Feb 20, 2017 - MA)) is shown to form nanoscale aggregates (NAs) (â¼20 nm) at copolymer concentrations â¥10% w/w, directly from the preformed surfact...
Feb 20, 2017 - Craig James,. â . Jocelyn Peach,. â . Sarah E. Rogers, ...... Giant vesicle formation through self-assembly of complementary random copolymers ...
Feb 20, 2017 - ... to Nanoscale Aggregates with a pH-Responsive Random Copolymer. Jonathan C. Peggâ , Adam Czajkaâ , Christopher Hillâ , Craig Jamesâ , ...
Dec 20, 2016 - ACS Journals. ACS eBooks; C&EN Global Enterprise .... Cameron Volders, Ehsan Monazami, Gopalakrishnan Ramalingam, and Petra Reinke.
An Alternative Route To Electrophilic Substitution. 2. Aromatic Alkylation in the Ion Neutral Complexes Formed Upon Addition of Gaseous Arenium Ions to ...
(b) Fleeman, W. L., Connick, W. B. The Spectrum 2002, 15, 14. [CAS]. (2) . ...... Kukushkin , Matti Haukka , Jo?o J. R. Fra?sto da Silva , Armando J. L. Pombeiro.
Jan 17, 2017 - ... (4-OH), which rapidly isomerizes to a 3,4-dihydro-1,2,4-triazine-based nitrone, ..... for dispersion interactions by Grimme et al.37 as implemented ..... solvent model as implemented in the Gaussian 09 program was applied. ... eige
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Article
An alternative route to nanoscale aggregates with a pH-responsive random copolymer Jonathan C Pegg, Adam Czajka, Christopher Hill, Craig James, Jocelyn Alice Peach, Sarah E. Rogers, and Julian Eastoe Langmuir, Just Accepted Manuscript • DOI: 10.1021/acs.langmuir.6b04559 • Publication Date (Web): 20 Feb 2017 Downloaded from http://pubs.acs.org on February 21, 2017
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An alternative route to nanoscale aggregates with a pH-responsive random copolymer copolymer Jonathan C. Pegg,† Adam Czajka,† Christopher Hill,† Craig James,†,¶ Jocelyn Peach,† Sarah E. Rogers,‡ and Julian Eastoe∗,† †School of Chemistry, University of Bristol, Cantock’s close, Bristol, , BS8 1TS, UK ‡ISIS-STFC, Rutherford Appleton Laboratory, Chilton, Oxon OX11 0QX, UK ¶Current address: Department of Chemistry and CSGI, University of Florence, 50019 Sesto Fiorentino, Firenze, Italy E-mail: [email protected] Phone: +44 (0) 117 928 9180
1
2
Abstract A random copolymer, poly(methyl methacrylate-co-2-dimethylaminoethyl methacry-
3
late) (poly(MMA-co-DMAEMA)) is shown to form nano-scale aggregates (NAs) (∼ 20
4
nm) at copolymer concentrations ≥10 % w/w, directly from the pre-formed surfactant-
5
stabilised latex (∼ 120 nm) in aqueous solution. The copolymer is prepared by a
6
conventional emulsion polymerisation. Introducing a small mole fraction of DMAEMA
7
(∼ 10 %) allows the copolymer hydrophilicity to be adjusted by pH and external tem-
8
perature, generating NAs with tuneable sizes and defined weight-average aggregation
9
number, as observed by dynamic-light scattering (DLS) and small-angle neutron scat-
10
tering (SANS). These NAs are different to the so-called mesoglobular systems, and are
Figure 1: ...“is it really necessary to use true A-B block copolymers for stabilising interfaces and micellar-like aggregates?” Copolymers can be broadly categorised as either block, graft or random type, according to the arrangement of monomers in the polymer backbone. In block copolymers, the monomers are distributed as clearly segregated sections of each monomer. In (perfectly) random copolymers, the monomers are arranged so that the probability of finding a given monomer at any point along the polymer chain is given by its respective mole fraction. ‘Lumpy’ (or ‘blocky’) random copolymers have a microstructure intermediate between block and (perfectly) random, so that the copolymers have a more lumpy monomer distribution. 37
polymers can require costly precursors, and are tedious and time-consuming, involving se-
38
quential controlled polymerisation or post polymerisation steps. On the other hand, random
39
copolymers are much easier to prepare and can be accessed from more conventional free
40
radical polymerisation routes; in some instances these more primitive polymers have been
41
shown to self-assemble, despite their less well-defined structures. 18–28 Hence, random copoly-
42
mers are much more amenable for industrial and commercial applications. For this class
43
of random copolymers it becomes of interest to know if lumpy molecular architectures (see
44
fig. 1) are able to adsorb to interfaces and self-assemble, or whether true A-B architectures
45
are needed.
46
This present work introduces a new random copolymer, poly(methyl methacyrlate-co-
47
2-dimethyl aminoethyl methacylate) (poly(MMA-co-DMAEMA)). The polymer is prepared
48
by a routine aqueous emulsion free-radical polymerisation with only a small molar fraction
49
of DMAEMA (∼ 10%). Poly(DMAEMA) is a polycation that is, along with its copolymers, 3
Characterisation and synthetic considerations of poly(MMA-co-DMAEMA)
Figure 2: 1 H-NMR spectrum of poly(MMA-co-DMAEMA) in D-Chloroform. (Inset) Copolymer molecular structure: repeat units MMA is shwon green and DMAEMA is shown pink. The signals highlighted by the pink (diamond headed) and green arrows correspond to the methylene and methoxy protons from DMAEMA and MMA respectively. The ratio of the these two signals was used to assess the molar ratio of the monomers in the copolymer.
185
Molecular weight characterisations were carried out by GPC (fig. S2, supporting informa-
186
tion); the Mw of the free copolymer was found to be 15.8 kg mol−1 with a molecular weight
187
dispersity (Ð= Mw /Mn ) = 1.88. The relatively broad Ð is a product of the free-radical emul-
188
sion polymerisation. It is important to keep in mind that emulsion polymerisation is a het-
189
erogeneous process, with the polymerisation commencing in the aqueous-continuous phase.
190
In emulsion polymerisation the monomer partitions between three phases: the monomer
191
droplets (the monomer reservoir), the aqueous-continuous phase and the surfactant micelle
192
phase (which will become the particle phase, as the polymerisation continues.) As a re-
193
sult of the water-soluble character of the initiator, oligomeric radicals are produced in the
194
aqueous-continuous phase. The final polymer particles formed originate from the primary
195
oligoradicals which enter the micelle (particle) phase, as they become water insoluble with
196
continuing propagation of polymer chains. 40 For this reason, the aqueous phase can play an 10
are no longer stabilised by surfactant, but rather by hydrophilic DMAEMA-rich regions at
251
the surface of the aggregates, thereby minimising unfavourable water-interactions with the
252
hydrophobic MMA-predominant cores. The sharp transition in size from B to C is therefore
253
consistent with a transition from a swollen latex (the size is mainly related to parameters
254
controlled in the synthesis) to intermolecular (nano)aggregates. The actual size transition
255
in itself is fairly immaterial. The DMAEMA-rich stabilising region is made possible by the
256
lumpy structure of the copolymer and can be loosely termed as a corona, with the caveat that
257
the copolymer is a blocky random copolymer, with broad Ð and heterogeneous incorporation
258
of DMAEMA throughout different polymer chains.
NH
+
NH + NH + NH +
B
A
NH NH+ + + NH+
C
NH NH
pH < 5
+
Temp > 65℃
pH > 5 pH = 2.0 to 4.5 Dh = 19 to 28 nm Dh = 120 nm
pH = 2.0 to 4.5 Dh = 145 to 122 nm
Figure 3: Schematic representation of the route to self-assembled nano-aggregates. (A) Surfactant-stabilised copolymer latex, suspended in aqueous solution, formed by aqueous free-radical copolymerisation. (B) When pH is reduced below 5, the copolymer swells into the aqueous phase. (C) Self-assembled NAs form as the temperature is taken above ∼ 60°C with stirring. The size of NAs is a function of the pH, Dh is the hydrodynamic diameter as measured by DLS.
Figure 4: (Upper) the intensity-weighted particle size distribution of the copolymer latex (blue-dashed trace) and self-assembled aggregates (red trace), both at pH 3.5. (Lower) Corresponding visual appearance of dispersions at 17 % w/w. (Right) swollen surfactantstabilised copolymer latex (state B) strongly scatters light. (Left) Self-assembled nanoaggregates (state C) dispersion weakly scatters light.
259
The transition from state B to C is accompanied by an increase in viscosity, prior to the
260
formation of smaller self-assembled NAs. Poly(DMAEMA) (and its copolymers) is a well
261
known thermoresponsive polymer. 29,30,47 Under basic conditions, poly(DMAEMA) exhibits
262
an inverse temperature solubility. i.e. a lower critical solution temperature (LCST) at 30-
263
50°C. 47 The LCST is strongly dependent upon pH (charge fraction) and ionic strength. 48
264
In acidic conditions the hydrophobic collapse (globular-phase) of polymer chains, associ-
265
ated with the LCST, is inhibited by like-charge repulsion and strong enthalpic interactions 14
Figure 5: Z-average hydrodynamic diameter (Dh ) as a function of pH, for unheated copolymer latex (blue hollow circles) and post-heated assembled-copolymer (red hollow triangles). A critical pH of < 5 is required to form self-assembled nano-aggregates, upon heating to at least 58°C. Error bars are the standard deviations of all data collected, from a minimum of three replicates.
287
On first consideration this pH-response of the copolymer latex appears curious. Poly(DMAEMA)
288
is a weak polybase, with a system dependent pK a , normally reported around 7. 50,51 Although,
289
this can vary with ionic strength and with copolymerisation of a hydrophobic monomers.
290
Cotanda et al. showed that the pK a of poly(DMAEMA-co-MMA) actually increased with
291
higher incorporation of the hydrophobic monomer in the copolymer. 47 This was ascribed
292
to a larger distance between DMAEMA units, in a highly random polymer, facilitating
293
protonation of adjacent amino groups. In the copolymer studied here, the heterogeneous
294
polymerisation results in a lumpy incorporation of DMAEMA monomers. So the proxim-
295
ity of DMAEMA units might make the subsequent protonation of local amine groups more
296
difficult, due to steric hindrance of consecutive protonated units, ultimately decreasing the
297
basicity of the copolymer. Incorporation of a trace amount of MAA into the copolymer,
298
at the expense of DMAEMA, (due to hydrolysis) could also shift the pK a to slightly lower
299
values. (But there is probably too little acrylic acid to make a conceivable difference to the
300
pK a .)
301
In fact, more pertinent is that the DMAEMA groups might be buried in the interior
302
of the copolymer latex at neutral pH. Here, the role of the surfactant stabilising the latex 16
Figure 6: (Upper) Z-average hydrodynamic diameter (Dh ) of self-assembled aggregates (formed at pH 3.5) as a function of pH. (Lower) Zeta potential (ζ) of self-assembled aggregates (formed at pH 3.5) as a function of pH. In both plots, the samples with the pH adjusted at room temperature are blue hollow circles and aggregates formed post-heating are red hollow triangles. The dashed lines represent the respective Dh or ζ of the aggregate at pH 3.5 and are guides for the eye. Error bars are the standard deviations of all data collected, from a minimum of three replicates (DLS) or 5 replicates (electrophoresis). 18
Figure 7: Surface activity (Blue squares, left axis) and the ratio of the intensity (I) of the 1st (373 nm) and 3rd (383 nm) vibration bands, from the fluorescence excitation spectra of pyrene (pink triangles, right axis), both as a function of copolymer concentration, at pH 3.5.
375
From the surface tension-concentration curve it is clear that the copolymer exhibits rea-
376
sonable surface activity, with a minimum surface tension (γ min ) = 45.2 mN m-1 . Up until
377
∼ 0.6 mg mL-1 surface tension decreases gradually, before falling sharply to γ min , represent-
378
ing the saturation of the liquid-air surface. The concentration for γ min and a CAC is in
379
good agreement with the fluorescence results also seen in fig.7. A noticeable surface activ20
a b Table 1: Properties of comparable polymer systems. Dh at pH = 3.5. poly(methacryloxyethyl trimethyl ammonium chloride-co-butyl acrylateacrylamide. 56 c Two breaks are observed in the surface tension plot, which are referred to as the first (0.7 mg mL−1 ) and second (0.4 mg mL−1 ) CAC, respectively. d poly(methyl methacrylate-co2-dimethylaminoethyl methacrylate)(79 mol % DMAEMA,) at pH = 9.5. 57 e poly(butyl acrylate-b-3-acrylamidopropyltrimethylammonium chloride). 58 f poly(allyl alcohol 1,2butoxylate-b-ethoxylate), commercially available from Aldrich. 58
CAC/(mg mL−1 ) γmin /(mN m−1 )
System
Dh /nm
random poly(DMAEMA-co-MMA) −this study poly(MTAC-co-BAAM)
0.7 0.07-0.4
45
23
a
47
not reported
0.5
46
10-27
not reported
50
54
0.2
32
15
b
c
block poly(DMAEMA-b-MMA)
d
poly(BA81 -b-AMPTMA55 ) poly(BO37 -b-EO100 )
e
f
404
NA morphology and aggregation properties
405
Earlier, DLS was used to study the relative size of NAs, without providing detailed internal
406
stuctural information. This is because only an effective diameter can be delineated from
407
DLS. On the other hand, small-angle neutron scattering (SANS) is a useful technique for
408
determining the time-average shape of particles over the colloidal length-scale. 59 In addition
409
to size and shape information (contained within the particle form factor, P(Q)), Mw of
410
aggregates can be approximated, allowing for the weight-average aggregation number of the
411
self-assembled NAs to be estimated.
412
In fig. 8 the SANS profiles for the copolymer latex, post-heating are given, along with
413
fits to the single particle P(Q). At pH 5, the copolymer latex does not undergo a transition
414
to NAs. As such, particles can be seen to scatter to lower-Q (i.e. lower angle) with a higher
415
absolute intensity (since intensity scales with the particle volume squared) in comparison to
416
the smaller NAs. Although not shown in the main text, (fig. S5, supporting information),
417
the copolymer latex can be fit to a spherical P(Q) across all pH values. In fact, this is
418
reassuring that DLS gives an acceptable approximation of the size of the larger copolymer 22
Figure 8: (Upper) SANS profiles of copolymer latex after heating, as a function of pH. (Lower) SANS profiles off-set for clarity, the multiplier, C is given in the legend. The black line, in each case, is the fit to the particle form factor (P(Q)). Table 2: Ellipsoidal P(Q) fit parameters. The dashed line represents the pH threshold for forming self-assembled nano-aggregates. At pH 5 the copolymer latex was fit to a spherical P(Q), so that ra = rb for an equivalent ‘ellipsoid’. Self-assembled aggregates formed at all other pH values were fit to the oblate ellipsoid P(Q), where ra < rb . Representative errors in ra and rb are ± 0.2 nm. Ellipsoid f it parameters pH
Figure 9: SANS profiles of copolymer nano-aggregates at pH 4.5 and pH 2.5, both in the presence of electrolyte and with no electrolyte to screen electrostatic inter-particle interactions. The solid black line is the fit to the nano-aggregate at pH 2.5 with no electrolyte. The fit includes a charged structure factor S(Q) in addition to an ellipsoidal form factor to fit the low-Q data.
462
In this case the low degree of polymerisation of DMAEMA in the copolymer structure
463
is important, together with the lumpy (and not block structure) and the broad Ð of the
464
copolymer. Eisenberg et al. estimated corona layers to be less that 0.3 nm in thickness
465
in poly(styrene-b-acrylic acid) copolymers with similarly low contents of corona forming
466
monomer. 62 The lumpy incorporation of DMAEMA, i.e some MMA groups may interrupt
467
consecutive sequences of DMAEMA units, reducing the propensity to extend into solution.
468
Chains richer in DMAEMA could be more likely to straddle the interface, rather than extend
469
into solution. It is not unreasonable to assume the predominant result of a higher concen-
470
tration of interfacial charge of the NAs results in a compaction of the aggregates since the
471
degree of polymerisation of DMAEMA is low, along with incomplete segregation of the two
472
monomers. In any case, NAs cannot be merely conceptualised as classic polymer micelles.
473
With reducing pH, aggregation number Nagg of the aggregates falls by more than a factor
474
of 2, from 72 to 35. This is consistent with an increase in the amphiphile solubility as more 26
lumpy incorporation of DMAEMA seem to be reasons for the aggregation behaviour, which
501
cannot be simply conceptualised as aggregating like classic polymer micelles. In addition, it
502
is the effective surface charge density of DMAEMA which plays a key role in governing the
503
aggregate morphology. Table 3: Overview of the general properties of poly(MMA-co-DMAEMA) and pH-dependent aggregate properties. a Dispersity (gel-permeation chromatography). b Surface tension at the CAC (surface-tensiometry). c CAC (fluorescence spectroscopy). d Hydrodynamic diameter, (dynamic-light scattering). e Zeta potential, (electrophoresis). f Aspect ratio (rb /ra ) and weight-average aggregation number, Nagg (SANS).
general
504
Mw /(kg mol−1 ) a
Ða
γmin /(mN m−1 ) b
CAC/(mg mL−1 ) c
15.8
1.88
45.2
0.72
(rb /ra ) f
Nagg f
pH
Dh /nm d
4.5
28.6
34.1
3.4
72
4.0
24.6
37.1
3.1
65
3.5
23.1
40.8
2.6
40
3.0
21.2
41.6
2.5
35
2.5
19.7
42.1
2.5
34
ζ/mV
e
Recently random copolymers have been gaining increasing attention in the literature. 27,63,64
505
The clear advantage held by random copolymers over block copolymers, is their comparably
506
straightforward (and usually cheaper) synthesis. Up to now, most of this research has been
507
directed toward replicating the tuneability of block copolymer systems, in an attempt to
508
match the versatility of self-assembled structures. However, in this respect, block copoly-
509
mers are always likely to have the upper hand, since they exhibit predictable control over the
510
resulting morphology of the self-assembled structure by tuning molecular parameters that are
511
controllable in the synthesis, such as the molecular weight, the degree of polymerisation of
512
the blocks and their chemical nature. 16,65,66 Perhaps a better focus of efforts could be directed
513
towards rapid and efficient routes to self-assembled aggregates. (2) typically self-assembled
514
aggregates in aqueous solution of random copolymers are prepared similarly to their block-
515
copolymer counterparts, via the water-induced micellisation method. 16,27 This is neither
516
a time/material efficient or particularly environmentally-friendly process, also requiring the 28
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