Chain Order and Cross-Link Density of Elastomers As Investigated by Proton Multiple-Quantum NMR

Saalwächter, Kay; Herrero, Berta; López–Manchado, Miguel A.

doi:10.1021/ma051238g

Cited by 128 publications

(295 citation statements)

References 60 publications

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“…Note that the proton dipolar reference value needed to convert D ress into S b suffers less from such changes in the model, due to a balance of multiple intra-and inter-group couplings along the backbone. [35] In any way, our qualitative argument is not affected, as the line shape in Figure 4(b) is the only one that does give a good match with the experiment after scaling and broadening. The super-Lorentzian line in Figure 4(d) can by no means describe the experimental data.…”

Section: Order Parameter Distributions and Comparison With Theorymentioning

confidence: 69%

“…[32,33] The corresponding data and results discussed in this paper were published before, and the reader is referred to the respective literature for details. [33,35,46] In short, we used a dedicated MQ pulse sequence of Baum and Pines, which is applied to initial z magnetization twice for equal times t DQ , first for the excitation of mainly DQ coherences, and then their reconversion into final z magnetization that is detected after a final 90 8 pulse. Phase cycling of either the excitation or the reconversion block is used to filter out either the DQ coherences or a reference signal that comprises all signals that do not contribute to DQ coherences.…”

Section: Nmr Spectroscopymentioning

confidence: 99%

“…[33] are summarized in Figure 2 of these curves can be performed by using semi-analytical build-up functions that are reviewed in ref. [32,35] One can either use build-up functions derived on the basis of specific distribution models such as a Gaussian distribution, or a gamma distribution according to Equation (7). A third option is to use a numerical Tikhonov regularization procedure to estimate the distribution without assumptions on the shape.…”

Section: Distributions In Bimodal Model Networkmentioning

confidence: 99%

See 2 more Smart Citations

NMR Reveals Non‐Distributed and Uniform Character of Network Chain Dynamics

Saalwächter

Sommer

2007

Macromol. Rapid Commun.

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Results of different NMR investigations of elastomers are reviewed with respect to their significance for statistical models of rubber elasticity. In contrast to earlier work based on lineshape analysis and relaxometry, results of recent multiple‐quantum experiments indicate that the NMR‐detected dynamic chain order parameter, which reflects the conformational space of individual monomer units at which the signal is detected locally, is a rather narrowly distributed quantity. Constraints to the dynamics and the conformations of a network chain thus act uniformly and appear as a dynamic average over chains of different length and with different end‐to‐end separations. All our findings are in good agreement with large‐scale computer simulations. Anomalies on swelling such as chain desinterspersion at the early stages and the appearance of heterogeneities, are also discussed.magnified image

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Section: Order Parameter Distributions and Comparison With Theorymentioning

confidence: 69%

Section: Nmr Spectroscopymentioning

confidence: 99%

Section: Distributions In Bimodal Model Networkmentioning

confidence: 99%

See 1 more Smart Citation

NMR Reveals Non‐Distributed and Uniform Character of Network Chain Dynamics

Saalwächter

Sommer

2007

Macromol. Rapid Commun.

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“…The magnetic dipole-dipole interaction of the cross-linked natural rubber was eliminated using the FMAS probe, with a rate 420 kHz. [8][9][10][11][12][13][14] The field-gradient FMAS probe enabled the application of various pulse sequences, such as distortionless enhancement by polarization transfer (DEPT), attached proton test (APT) and two-dimensional correlation measurements, to solid-state NMR spectroscopy. Moreover, the fieldgradient FMAS probe enabled the measurement of inverse correlations between 1 H and 13 C to detect the small signals from the small amounts of the cross-linking junctions, that is, the use of techniques such as heteronuclear multiple quantum correlation, heteronuclear single quantum correlation and heteronuclear multiple bond correlation.…”

Section: Introductionmentioning

confidence: 99%

Mechanical properties and cross-linking structure of cross-linked natural rubber

Chaikumpollert

Yamamoto

Suchiva

et al. 2012

Polym J

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Molecular singularity of cross-linked natural rubber was proposed to be a significant cross-linking junction of rubber, on the basis of the assignment of nuclear magnetic resonance (NMR) signals achieved in our previous work. This molecular singularity was observed to have an important role in the most outstanding mechanical properties of the rubber, through the investigation of the relationships between the structure of cross-linking junctions and the mechanical properties of various cross-linked rubbers. The various cross-linked natural rubbers were prepared by conventional vulcanization (CV), efficient vulcanization (EV) and semi-EV (SemiEV) to have nearly identical cross-link densities. These rubbers were analyzed using solid-state NMR spectroscopy. Using 1 H-NMR spectroscopy, the amount of tertiary carbons linking to sulfur in the CV rubber was observed to be the same as those of the EV and SemiEV rubbers. 13 C-NMR spectroscopy revealed that the number of quaternary carbons linking to sulfur in the CV rubber was the largest among the rubbers. The CV rubber exhibited the best mechanical properties; hence, a cross-linking junction of quaternary carbons linked to sulfur was assigned to the molecular singularity.

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“…The caveats and limitations of MQ-NMR-derived distributions have been discussed in detail elsewhere [28,30] and will not be repeated here, except to note that the uncertainly associated with distributions for p greater than 200 (roughly the degree of polym erization at M e ) and less than 10 is relativ ely large. This issue results from a combination of difficulties, including fitting faithfully MQ-NMR data in the plateau region (i.e., long MQ excitation times) and the inability to sufficiently sample at short excitation tim es.…”

Section: Mq-nmr Derived Siloxane Network Structurementioning

confidence: 99%

Molecular weight distributions of irradiated siloxane-based elastomers: A complementary study by statistical modeling and multiple quantum nuclear magnetic resonance

Dinh

Mayer

Maiti

et al. 2011

Journal of Applied Physics

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ABSTRACT:The statistical methodology of population balance (PB) has been applied to predict the effects of cross-linking and chain-scissioning induced by ionizing radiation on the distribution of molecular weight between cross-links (MWBC) of a siloxane-based elastomer. Effective molecular weight distributions were extracted from the quantification of residual dipolar couplings by multiple quantum nuclear magnetic resonance (MQ-NMR) measurements and are taken to reflect actual MWBC distributions. The PB methodology is then applied to the unirradiated MWBC distribution and considers both chain-scissioning and the possibility of formation of three types of cross-links: random recombination of scissioned-chain ends (endlinking), random covalent bonds of free radicals on scissioned-chain ends (Y-cross-linking), and formation of random cross-links from free radicals on side groups (H-cross-linking). The qualitative agreement between the statistical modeling approach and NMR data confirms that it is possible to predict trends for the evolution of the distribution of MWBC of polymers under irradiation. The approach described herein can also discern heterogeneities in radiation effects in different structural motifs in the polymer network.--

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Chain Order and Cross-Link Density of Elastomers As Investigated by Proton Multiple-Quantum NMR

Cited by 128 publications

References 60 publications

NMR Reveals Non‐Distributed and Uniform Character of Network Chain Dynamics

NMR Reveals Non‐Distributed and Uniform Character of Network Chain Dynamics

Mechanical properties and cross-linking structure of cross-linked natural rubber

Molecular weight distributions of irradiated siloxane-based elastomers: A complementary study by statistical modeling and multiple quantum nuclear magnetic resonance

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