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1 Methusalem Advisory Board meeting, Ghent, 17 June 2011
2 Methusalem Advisory Board meeting, Ghent, 17 June 2011
NMP: principle and objective
active species dormant species
properties by Nitroxide Mediated Polymerization (NMP) in homogeneous - - PowerPoint PPT Presentation
properties by Nitroxide Mediated Polymerization (NMP) in homogeneous - - PowerPoint PPT Presentation
Methusalem Advisory Board meeting, Ghent, 17 June 2011 Model-based optimization of polystyrene properties by Nitroxide Mediated Polymerization (NMP) in homogeneous and dispersed media Lien Bentein 1 Methusalem Advisory Board meeting, Ghent,
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3 Methusalem Advisory Board meeting, Ghent, 17 June 2011
Bulk NMP: system & kinetic model
initiator (alkoxyamine) monomer
Bulk NMP of styrene initiated by SG1-phenylethyl at 396 K Classical synthesis approach:
initial molar ratio of monomer to initiator equal to targeted chain length at complete conversion TARGETED chain length (TCL) = [styrene]0/[SG1-phenylethyl]0
Kinetic model:
- main reactions (activation, deactivation, propagation, termination)
- side reactions (thermal initiation, (chain) transfer reactions)
- diffusional limitations accounted for (mainly important on termination &
deactivation)
Bentein et al. Macromol. Theory Simul. 2011, 20, 238
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4 Methusalem Advisory Board meeting, Ghent, 17 June 2011
Side reactions
Diels Alder reaction: Monomer assisted homolysis: Formation of 1,2- diphenylcyclobutane: Ene reaction: DIMER
THERMAL INITIATION
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5 Methusalem Advisory Board meeting, Ghent, 17 June 2011
Side reactions
Chain transfer to monomer: Chain transfer to dimer: Transfer from nitroxide to dimer: Transfer from nitroxide to monomer:
(CHAIN) TRANSFER REACTIONS
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6 Methusalem Advisory Board meeting, Ghent, 17 June 2011
Classical synthesis approach: results
TCL(-) TCL(-)
Experimental data from Lutz et al., Macromol. Rapid Commun., 2001, 189
TCL(-)
OBTAINED average chain length = 557 end group functionality = 0.57
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7 Methusalem Advisory Board meeting, Ghent, 17 June 2011
Classical synthesis approach: results (2)
NUMBER CLD MASS CLD
Chain transfer to dimer mainly responsible for loss of control over average chain length, PDIpol and polymer end-group functionality TCL=960
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8 Methusalem Advisory Board meeting, Ghent, 17 June 2011
Classical synthesis approach: results (3)
OBTAINED average chain length (-) CONVERSION = 0.85
TCL= 1000
Non-classical synthesis (fed-batch) approach ?
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9 Methusalem Advisory Board meeting, Ghent, 17 June 2011
Case I: predetermined amount of M added (1)
15 % improvement OBTAINED average CL polymer end group functionality PDIpol 794 0.39 1.65 800 0.54 1.46
nstyrene= 8.74 10-2 mol
TCL 2000
initial TCL = 500 nstyrene= 8.74 10-2 mol
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10 Methusalem Advisory Board meeting, Ghent, 17 June 2011
Case I: predetermined amount of M added (2)
REACTION PROBABILITY FOR MACRORADICALS (RPi
bulk)
Ri +M
PROPAGATION CHAIN TRANSFER TO MONOMER CHAIN TRANSFER TO DIMER DEACTIVATION TERMINATION BY RECOMBINATION WITH MACRORADICAL
+X +M +D
TERMINATION BY RECOMBINATION WITH INITIATOR RADICAL
+Rj +R0
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11 Methusalem Advisory Board meeting, Ghent, 17 June 2011
Case I: predetermined amount of M added (3)
PROPAGATION CHAIN TRF TO DIMER TERMINATION (RECOMB) DEACTIVATION
REPEATED TEMPORARY SUPPRESSION OF CHAIN TRF TO DIMER
REACTION PROBABILITY FOR MACRORADICALS (RPi
bulk)
RPi
bulk,propagation (-)
RPi
bulk,chain TRF to D (-)
RPi
bulk,termination by recomb(-)
RPi
bulk,deactivation(-)
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12 Methusalem Advisory Board meeting, Ghent, 17 June 2011
Case I: predetermined amount of M added (4)
IMPROVEMENT OBTAINED average chain length (-)
MULTIPLE ADDITION of predetermined amount
CONVERSION = 0.85
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13 Methusalem Advisory Board meeting, Ghent, 17 June 2011
Case II: criterion based amount of M added (1)
OBTAINED average CL polymer end group functionality PDIpol 1042 0.19 1.90 1594 0.62 1.37 >43 % improve- ment
initial TCL = 100
TCL 5000
after each addition: [styrene]/[alkoxyamine] = 100
no classical equivalent
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14 Methusalem Advisory Board meeting, Ghent, 17 June 2011
Case II: criterion based amount of M added (2)
PROPAGATION CHAIN TRF TO DIMER TERMINATION (RECOMB) DEACTIVATION
EFFECTIVE SUPPRESSION OF CHAIN TRF TO DIMER AND TERMINATION
REACTION PROBABILITY FOR MACRORADICALS (RPi
bulk)
RPi
bulk,propagation (-)
RPi
bulk,chain TRF to D (-)
RPi
bulk,termination by recomb(-)
RPi
bulk,deactivation(-)
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15 Methusalem Advisory Board meeting, Ghent, 17 June 2011
Case II: criterion based amount of M added (3)
IMPROVEMENT OBTAINED average chain length (-)
MULTIPLE ADDITION of criterion based amount MULTIPLE ADDITION of predetermined amount
CONVERSION = 0.85
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16 Methusalem Advisory Board meeting, Ghent, 17 June 2011
Fed-batch NMP of styrene
Theoretically, polymer properties can be improved for average chain lengths higher than 500 by a fed-batch approach But will the approach really work in practice? …the experiments are currently being performed in collaboration with the Polymer Chemistry Research Group…
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17 Methusalem Advisory Board meeting, Ghent, 17 June 2011
CRP in dispersed systems; miniemulsion?
General
- industrially attractive: excellent heat transfer, ease of mixing and
handling/transporting of the final product
- water-borne systems: more environmentally friendly and economically interesting
- for CRP: emphasis on (mini)emulsion due to the expectation of similar/better
properties than in bulk (inherent compartmentalization of radical species ability to manipulate overall reaction rates and control over polymer properties by adapting the particle size)
CRP in miniemulsion
- alter particle size by amount of added surfactant
- ideally polymerization reactions only inside the particles, in which controlling agent
is present
styrene: radicals from thermal initiation captured by controlling agent
- encapsulation of additives (pigments)
- copolymerization of highly water-insoluble monomers
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18 Methusalem Advisory Board meeting, Ghent, 17 June 2011
‘Ideal’ miniemulsion: concept
emulsifier initiator (alkoxyamine) EMULSIFICATION BEFORE POLYMERIZATION ASSUMPTIONS:
- oil-soluble initiator
- uniform monomer droplet size
- homogeneous initiator concentration
monomer water monomer droplets
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19 Methusalem Advisory Board meeting, Ghent, 17 June 2011
‘Ideal’ miniemulsion: concept
BEFORE POLYMERIZATION ASSUMPTIONS:
- oil-soluble initiator
- uniform monomer droplet size
- homogeneous initiator concentration
POLYMERIZATION ASSUMPTIONS:
- polymerization only in oil phase
- no mass transfer to aqueous phase
- constant particle size
monomer droplets
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20 Methusalem Advisory Board meeting, Ghent, 17 June 2011
‘Ideal’ miniemulsion: modeling approaches for NMP
- Generalized Smith-Ewart equations
- detailed reaction network (thermal initiation through Mayo mechanism, chain
transfer to monomer, to dimer and transfer from nitroxide to dimer)
- distinction between initiator radicals and macroradicals
- diffusional limitations included
up to high conversion
- effect of particle size on overall polymerization rate as well as polymer
properties
In literature: mainly TEMPO/styrene
- Modified Smith-Ewart equations
- intrinsic kinetic model
- often limited to low conversion (Zetterlund: TEMPO/TIPNO)
- no thermal initiation, no compartmentalization of nitroxide, termination by
disproportionation (Charleux: SG1)
- Kinetic Monte Carlo (Tobita)
- intrinsic kinetic model
- focus on the effect of particle size on overall polymerization rate
Our approach: SG1/styrene
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21 Methusalem Advisory Board meeting, Ghent, 17 June 2011
‘Ideal’ miniemulsion: modeling
droplets with i macroradicals, r initiator radicals, j nitroxide radicals
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22 Methusalem Advisory Board meeting, Ghent, 17 June 2011
‘Ideal’ miniemulsion NMP: modeling
Generalized Smith-Ewart equations = NA vp ka,app τ0 (Ni-1,r
j-1 - Ni,r j)
dNi,r
j
dt + NA
- 1 vp
- 1 <kda,app ,0> ( (i+1)(j+1)Ni+1,r
j+1 – (i)(j)Ni,r j)
+ NA
- 1 vp
- 1 <kda0,app ,0>((r+1)(j+1)Ni+1,r
j+1 – (r)(j)Ni,r j)
+ NA vp kthi,app [M][D](Ni,r-2
j – Ni,r j)
+ NA
- 1 vp
- 1 <ktc,app ,0> ((i+2)(i+1)Ni+2,r
j – (i)(i-1)Ni,r j)
+ NA
- 1 vp
- 1 ktc00/2 ((r+2)(r+1)Ni,r+2
j – (r)(r-1)Ni,r j)
+ NA
- 1 vp
- 1 <ktc0,app ,0>((i+1)(r+1)Ni+1,r+1
j – (i)(r)Ni,r j)
+ <ktrM,app ,0>[M]((i+1)Ni+1,r-1
j – (i)Ni,r j)
+ <ktrD,app ,0>[D]((i+1)Ni+1,r-1
j – (i)Ni,r j)
+ kp0 [M]((r+1)Ni-1,r+1
j – (r)Ni,r j)
+ ktrXD[D]((j+1)Ni,r-1
j+1 – (j)Ni,r j)
droplets with i macroradicals, r initiator radicals, j nitroxide radicals i-1 r j-1 i+1 r j+1 i r-1 j-1 i r+1 j+1
+ NA vp ka0,app [R0X] (Ni,r-1
j-1 - Ni,r j)
i+1 r j+1 i-1 r j-1 i r+1 j+1 i r-1 j-1 i r-2 j i r+2 j i+2 r j i-2 r j i r+2 j i r-2 j i+1 r+1 j i-1 r-1 j i+1 r-1 j i-1 r+1 j i-1 r+1 j i+1 r-1 j i r-1 j+1 i r+1 j-1
number of droplets with i, r, j
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23 Methusalem Advisory Board meeting, Ghent, 17 June 2011
‘Ideal’ miniemulsion NMP: modeling
Generalized Smith-Ewart equations
droplets with i macroradicals, r initiator radicals, j nitroxide radicals
“Bulk” concentrations and conversion: continuity equations Average properties: modified moment equations
e.g. total concentration dormant macrospecies
dτ0 dt = <kda,app,0> (NAvp)2 i,j,r (i) (j) Ni,r
j
- <ka,app,0> τ0 Ni,r
j
i,j,r
Avogadro constant droplet volume total number of droplets DEACTIVATION ACTIVATION
Viscosity effects included
Number of droplets with (i,r,j)
Analogous as for normal bulk NMP: Bentein et al. Macromol. Theory Simul. 2011, 20, 238
Ni,r
j
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24 Methusalem Advisory Board meeting, Ghent, 17 June 2011
Polymerization rate regions (dp)
TCL = 300
Miniemulsion NMP of styrene initiated by SG1-PhEt at 396 K
region I region II
acceleration retardation
region III bulk
MAXIMUM acceleration (conversion) conversion
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25 Methusalem Advisory Board meeting, Ghent, 17 June 2011
Control over chain length & livingness (dp)
TCL = 300 Full line = miniemulsion Dotted line = bulk always better worse higher MAX MAX MAX
MAXIMUM in region II
bulk bulk bulk
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26 Methusalem Advisory Board meeting, Ghent, 17 June 2011
Reaction probabilities
TERMINATION BY RECOMBINATION WITH MACRORADICAL
REACTION PROBABILITY FOR MACRORADICALS & INITIATOR RADICALS
Ri +M
PROPAGATION CHAIN TRANSFER TO MONOMER CHAIN TRANSFER TO DIMER DEACTIVATION TERMINATION BY RECOMBINATION WITH MACRORADICAL
+X +M +D
TERMINATION BY RECOMBINATION WITH INITIATOR RADICAL
+Rj +R0 R0 +M
PROPAGATION CHAIN TRANSFER TO MONOMER CHAIN TRANSFER TO DIMER DEACTIVATION
+X +M +D
TERMINATION BY RECOMBINATION WITH INITIATOR RADICAL
+Rj +R0
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27 Methusalem Advisory Board meeting, Ghent, 17 June 2011
Region I: retardation (reaction probabilities)
TCL = 300 region I dp = 15 nm fast decrease [R0X] with conversion lower PDI initiator radicals (exception): macroradicals: segregation of radicals and similar overall importance of chain transfer to dimer: higher livingness confined space effect: lower polymerization rate and positive effect on control over chain length and end-group functionality
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28 Methusalem Advisory Board meeting, Ghent, 17 June 2011
Region I: retardation (particle distribution)
region I dp = 15 nm
inactive particle: 0 macroradicals 0 initiator radicals 0 nitroxide radicals
very low: confirming lower polymerization rate TCL = 300
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29 Methusalem Advisory Board meeting, Ghent, 17 June 2011
Region I: retardation (particle distribution)
region I dp = 15 nm
inactive particle: 0 macroradicals 0 initiator radicals 0 nitroxide radicals
very low: confirming lower polymerization rate
active particle: 0 macroradicals 1 initiator radical 1 nitroxide radical
TCL = 300 1 nitroxide radical in very small volume → high concentration (Tobita: Single Molecule Concentration Effect)
active particle: 1 macroradical 0 initiator radicals 1 nitroxide radical
„living‟ characteristics: confirming good control
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30 Methusalem Advisory Board meeting, Ghent, 17 June 2011
Region II: acceleration (reaction probabilities)
TCL = 300 region II dp = 30 nm better overall suppression of termination and chain transfer to dimer reactions (compared to region I): higher livingness clearly propagation favored: higher polymerization rate, higher initial chain lengths very slow decrease [R0X] with conversion higher PDI
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31 Methusalem Advisory Board meeting, Ghent, 17 June 2011
Region II: acceleration (particle distribution)
TCL = 300 region II dp = 30 nm higher: in agreement with higher polymerization rate
0 macroradicals 0 initiator radicals 0 nitroxide radicals 0 macroradicals 0 initiator radicals 2 nitroxide radicals 0 macroradicals 0 initiator radicals 4 nitroxide radicals
inactive particles
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32 Methusalem Advisory Board meeting, Ghent, 17 June 2011
Region II: acceleration (particle distribution)
TCL = 300 region II dp = 30 nm
1 0 5
higher: in agreement with higher polymerization rate well-balanced amount of nitroxide radicals: good livingness
1 macroradical 0 initiator radicals 1 nitroxide radical 1 macroradical 0 initiator radicals 3 nitroxide radicals
active particles
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33 Methusalem Advisory Board meeting, Ghent, 17 June 2011
Transition region II to region III
TCL = 300 region II → III dp = 70 nm similar rates on average: indicative of transition convergence to “bulk” properties: diminished suppression of termination and chain transfer to dimer lower livingness faster decrease [R0X] with conversion lower PDI
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34 Methusalem Advisory Board meeting, Ghent, 17 June 2011
Transition region (2)
TCL = 300 region II → III dp = 70 nm
inactive particles: 0 macroradicals 0 initiator radicals
more nitroxide radicals: retardation → “bulk” high
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35 Methusalem Advisory Board meeting, Ghent, 17 June 2011
Transition region (2)
TCL = 300 region II → III dp = 70 nm
inactive particles: 0 macroradicals 0 initiator radicals
more nitroxide radicals: retardation → “bulk” high
active particles: 1 macroradical 0 initiator radicals
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36 Methusalem Advisory Board meeting, Ghent, 17 June 2011
Effect of diffusional limitations (dp)
TCL = 300 most pronounced at higher dp (bulk limit) Macroradicals Nitroxide radicals
r i j j r i p R
iN N n
, ,
1
r i j j r i p X
jN N n
, ,
1
Full line = with diff. lim. Dotted line = without diff. lim. region II dp = 30 nm region II → III dp = 70 nm region I dp = 15 nm
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37 Methusalem Advisory Board meeting, Ghent, 17 June 2011
Effect of diffusional limitations (dp)
TCL = 300 most pronounced at higher dp (bulk limit) Macroradicals Nitroxide radicals
r i j j r i p R
iN N n
, ,
1
r i j j r i p X
jN N n
, ,
1
Full line = with diff. lim. Dotted line = without diff. lim. main effect at high conversion region II dp = 30 nm region II → III dp = 70 nm region I dp = 15 nm
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38 Methusalem Advisory Board meeting, Ghent, 17 June 2011
Interplay TCL and dp for miniemulsion characteristics
TCL = 300 TCL = 800 TCL = 2000 higher TCL: more improvement at higher dp higher TCL: maximal acceleration at higher dp higher TCL: more effect at higher dp higher TCL: limited increase PDI conversion = 0.70
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39 Methusalem Advisory Board meeting, Ghent, 17 June 2011
Conclusions
bulk NMP of S (SG1-mediated; 396 K)
- chain transfer to dimer reactions are important for high TCL
- fed-batch approach theoretically proven to improve polymer properties
miniemulsion NMP of S (SG1-mediated; 396 K)
- strong effect of droplet/particle size on polymerization rate and control
- ver polymer properties:
- polymer end-group functionality always higher than in bulk
- maximal acceleration corresponding with maximal end-group
functionality
- improvement of all properties compared to bulkonly for very small
particles
- diffusional limitations are only important for high particle sizes at high
conversion
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40 Methusalem Advisory Board meeting, Ghent, 17 June 2011
Acknowledgements
1.
- L. Bentein acknowledges financial support from a doctoral fellowship
from the Fund for Scientific Research Flanders (FWO). 2. This work was supported by the Interuniversity Attraction Poles Programme - Belgian State - Belgian Science Policy and the Long Term Structural Methusalem Funding by the Flemish Government. The research leading to these results has received funding from the European Community’s Sixth framework Programme (contract nr 011730).
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41 Methusalem Advisory Board meeting, Ghent, 17 June 2011
Glossary
CRP: controlled radical polymerization
Livingness: polymer end-group functionality
NMP: nitroxide mediated polymerization
Targeted chain length (TCL): the chain length that would be obtained by an ideal, controlled polymerization at 100% conversion, i.e., the initial ratio of monomer/initiator
Reaction probability of a molecule: the ratio of the rate of a particular reaction to the rates of all other possible reactions that the molecule can undergo
Segregation effect of radicals: physical segregation of radicals in particles, allowing the suppression of bimolecular termination
Confined space effect: smaller particle/smaller volume leads to increased concentrations and increased rates (in this case: of deactivation)
Single molecule concentration effect: one molecule present in such a small volume that its concentration is higher than the concentration of this species in the equivalent bulk system
Mn
pol: number average molar mass of the polymer