A precise polyrotaxane synthesizer

Mechanically interlocked molecules are likely candidates for the design and synthesis of artificial molecular machines. Although polyrotaxanes have already found niche applications in exotic materials with specialized mechanical properties, efficient synthetic protocols to produce them with precise numbers of rings encircling their polymer dumbbells are still lacking. We report the assembly line-like emergence of poly[n]rotaxanes with increasingly higher energies by harnessing artificial molecular pumps to deliver rings in pairs by cyclical redox-driven processes. This programmable strategy leads to the precise incorporation of two, four, six, eight, and 10 rings carrying 8+, 16+, 24+, 32+, and 40+ charges, respectively, onto hexacationic polymer dumbbells. This strategy depends precisely on the number of redox cycles applied chemically or electrochemically, in both stepwise and one-pot manners.

A precise polyrotaxane synthesizer

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Renewable energy integration and waste heat valorization in aluminum remelting for co-producing kerosene and methanol

Advanced control strategies to exploit the hydropower potential enhancing ancillary services provision to the power system

Green hydrogen production using Shewanella oneidensis MR-1 bioanode and cuprous oxide-based photocathode