Experimental Polymer Mechanochemistry and its Interpretational Frameworks

Akbulatov, Sergey; Boulatov, Roman

doi:10.1002/cphc.201601354

Cited by 133 publications

(167 citation statements)

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“…Mechanical force has been known for many decades to break covalent bonds of polymers, causing their degradation. More recently, however, a number of research groups have harnessed the potential of mechanical force towards rationally designed “productive” mechanochemistry, in which chemical reactions of polymers, induced by mechanical force, yield desirable changes in properties or reactivity . In addition to fundamental insights in how force induces unusual chemical reactivity, mechanochemistry is of emerging importance in stimuli‐responsive materials: there are reports of polymers that change color, release acid, show chemiluminescence, or catalyze olefin metathesis reactions due to mechanochemical cleavage of specific chemical bonds …”

Section: Methodsmentioning

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Forcing Ladderenes into Plastic Semiconductors with Mechanochemistry

Thomas

2017

Angew Chem Int Ed

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Section: Methodsmentioning

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Forcing Ladderenes into Plastic Semiconductors with Mechanochemistry

Thomas

2017

Angew Chem Int Ed

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“…Reported extrapolations of force-dependent activation energies from strain free values vary from usefully approximate (estimated accelerations being within af actor of two of the explicitly calculated ones) [17,18] to qualitatively incorrect (e.g.,p redicted inhibition of reactions that are accelerated by force). [5] The known reasonsappear to reflect primarily strong and remarkably complex dependences of both the molecular geometries and reaction mechanisms [19,20] on force.…”

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“…Sonicating dilute polymer solutions is by far the most popular technique to induce polymer mechanochemistry, but such experiments are as challenging to interpret mechanistically or quantitatively as they are easy to do technically. [5] SMFS is the only technique that allows control of the force acting on am acromolecule and remains the only means of measuring force/ratec orrelations. Despite the technical complexity of SMFS, the limited substrate scopea nd the lack of spectroscopic characterization of the products, SMF measurements continue to impact disproportionately the development of polymer mechanochemistry.…”

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“…Yet, the long-term impact of overcoming these challenges seems equally substantial and is likely to extendb eyond polymer science. While we are probably many years away from achieving this goal, partial solutions to an umber of known mechanochemical problems [5,12] are likely to have far-ranging technological andf undamental implications.…”

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The Challenges and Opportunities of Contemporary Polymer Mechanochemistry

Boulatov

2017

ChemPhysChem

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Most polymeric materials are subjectt om echanical loads throughout their lifetimes, from manufacture to recycling. [1][2][3][4][5][6][7] Stretching, compression, twisting or other distortions of the macroscopic shapeo famaterial is accompanied by stretching of individual polymer chains or chain segments. The more ac hain is stretched, the more the kinetica nd thermodynamic stabilities of its constituent monomers changes. This coupling of am echanicall oad, often acting at length scales larger than 1 mm, and chemical reactivity localized within nm 3 volumes, is called mechanochemistry.Incommercial polymers, such as polystyrene or vulcanized rubbers, as ufficiently large load-even ac ompressiveo neleads to fragmentationo fafraction of the polymer chains. This fragmentation lowers the density of bonds across which the load distributes and thust he capacityo ft he material to withstand furtherl oading, ultimately resulting in materialf ailure. Conversely,i tm ay be possible to exploit mechanochemical coupling to design polymeric materials that respondt om echanical loads in ways that prevent or at least inform the user of impeding catastrophicf ailure.T hese responses include selfstrengthening [8] (i.e.,t he formation of multiple load-bearing bonds per each mechanochemically failed bond) and mechanochromism [9] (i.e.,c hanges in local opticalp roperties of the materialp roportional to either instantaneous or accumulated stress at al evel of as ingle polymer chain). The role of mechanochemistry in facilitatingm aterial failure and( potentially)p reventingi te xplains the contemporary interest in the field from materials scientists and engineers. [10] Mechanochemical phenomena are of interest to organic and physicalc hemists thanks to their potentialt oe xpand our understanding of how external variables can affect and control chemicalr eactivity.Acomputationally and conceptually tractable model of localized reactioni nastretched polymer is an isolated reactives ite with tensile force acting between the same pair of atoms that connectt his moiety to the rest of the macrochain. [11][12][13] Consequently,c hemists discuss polymer mechanochemistry in terms of effectso ff orce on reactivitya nd contrasts are often drawn in the literature between force and other experimentalv ariables that affect reaction rates, mecha-nisms and energies, including temperature and (more rarely) pressure, solvento re lectromagnetic fields. An important, if underappreciated, aspect of this view of polymerm echanochemistry is that in it force is not af undamental physicalq uantity, but simply ac onvenienta pproach to making the system tractable by (in the words of Wilczek) "offering approximate, truncated description of the dynamics of matter [that] is easier to use and focuseso nt he relevant" [14] than the alternatives,t hus "shielding us from irrelevant details" (e.g.,a tomicm otions in parts of the macrochain far removed from the reacting site). This approacho fm odeling localized chemical reactivity in complex dynamic systems by representi...

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Stilbenes Revisited: Understanding the Mechanism of Mechanochemical Coupling

O’Neill¹,

Boulatov²

2022

Molecular Photoswitches

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Experimental Polymer Mechanochemistry and its Interpretational Frameworks

Cited by 133 publications

References 214 publications

Forcing Ladderenes into Plastic Semiconductors with Mechanochemistry

Forcing Ladderenes into Plastic Semiconductors with Mechanochemistry

The Challenges and Opportunities of Contemporary Polymer Mechanochemistry

Stilbenes Revisited: Understanding the Mechanism of Mechanochemical Coupling

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