Difference between revisions of "Polyelectrolyte Multilayers"

Revision as of 13:38, 7 October 2010

What is a Polyelectolyte Multilayer (PEM)?

PEMs are composed of alternating layers of oppositely charged polyelectrolytes (PEs) (synthetic PEs or biomolecules), which are generally built up based on the Layer-by-Layer technique. [1,2] Due to their potential applications as membrane, encapsulation and matrix materials, and for enzymes and proteins in sensor applications, PEMs have stimulated great interests from both academic researchers and industries.[3] See also a PEM website. Despite the large number of experimental works, theoretical and computational studies toward understanding the microscopic structure of PEMs are scarce.[4]

Our Research

In close collaboration with experimental investigations from groups of Prof. von Klitzing and Prof. Hugel, we are currently working to investigate the inner structure and dynamics of a small layer number of PEMs via all-atom (AA) and coarse-grained (CG) simulations. The AA level simulations proved to be consistent with existing experimental data on chain conformation of adsorbed poly(styrene sulfonate)(PSS) in PSS monolayer systems, dielectric permittivity and diffusion constant of water in PSS/PDADMA polyelectrolyte complexes (PDADMA stand for poly(diallyldimethylammonium)).

So far, we are building the PSS/PDADMA bilayers based on the previously obtained PSS monolayers and we are expecting to extract exciting information from these studies. The simulation of a bilayer represents our final goal for atomistic simulations of PMEs so far, due to the high requirement of computer resources.

Due to the limitations of atomistic simulations, further insight into structure and dynamics of PEMs can be achieved only with simulations at CG level. Qualitative understanding and agreement with experiments has been obtained by us using the already existing generic bead-spring PE model. However, a refined CG PE model is needed in order to be quantitatively predictive. This is part of our next working program.

Some selected results obtained during the last 2.5 years are:

a) Bilayer thermodynamical instability

Our CG level simulations have shown that depending on the relative strength of the monomer-monomer and monomer-surface interaction energies, a progressive redissolution of the first bilayer or a partial dewetting resulting in a disordered melt can happen.

We have shown that a fast enough deposition of the third layer -- before the aging process -- can prevent such redissolution or partial dewetting and provide the stability needed to form a PEM. We have checked that the deposition of further layers is a stable process. This suggests that the first PE bilayer is not thermodynamically stable, while tri-layers and higher layers are stable, at least within the long run time of our simulations.

b) Charge compensation mechanism

In our AA level simulations on PSS/PDADMA complexes, intrinsic (polyanions pair with polycations) and extrinsic (polyions pair with salt ions) charge compensation mechanisms have been found to co-exist, although the intrinsic one is predominant in the investigated salt (NaCl) concentration range from 0.17 to 1.00 mol/L.

Furthermore, the relative scale of the interaction energy of the ion-pairs in such PSS/PDADMA mixture is calculated to follow (in kJ/mol): Na-Cl (-520) > PSS-Na (-420) > PDADMA-Cl (-280) ~ PSS-PDADMA (-270). The relative scale of the interaction energy can be very useful to explain some experimental finding [5], where PSS is found to be in a higher concentration than PDADMA in PSS/ PDADMA complexes. This information is also valuable to properly model the interactions between ion-pairs in the upcoming, refined, CG model.

c) PSS adsorption monolayer

The PSS monolayer is diposited from a PSS solution via atomistic simulations. Our results demonstrate that short-range interactions originating from the adsorbing substrate play a significant role in the layer structure of the adsorbed PSS, and they alone are already sufficient to induce a stable PSS adsorption layer. The PSS chains are found to behave as hydrophilic PEs, two kinds of conformations of which are observed: flat PSS adsorption layer dominates with some adsorbed PSS chains dangling into the above PSS solution.

d) PE chain pulling experiment

The present, non-refined CG model yields a qualitative agreement with the experiments by the Hugel group. This makes us confident that maybe even a quantitative comparison might be obtainable once the refined coarse-grained model will be ready.

A PE chain, which is similar to the PE chains of the capping layer, is introduced with the corresponding counterions. The averaged force that is needed to keep one of the chain ends fixed at a given point $Z_{tip}$ is measured by performing several independent runs. The position of the chain tip is slowly increased to a new value where a new measurement was performed.

Scientists

Publications

René Messina, Christian Holm, Kurt Kremer.
Polyelectrolyte Multilayering in Spherical Geometry.
Langmuir 19:4473–4482, 2003.
[PDF] (963 KB) [Preprint]
René Messina, Christian Holm, Kurt Kremer.
Polyelectrolyte Adsorption and Multilayering on Charged Colloidal particles.
Journal of Polymer Science, Part B: Polymer Physics 42:3557, 2004.
[PDF] (620 KB) [DOI]
Juan J. Cerdà, Baofu Qiao, Christian Holm.
Understanding polyelectrolyte multilayers: an open challenge for simulations.
Soft Matter 5:4412–4425, 2009.
[PDF] (1.7 MB) [DOI]
Juan J. Cerdà, Baofu Qiao, Christian Holm.
Modeling strategies for polyelectrolyte multilayers.
European Journal of Physics Special Topics 177(1):129–148, 2009.
[PDF] (971 KB) [DOI]
Baofu Qiao, Juan J. Cerdà, Christian Holm.
Poly(styrenesulfonate)-Poly(diallyldimethylammonium) Mixtures: Toward the Understanding of Polyelectrolyte Complexes and Multilayers via Atomistic Simulations.
Macromolecules 43(18):7828–7838, 2010.
[PDF] (2.3 MB) [DOI]

References

[1] J. Schmitt, G. Decher and G. Hong. Thin Solid Films, 1992, 210/211, 831.URL

[2] G. Decher, Science,1997, 277, 1232. URL

[3] J. B. Schlenoff, Langmuir, 2009, 25, 14007.URL

[4] A. V. Dobrynin. Curr. Opin. Colloid Interface Sci, 2008, 13, 376.URL

[5] H. H. Hariri, and J. B. Schlenoff, Macromolecules, 2010, DOI: 10.1021/ma1012978. URL

Polyelectrolyte Multilayers page update On Oct. 08 2010.

@@ Line 1: / Line 1: @@
 __NOTOC__
 == What is a Polyelectolyte Multilayer (PEM)? ==
-PEMs are composed of alternating layers of oppositely charged polyelectrolytes (PEs) (synthetic PEs or biomolecules), which are generally built up based on the Layer-by-Layer technique. [1,2] Due to their potential applications, e.g., membrane,
+PEMs are composed of '''alternating layers of oppositely charged polyelectrolytes''' (PEs) (synthetic PEs or biomolecules), which are generally built up based on the Layer-by-Layer technique. [1,2] Due to their potential applications as membrane, encapsulation and matrix materials, and for enzymes and proteins in sensor applications, PEMs have stimulated great interests from both academic researchers and industries.[3] See also a [http://www.chem.fsu.edu/multilayers/ PEM website].  Despite the large number of experimental works, '''theoretical and computational studies''' toward understanding the microscopic structure of PEMs '''are scarce'''.[4]
-encapsulation and matrix materials for enzymes and proteins in sensor
-applications, PEMs have stimulated great interests from both academic researchers and
-industries. See the latest review [3] on their applications.
-== Status of the PEM´s research at a glance ==
-Since the pionering work of Decher et al in the 90´s, many scientists have been studying and characterizing the properties of Polyelectrolyte Multilayers. The research done about PEMs has been summarized in a few reviews [9-13].  But, just to mention a few relevant contributions to the field of PEM´s:
-* [[PEM experimental studies]].
-* [[PEM theoretical studies]].
-* [[Numerical simulations about PEM´s]].
-Nonetheless, despite the amount of work done during the last 15 years, the understanding of the multilayer formation process and the knowledge about how slight differences during the growth process are able to strongly modify the properties of the multilayer materials is still in its infancy.  The complex nature of PEMs possesses a challenge when one tries to choose a PEM system for a particular application. Therefore, one must first try to learn more about the fundamental properties of PEMs before it is possible to understand how to use these films for specific applications without a large and exhausting process of trial and error. Doubtless, the understanding of such issues is of paramount importance to improve current building-up methods and devices, tune finely the properties of such materials for specific purposes, and in turn devise new potential applications for such materials. Such knowledge will not be only of benefit for the  Scientific Community but also for industry as well as society due to the huge potentiality of such materials for new devices and applications.
 == Our Research ==
-Our current reserach on Polyelectrolyte Multilayers (PEM´s) is aimed to help to shed light on some still not clearly understood aspects governing multilayer formation and the control of their properties.  At this stage,  numerical  simulations that use the  state-of-the-art algorithms to deal with charged soft matter  offer a very valuable and useful tool in order to elucidate the mechanisms governing multilayering assembly and the properties of PEMs. These numerical simulations can build a bridge between the detailed experimental results and the relatively coarse grained analytical models. Our currents aims in the area of PEM research are:
+[[Image:scheme_PSS-PDADMA.png|100px|right|Schematic representation of PSS and PDADMA.]]
-* Clarify which factors contribute to stabilize multilayer films with special reference to weak polyelectrolytes.
+In close collaboration with experimental investigations from groups of Prof. [http://www.chemie.tu-berlin.de/klitzing/menue/home/ von Klitzing] and Prof. [http://cell.e22.physik.tu-muenchen.de/ Hugel], we are currently working to investigate the inner structure and dynamics of a small layer number of PEMs via '''all-atom''' (AA) and '''coarse-grained''' (CG) simulations. The AA level simulations proved to be '''consistent''' with existing experimental data on '''chain conformation''' of adsorbed poly(styrene sulfonate)[http://en.wikipedia.org/wiki/Sodium_polystyrene_sulfonate (PSS)] in PSS monolayer systems, '''dielectric permittivity''' and '''diffusion constant''' of water in PSS/PDADMA polyelectrolyte complexes (PDADMA stand for poly(diallyldimethylammonium)).
-* Explain the mechanisms and the causes that induce the formation of exponential growing films instead of linear films.
-* Study how the stability and the properties of PEMs, as well as the kinetics of both linear and exponential buildup regimes as a function of the several factors which have been observed to be of relevance in experiments.
-* Study of hollow spherical PEM nanocapsules as drug carriers and chemical nanoreactors.
-* Refine current electrostatic methods in order to allow faster and more detailed simulations of large PEM systems.
-* Investigate, in close collaboration with simultaneous experimental investigations (Specially groups of von Klitzing, T. Hugel, Helm), the inner structure and dynamics of a well defined, but small number of multilayer polymers on various substrates.
-== Scientists ==
+So far, we are building the PSS/PDADMA bilayers based on the previously obtained PSS monolayers and we are expecting to extract exciting information from these studies. The simulation of a bilayer represents our final goal for atomistic simulations of PMEs so far, due to the high requirement of computer resources.
-* ''[[Baofu Qiao]]''
+Due to the limitations of atomistic simulations, further insight into structure and dynamics of PEMs can be achieved only with simulations at CG level. Qualitative understanding and agreement with experiments has been obtained by us using the already existing generic bead-spring PE model. However, a refined CG PE model is needed in order to be quantitatively predictive. This is part of our next working program.
-* ''[[Joan Josep Cerdà]]''
-* ''[[Christian Holm]]''
-== Publications ==
+Some selected results obtained during the last 2.5 years are:
-<bibentry> messina02c, messina03a,cerda09b,cerda09c</bibentry>
-== References ==
+a) '''Bilayer thermodynamical instability'''
-[1] Decher G, Hong JD, and Schmitt J, Thin Solid Films, 210, 831, (1992).
+[[Image:thermodynamic_stability_bilayer_vs_trilayer.png|100px|right|Thermodynamic instability of the bilayer and the stability of the fast deposited tri-layer.]]
-[2] Tran D, and Renneberg R, Biosensors and Bioelectronics, 18, 1491, (2003).
+Our CG level simulations have shown that depending on the relative strength of the monomer-monomer and monomer-surface interaction energies, a '''progressive redissolution''' of the first bilayer or a '''partial dewetting''' resulting in a disordered melt can happen.
-[3] Thierry B, Winnik FM, Merhi Y, and Tabrizian M, J. Am. Chem. Soc., 125, 7494, (2003).
+We have shown that a '''fast enough deposition of the third layer''' -- before the aging process  --  can '''prevent such redissolution or partial dewetting''' and provide the stability
+needed to form a PEM. We have checked that the deposition of further layers is a stable process. This suggests that the first PE bilayer is not thermodynamically stable, while tri-layers and higher layers are stable, at least within the long run time of our simulations.
-[4] Malaismy R, and Bruening M, Langmuir, 21, 10587, (2005)
+b) '''Charge compensation mechanism'''
-[5] Jiang L, Lu F, Chang Q, Liu Y, Liu H, Li Y, et al., Chem. Phys. Chem., 6, 481,(2005).
+[[Image:intrinsic_vs_extrinsic_result_in_PEC.png|100px|right|Possibilities of sulfurs from PSS and nitrogens from PDADMA which are intrinsically and extrinsically charge compensated.]]
-[6] Arsenault AC, Halfyard J, Wang Z, Kitaev V, Ozin GA, et al., Langmuir, 21, 499, (2005).
+In our AA level simulations on PSS/PDADMA complexes, intrinsic (polyanions pair with polycations) and extrinsic (polyions pair with salt ions) charge compensation mechanisms have been found to co-exist, although '''the intrinsic one is predominant''' in the investigated salt (NaCl) concentration range from 0.17 to 1.00 mol/L.
-[7] Kamande MW, Fletcher KA, Lowry M, and Warner IM, J. Sep. Sci., 28, 710, (2005).
+Furthermore, the relative scale of the interaction energy of the ion-pairs in such PSS/PDADMA mixture is calculated to follow (in kJ/mol): Na-Cl (-520) > PSS-Na (-420) > PDADMA-Cl (-280) ~ PSS-PDADMA (-270). The relative scale of the interaction energy can be very useful to explain some experimental finding [5], where PSS is found to
+be in a higher concentration than PDADMA in PSS/ PDADMA complexes. This information is also valuable to properly model the interactions between ion-pairs in the upcoming, refined, CG model.
-[8] Khopade AJ, Arulsudar N, Khopade SA, Hartmann J, Biomacromolecules, 6, 229, (2005).
+c) '''PSS adsorption monolayer'''
+[[Image:PSS_momolayer.png|100px|right|PSS adsorption monolayer]]
-[9] Messina R, Holm C, Kremer K, J. Poly. Sci. B, 42, 3557, (2004). [10] Klitzing RV, Wong JE, Jaeger W, and Steiz R, Current Op. Coll. Interf. Sci., 9, 158,(2004).
+The PSS monolayer is diposited from a PSS solution via atomistic simulations. Our results demonstrate that short-range interactions originating from the adsorbing substrate play a significant role in the layer structure of the adsorbed PSS, and they alone are already sufficient to induce a stable PSS adsorption layer. The PSS chains are found to behave as hydrophilic PEs, two kinds of conformations of which are observed: flat PSS adsorption layer dominates with some adsorbed PSS chains dangling into the above PSS solution.
-[11] Schönhoff M, Current Op. Coll. Interf. Sci., 8, 86, (2003). [12] Hammond PT, Current Op. Coll. Interf. Sci., 4, 430, (2000).
-[13] Decher G, Science, 277, 1232, (1997).
+d) '''PE chain pulling experiment'''
-[14] Kharlampieva E, and Sukhishvili SA, Langmuir, 19, 1235, (2003).
+[[Image:PE_pulling_experiment.png|100px|Results from our CG simulations]]
+[[Image:PE_pulling_experiment_Hugel.png|100px|Exp. data from Hugel's group]]
-[15] Schoeler B, Kumaraswamy G, and Caruso F, Macromolecules, 35, 889, (2002).
+The present, non-refined CG model yields a qualitative agreement with the experiments by the Hugel group. This makes us confident that maybe even a quantitative comparison might be obtainable once the refined coarse-grained model will be ready.
-[16] Kujawa P, Moraille P, Sanchez J, Badia A, Winnik FM, J.Am.Chem.Soc, 127, 9224, (2005) .
+A PE chain, which is similar to the PE chains of the capping layer, is introduced with the corresponding counterions. The averaged force that is needed to keep one of the chain ends fixed at a given point $Z_{tip}$ is measured by performing several independent runs. The position of the chain tip is slowly increased to a new value where a new measurement was performed.
-[17] Salomäki M, Vinokurov IA, Kankare J, Langmuir, 21, 11232, (2005). [18] Guyomard A, Muller G, Glinel K, Macromolecules, 38, 5737, (2005).
-[19] Netz RR, Joanny JF, Macromolecules, 32, 9013, (1999).
+== Scientists ==
-[20] Park SY, Rubner MF, and Mayes AM, Langmuir, 18, 9600, (2002).
+* ''[[Baofu Qiao]]''
+* ''[[Marcello Sega]]''
+* ''[[Christian Holm]]''
-[21] Castlenovo M, and Joanny JF, Langmuir, 16, 7524, (2000).   [22] Messina R, Holm C, Kremer K, Langmuir, 19, (10), 4473, (2003).
+== Publications ==
+<bibentry> messina03a,  messina04b, cerda09b,cerda09c, qiao10a</bibentry>
-[23] D. Kovacevic, S. van~der Burgh, M.A. Cohen-Stuart, Langmuir 18, 5607 (2002).
+== References ==
+[1] J. Schmitt, G. Decher and G. Hong. ''Thin Solid Films'', '''1992''', ''210/211'', 831.[http://www.sciencedirect.com/science/article/B6TW0-47X13HN-47/2/e56caa8317193804cc1863ce3db4a32b URL]
-[24] Patel PA, Jeon J, Mather PT, and Dobrynin AV, Langmuir, 21, 6113, (2005).
+[2] G. Decher, ''Science'','''1997''', ''277'', 1232. [http://www.sciencemag.org/cgi/content/abstract/277/5330/1232 URL]
-[25] Panchagnula V, Jean J, Rusling JF, and Dobrynin AV, Langmuir, 21, 1118, (2005).
+[3] J. B. Schlenoff, ''Langmuir'', '''2009''', ''25'', 14007.[http://pubs.acs.org/doi/abs/10.1021/ja802054k URL]
-[26] Abu-Sharkh B, J. Chem Phys., 123, 114907, (2005).
+[4] A. V. Dobrynin. ''Curr. Opin. Colloid Interface Sci'', '''2008''', ''13'', 376.[http://www.sciencedirect.com/science/article/B6VRY-4S7JFXX-2/2/fd13c66c913bca456ed80d11acd1da39 URL]
+[5] H. H. Hariri, and J. B. Schlenoff, ''Macromolecules'', '''2010''', DOI: 10.1021/ma1012978. [http://dx.doi.org/10.1021/ma1012978 URL]
-'''Polyelectrolyte Multilayers page is under construction ...'''
+'''Polyelectrolyte Multilayers page update On Oct. 08 2010.'''
---[[User:Jcerda|Jcerda]] 20:58, 4 January 2008 (CET)