101
MMTs, showing a higher dispersion yield of 58.1% and 56.3%, respectively. After
102
sitting for 1 week, the yield of control sample decreases from 48.5% to 40.8%.
103
However, for CNFC-dispersed suspension, only a slight change in dispersion yield is
104
observed, decreasing from 56.3% to 54.8%. There is an obvious phase separation for
105
CMC-dispersed suspension due to the aggregate of individual MMTs in water (Fig.
106
1b). CNFC is, therefore, an effective dispersant for the preparation of individual
107
MMT suspension with desired dispersion yield and colloidal stability.
108
Additionally, the effect of the CNFC’s dosages on the colloidal stability of
109
aqueous individual MMT suspensions is quantified by a turbiscan lab analyzer. As the
110
dosage of CNFCs increases from 0 wt % to 50 wt %, the TSI (turbiscan stability index)
111
of aqueous individual MMT suspensions presents a declining tendency, which
112
indicates an increase in colloidal stability (Fig. 1c). Specifically, the CNFC has a
113
negligible effect on the stability of individual MMT suspension when its dosage is 2
114
wt %. An enhanced stability is achieved for aqueous suspensions with CNFC dosages
115
of 6 wt%, 10 wt%, and 15 wt%, but their corresponding TSI-time curves are almost
116
overlapping. When the CNFCs reach 50 wt%, the individual MMT suspension
117
exhibits the best colloidal stability. Interestingly, the growth trend in yields and
118
colloidal stability of aqueous individual MMT suspensions is quite similar with
119
increasing amount of CNFCs (Fig. 1d).
7
120 121
Fig. 1. Visual appearance of aqueous individual MMT dispersions with/without a
122
dispersant (CMC or CNFC) before (a) and after (b) sitting for 1 week. Note that the
123
dosage of CNFC or CMC is approximately 10 wt% (based on raw MMTs), the
124
number in pictures indicates the yield of individual MMT suspensions.
125
CNFC-dispersed individual MMT suspension exhibits better colloidal stability over
126
sample with CMC dispersant and control sample. (c) TSI-time curves and (d) yields
127
of individual MMT suspensions at different dosages (based on raw MMTs) of CNFC
128
dispersant.
129 130
In addition to improving the dispersion yield and colloidal stability, the addition
131
of CNFCs has the ability to protect individual MMT from dramatic fragmentation
132
during ultrasonic treatment. As we can see from the atomic force microscopy (AFM)
133
images in Fig. 2, CNFC-dispersed individual MMTs show a larger size than
134
dispersant-free control sample. The average size of individual MMTs without CNFCs
135
was approximately 85.4 nm measured by particle diameter analysis (Fig. 2a).
136
However, the individual MMTs with 6 wt% and 15 wt% CNFC dispersant exhibit an
137
average size of 181.3 nm (Fig. 2b) and 228.3 nm (Fig. 2c), respectively. The 8
138
improved average size of CNFC-dispersed individual MMTs is primarily ascribed to
139
the effective absorption of ultrasonication power by CNFCs.
140 141
Fig. 2. AFM height images of individual MMTs prepared with different dosage of
142
CNFC. (a) 0 wt%, (b) 6 wt%, and (c) 15 wt%.
143 144
3.2. Interfacial interaction between MMTs and CNFCs
145
To understand the underlying mechanism for the excellent dispersing capacity of
146
CNFCs for individual MMTs, the interfacial interactions between the CNFCs and the
147
individual MMTs were characterized comprehensively by using a QCM-D and an
148
AFM.
149
We initially investigated the affinity between the CNFCs and the individual
150
MMTs. Fig. 3a displays the AFM image of CNFC-dispersed individual MMTs. As we
151
can see from the AFM image that a small part of CNFCs could adsorb on the surface
152
of individual MMTs (yellow circles), and their affinity is further determined by a
153
QCM-D. Fig. 3b shows the adsorption behaviors of CNFC suspensions with different
154
concentrations on MMT film. As the concentration of CNFC dispersion increases 9
155
from 0.1 g/L to 0.75 g/L, an increase in adsorption capacity of CNFC on MMT (from
156
3.33 mg/cm2 to 4.20 mg/cm2) is observed. There is a strong adsorption between the
157
two components and increasing with the concentration of CNFC, indicating that Van
158
der Waals force and hydrogen bonds are stronger than repulsion interaction.
159
The adsorption and desorption behaviors of individual MMTs on CNFC film
160
were also performed by QCM-D analysis to further characterize the affinity between
161
the two components. We can see from Fig. 3c that △F2 (the change in frequency
162
after desorption) is almost equal to 1/2 △ F1 (the change in frequency after
163
adsorption). However, the change in frequency of MMTs adsorbed on CMC is equal
164
to its desorption change (Fig. S1). The difference between the △F1 and the △F2
165
suggests that there are stronger interfacial interactions between the individual MMTs
166
and the CNFCs in water.
167
An AFM was then utilized to investigate the surface morphology and roughness
168
of crystal sensor with an active top thin Au film for QCM-D analysis before and after
169
adsorption. Fig. 3d displays the surface morphology of thin Au film on crystal sensor,
170
with a surface roughness (Rq) of approximately 0.9 nm. After grafting individual
171
MMTs to PDAC-modified Au film, a uniform thin layer of individual MMT film was
172
deposited on the thin Au film (Fig. 3e), showing a Rq of lower than 5 nm over a 5 × 5
173
µm2 scanning area. After a saturation adsorption process using CNFC dispersion as a
174
flowing phase, a dense CNFC film fully covers on the individual MMT film (Fig. 3f).
175
And the dense structure of the CNFCs adsorbed on MMT film is similar to that of the
176
neat CNFC film (Fig. S2), suggesting a thin film of CNFC film was formed on MMT
177
film due to their strong interfacial interaction.
10
178 179
Fig. 3. The characterizations of the affinity between CNFCs and MMTs by QCM-D
180
and AFM analysis. (a) AFM height image of CNFC-dispersed individual MMTs.
181
Yellow circles suggest the adsorption of CNFC on the surface of MMTs. (b)
182
Adsorption behaviors of CNFC suspensions with different concentrations on MMT
183
film. (c) Adsorption and desorption of individual MMT suspension (0.1g/L) on CNFC
184
film. AFM images of (d) bare Au surface on crystal sensor, (e) individual MMT film
185
deposited on PDAC-modified Au surface, and (f) CNFC film adsorbed on the
186
aforementioned individual MMT film.
187 188
The strong adsorption of CNFCs by the individual MMTs in water is primarily
189
due to the hydrogen bonds formed between the hydroxyl groups in CNFC and the
190
negatively charged O atoms in MMT. To verify our hypothesis, QCM-D test and AFM
191
colloidal technique were adopted to investigate the interfacial interactions between the
192
CNFCs and the MMTs in pure water or urea solution.
193
Fig. 4a is a schematic drawing of the AFM measurement instrument including a
194
colloidal sphere probe modified with RSiX3 and CNFCs and a flat SiO2 substrate
195
modified with monolayer MMT surface. Urea is a well-known hydrogen-bond
196
breaker that has the ability to shield the hydrogen bonds between the CNFCs and the 11
197
individual MMTs. Herein, urea (1 mol/L) was added in CNFC suspension to reduce
198
the hydrogen bonds between the CNFCs and the individual MMTs. According to the
199
QCM-D characterization in Fig. 4b, the adsorption capacity of CNFC by individual
200
MMTs in urea solution is much smaller than that of CNFCs by individual MMTs in
201
pure water. In addition, AFM force measurement was applied to measure the
202
hydrogen bonding interaction between the two components. The adhesive force
203
between the CNFCs and the individual MMTs in 1 mol/L urea solution declines from
204
1.21 mN/m to 0.44 mN/m (Fig. 4c).
205
In conclusion, according to QCM-D analysis and AFM force measurements, the
206
hydrogen bonding interactions significantly contribute to the strong adsorption
207
between the individual MMTs and the CNFCs. The adsorption of CNFCs on MMTs
208
increases the electrostatic repulsive forces among individual MMTs, which lays the
209
foundation for obtaining stable colloidal suspensions of individual MMTs in water.
210 211
Fig. 4. (a) Schematic drawing (not to scale) of the colloidal sphere probe covered with
212
bilayer of RSiX3 and CNFCs and the flat MMT surface used for AFM force
213
measurements. (b) Adsorption of CNFCs on MMTs with/without urea. (c) 12
214
Force-distance curves between the CNFCs and the individual MMTs in pure water
215
and 1mol/L urea solution.
216 217
3.3. Dispersive mechanism of CNFCs for individual MMTs in water
218
To the best of our knowledge, the underlying mechanism for stabilizing
219
individual MMTs in water by CNFC dispersant remains ambiguous. Herein AFM
220
force measurement with colloidal probe technique was adopted to explore the
221
interaction mechanism from the molecular perspective [19-23]. Fig. 5a shows the
222
schematic of AFM for the measurement of force/distance (F/D) curves, which
223
includes a colloidal sphere probe first decorated with a thin layer of cationic PDAC,
224
followed by depositing individual MMTs, and an individual MMT modified substrate.
225
Generally, the AFM F/D curve contains trace curve and retrace curve. Fig. 5b is
226
a typical F/D curve between a MMT decorated probe and a MMT modified substrate.
227
In trace process, the total repulsive force increases gradually and then achieves the
228
maximum value when the MMT decorated probe approaches to the MMT modified
229
substrate. Herein we measured the approaching F/D curves in CNFC dispersions.
230
To explore the dispersion mechanism of CNFCs for individual MMTs,the
231
electrostatic and steric repulsions should be analyzed separately and individually.
232
Commonly, if just electrostatic force and van der Waals force exist in the dispersion
233
system,
234
Derjaguin-Landau-Verwey-Overbeek (DLVO) theory ( F(D)ୈ = F(D)ୈ +
235
F(D)ୈ; Where D represents the distance between colloidal probe and measurement
236
substrate, F(D)DLVO denotes DLVO force, F(D)VDW is van der Waals attraction force
237
while F(D)EDL represents electrostatic double layer repulsion force. As shown in Fig.
238
5c, the F/D curve is well agreement with DLVO theory fitting as the probe is
239
approaching the substrate. Nevertheless, a notable derivation between the measured
F/D
curve
could
be
13
well
fitted
by
classic
240
data and the fitting curves appears as the distance between the probe and the substrate
241
is less than 15 nm (Fig. 5c), which is ascribed to steric repulsion that is not considered
242
in DLVO theory.
243
After considering the influence of steric repulsion, the DLVO theory is modified
244
to DLVO-s theory ( F(D)ୈିୗ = F(D)ୈ + F(D)ୈ + F(D)ୗ (where F(D)S
245
represents steric repulsion force), and the DLVO-S fitting curve coincides well to
246
experiment data in the whole range. The individual proportion of electrostatic and
247
steric repulsion is as a function of distance (Fig. 5d). The electrostatic repulsion
248
belongs to long-range force that gradually decreases with the increase of distance
249
between the individual MMTs, while the steric resistance is the dominant repulsion at
250
shorter range, which rapidly decreases with increasing distance.
251 252
Fig. 5. (a) Schematic drawing (not to scale) of the colloidal sphere probe covered with
253
bilayer of PDAC and MMTs and the flat MMT surface used for AFM force
254
measurements in aqueous CNFC. (b) Typical AFM F/D curve between MMT
255
colloidal probe and MMT substrate. (c) F/D curve and corresponding DLVO and
256
DLVO-s fitting curves between the MMTs in 0.3g/L CNFC. (d) Proportion and
257
magnitude of electrostatic and steric repulsions at different distances.
258 14
259
As we presented above, the yield and stability of individual MMT suspension are
260
highly dependent on the dosage of CNFC dispersant. To understand the underlying
261
mechanism, we try to study the surface interactions between the MMTs through
262
measurements of approaching F/D curves in CNFC dispersions with varying
263
concentrations. Fig. 6a indicates the approaching F/D curves measured between the
264
individual MMTs in pure water and CNFC dispersions with different solid contents.
265
In pure water, attractive forces dominate the interfacial interaction between the
266
individual MMTs, which leads to the aggregation of aqueous individual MMT
267
suspensions. With increasing solid contents of CNFC dispersion, the interfacial
268
interactions between the individual MMTs change from attractive force to repulsive
269
force, and the intensity and range of repulsion increase as well.
270
To explain the individual contribution of electrostatic repulsion and steric
271
hindrance on the repulsive force between the individual MMTs in different CNFC
272
dispersions, the approaching F/D curves are fitted by the DLVO and DLVO-s models
273
(Fig. S3). According to the fitting results, several parameters are obtained to directly
274
determine the interaction intensity and range of repulsive forces between the
275
individual MMTs. Debye length and electrostatic interaction constant are for
276
electrostatic repulsion while characteristic length and steric interaction constant are
277
for steric repulsion. The Debye and characteristic lengths indicate the interaction
278
range of electrostatic repulsion and steric hindrance, respectively, while the
279
electrostatic and steric interaction constants relate to the interaction intensity of
280
electrostatic repulsion and steric hindrance, respectively, the larger the interaction
281
constant, the stronger the interaction intensity.
282
As shown in Fig. 6b, the Debye length and interaction constant of electrostatic
283
repulsion increases gradually and finally tends to be stable. The strong adsorption of 15
284
highly negative CNFCs (Fig. S4) on the surface of individual MMTs by hydrogen
285
bonding significantly improves their charge density, thus rendering the increase of
286
both Debye length (interaction length) and electrostatic interaction constant (intensity).
287
As the adsorption capacity of the individual MMTs reaches saturation point, the
288
electrostatic repulsion between the individual MMTs will be stable.
289
However, an obvious different phenomenon is observed for steric hindrance with
290
increasing concentrations of CNFC dispersion. The characteristic length demonstrates
291
an increasing tendency while a declining trend is observed for the steric interaction
292
constant (Fig. 6c). When the concentration of CNFC dispersion is low, the interaction
293
range of repulsive force is limited to the surface of the individual MMTs,but its
294
interaction constant is large due to the dense structure of the adsorption layer. As the
295
concentration of CNFC suspension continues to rise, the thickness of adsorbed CNFC
296
layer grows and more free CNFCs are presented, which lead to larger accessible
297
distance between the individual MMTs that finally renders the increasing interaction
298
range of steric repulsion. Moreover, the dense structure of the adsorbed CNFC layer
299
on the surface of MMTs tends to be loose with the growing thickness of adsorption
300
layer, thus resulting in the decrease of interaction constant of steric repulsion. Despite
301
the decrease of the steric interaction constant with the increasing concentrations of
302
CNFC suspension, the total steric repulsion demonstrates an increasing trend and
303
eventually become a dominant repulsion interaction.
16
304 305
Fig. 6. (a) F/D curves between individual MMTs in CNFC dispersions with varying
306
solid contents. (b) Electrostatic and (c) steric parameters in various CNFC dispersions
307
system.
308 309
In sum, the colloidal stability of individual MMTs suspensions enhances with
310
increasing concentrations of CNFC suspension. The electrostatic repulsion dominates
311
the interfacial interactions between the individual MMTs at long range while the
312
steric hindrance is a predominant factor at short range. As the increase of CNFC
313
concentration, the individual MMT suspension tends to be more stable due to the
314
increase of total repulsion. More significantly, the role of electrostatic repulsion and
315
steric resistance in the colloidal stability of individual MMT suspensions is highly
316
dependent on the concentrations of CNFC suspension. When the CNFCs’
317
concentration reaches 0.1 g/L, the colloidal stability of individual MMTs suspension
318
is mainly due to electrostatic repulsive forces, but the steric hindrance gradually
319
become a predominant repulsion as the concentration increases continuously.
320 17
321
3.4. CNFC-dispersed individual MMTs for nanocomposite films with excellent
322
properties
323
Normally, the addition of individual MMTs into pure CNFC films will inevitably
324
deteriorate their excellent optical and mechanical properties due to the easy
325
aggregation of sheet-like MMTs. However, incorporating CNFC-dispersed individual
326
MMTs into CNFC dispersion could address above challenge and obtain
327
nanocomposite films with optical and mechanical properties comparable to pure
328
CNFC films.
329
Fig. 7a and b shows the optically transparent appearance of nanocomposite films
330
containing 30 wt% individual MMTs obtained by using 0 wt% or 50 wt% CNFC
331
dispersant. Pure CNFC film presents a transmittance of 90.4% at 550 nm and a tensile
332
strength of 128 MPa. However, nanocomposite film demonstrates a decrease in the
333
optical transparency (88.0% at 550 nm) and tensile strength (118 Mpa) when
334
individual MMTs are added (Fig. 7c and d). When individual MMTs with 50 wt %
335
CNFC dispersant were blended with CNFC to prepare nanocomposite film, the
336
resulting nanocomposite film presents a similar transparency (90.3% at 550 nm) and a
337
better tensile strength (143 MPa) compared to pure CNFC films.
338
The reason behind the enhanced transparency is mainly due to the superior
339
colloidal stability of individual MMT suspension using 50 wt% CNFCs as a
340
dispersant that significantly contributes to the formation of ordered structure within
341
film during self-assembly [24-25]. In addition, with increasing CNFC dispersant’s
342
dosage, larger planar size is obtained for individual MMTs, which enables the
343
enhancement in tensile strength.
18
344 345
Fig.7. Visual appearances of nanocomposite films with 30 wt% individual MMTs
346
obtained by using (a) 0 wt% or (b) 50 wt% CNFC dispersant. (c) Total light
347
transmission and (d) tensile strength of pure CNFC film and nanocomposite films
348
with 30 wt% individual MMTs obtained by using 0 wt% or 50 wt% CNFC
349
dispersant .
350 351
4. Conclusions
352
In summary, a comprehensive understanding of the dispersive mechanism of
353
CNFCs for individual MMTs is unveiled by AFM colloidal technique and QCM-D.
354
There is a strong affinity between the two components primarily resulting from the
355
hydrogen bonding interaction, which lays the foundation for preparing stable colloidal
356
suspensions of individual MMTs. Moreover, both the long-range electrostatic
357
repulsion and short-range steric resistance contribute to the colloidal stability of
358
individual MMTs in water and their individual contributions are dependent on the
359
dosage of CNFC dispersant. When the concentration of CNFC dispersant is lower
360
than 2 wt%, the electrostatic repulsion is the dominant interaction for the colloidal
361
stability of individual MMTs. As the CNFC’s dosage continues to increase, the role of
362
steric hindrance in the interfacial interactions grows gradually and eventually
363
becomes a predominant repulsion. Finally, the addition of CNFC-dispersed individual
364
MMTs into pure CNFC film will not deteriorate their optical and mechanical 19
365
properties. When the dosage of CNFC dispersant is 50 wt%, the resulting
366
nanocomposite film with 30 wt% individual MMTs demonstrated a similar
367
transparency (90.3%) at 550 nm and a better strength (143 MPa) compared to pure
368
CNFC film. This work gives a comprehensive insight on the dispersive mechanism of
369
CNFCs for individual MMTs in water and may extend the use of MMTs in numerous
370
value-added fields, such as high-performance nanocomposites and flexible
371
electronics.
372 373
Author information
374
*Corresponding author: [email protected] (Z. Fang), [email protected] (X. Qiu),
375 376
Acknowledge
377
We appreciate the Pearl River S&T Nova Program of Guangzhou (grant no.
378
201806010141), the National Natural Science Foundation of China (grant no.
379
21978103, 31700508), the Natural Science Foundation of Guangdong Province,
380
China (grant no. 2017A030310635), Science and Technology Program of Guangdong
381
Province (grant no. 2017B090903003), and the Foundation (grant no. KF201812) of
382
Key Laboratory of Pulp and Paper Science and Technology of Ministry of
383
Education/Shandong Province of China.
384 385 386 387 388 389 390 391 392 393 394 395 396 397
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