Metal and Proton Relay-Controlled Hierarchical Multistep Switching Cascade

A Reversible Nitroamino-Based Switch Modulates Hydrogen-Bonding Networks in Energetic Materials

The regulation of hydrogen-bonding networks in molecular switches is critical for adaptive materials. However, most of the reported molecular switches are not capable of modulating hydrogen-bonding networks in energetic materials, limiting high-demand applications in explosives. In this work, the first high-energy nitroamino-based molecular switch is reported. It can control the complex hydrogen-bonding systems of energetic materials by reversible cycling for property modulation. Through alkali-acid stimulation, the nitroamino-based switch undergoes dynamic transitions, which reconfigure H-bond networks and separate twin crystals (in x-ray verification). Supported by crystallography and theoretical modeling (e.g., the density of states), this switching mechanism modulates molecular planarity (Δθ > 60°) and optimizes the energy-stability balance, obtaining a compound 6-β with comprehensive properties comparable to classical explosives (e.g., RDX and HMX). By linking hydrogen-bonding engineering and energetic materials science through the nitroamino-based molecular switch, it facilitates superior energetic compounds that can be applied to defense equipment. In addition, our work establishes the nitroamino-based switch as a generalized tool for molecular engineering, bridging dynamic hydrogen-bonding control and self-assembly materials design.

Light-Triggered Reversible Helicity Switching of a Rotor by a Photo-Responsive Plier

Controlling synchronized motion and transmission of molecular motion to a remotely located guest is not trivial. Here, we demonstrate a light-triggered, scissor-like conformational change in a molecular plier to reversibly alter the conformation and helical chirality of a noncovalently bound rotor. The plier comprises three building blocks: an azobenzene unit that controls the open-close motion of the plier upon light-activated isomerization from E to Z, a BINOL unit that serves as both a hinge and a chiral inducer and two pyridine moieties that can form a complex with the rotor guest. The light-induced conformational alteration of the plier was unequivocally demonstrated by 1H NMR, UV-Vis, and CD spectroscopy. The open-close motion of the plier was translated to the rotor via a 1 : 1 host-guest complex. Indeed, CD spectroscopy, NMR spectroscopy, thermal back isomerization studies, and molecular modelling confirm that the light-triggered conformational alterations of the plier can induce mechanical twisting and helicity switching in the rotor.

Abiotic Acyl Transfer Cascades Driven by Aminoacyl Phosphate Esters and Self-Assembly

Biochemical acyl transfer cascades, such as those initiated by the adenylation of carboxylic acids, are central to various biological processes, including protein synthesis and fatty acid metabolism. Designing cascade reactions in aqueous media remains challenging due to the need to control multiple, sequential reactions in a single pot and manage the stability of reactive intermediates. Herein, we developed abiotic cascades using aminoacyl phosphate esters, the synthetic counterparts of biological aminoacyl adenylates, to drive sequential chemical reactions and self-assembly in a single pot. We demonstrated that the structural elements of amino acid side chains (aromatic versus aliphatic) significantly influence the reactivity and half-lives of aminoacyl phosphate esters, ranging from hours to days. This behavior, in turn, affects the number of couplings we can achieve in the network and the self-assembly propensity of activated intermediate structures. The cascades are constructed using bifunctional peptide substrates featuring side chain nucleophiles. Specifically, aromatic amino acids facilitate the formation of transient thioesters, which preorganized into spherical aggregates and further couple into chimeric assemblies composed of esters and thioesters. In contrast, aliphatic amino acids, which lack the ability to form such structures, predominantly undergo hydrolysis, bypassing further transformations after thioester formation. Additionally, in mixtures containing multiple aminoacyl phosphate esters and peptide substrates, we achieved selective product formation by following a distinct pathway that favors subsequent reactions through reactivity changes and self-assembly. By coupling chemical reactions with molecules of varying reactivity time scales, we can drive multiple reaction clocks with distinct lifetimes and self-assembly dynamics, facilitating precise temporal and structural regulation.

Improving Fatigue Resistance and Autonomous Switching of pH Responsive Hydrazones by Pulses of a Chemical Fuel

The chemically triggered reversible switching of pH-responsive hydrazones involves rotary motion-induced configurational changes, serving as a prototype for constructing an array of molecular machines. Typically, the configurational isomerization of such switches into two distinct forms (E/Z) occurs through the alteration of the pH the medium, achieved by successive additions of acid and base stimuli. However, this process results in intermittent operation due to the concomitant accumulation of salt after each cycle, limiting switching performance to only a few cycles (5-6). In this context, we introduce a novel strategy for the autonomous E/Z isomerization of hydrazones in acetonitrile using pulses of trichloroacetic acid as a chemical fuel. The use of this transient acid enabled reversible switching of hydrazones even after 50 cycles without causing significant fatigue. To test the broad viability of the fuel, a series of ortho/para-substituted hydrazones were synthesized and their switching performance was investigated. The analysis of kinetic data showed a strong dependency of switching operations including the lifetime of transient state, on the electronic properties of substituents. Finally, a distinct color change from yellow to orange due to reversible switching of the para-methoxy substituted hydrazone was employed for the creation of rewritable messages on commercially available paper.

Control of Photoisomerization Kinetics via Multistage Switching in Bimetallic Ru(II)-Terpyridine Complexes

In this study, we carried out detailed experimental and theoretical investigation on photophysical, electrochemical, and photoisomerization behaviors of a new array of luminescent binuclear Ru(II) complexes derived from a phenylene-vinylene-substituted terpyridyl ligand possessing RT lifetimes within 60.3-410.5 ns. The complexes experienced trans-to-cis isomerization in MeCN on irradiation with visible light, accompanied by significant changes in their absorption and emission spectral profiles. The reverse cis-to-trans process is also possible with the use of ultraviolet (UV) light. On conversion from trans to cis isomers, the emission intensity increases substantially, while for the reverse process, luminescence quenching occurs. Thus, "off-on" and "on-off" emission switching is facilitated upon treatment with visible and UV light alternatively. By the use of chemical oxidants (ceric ammonium nitrate and potassium permanganate) and reductants (metallic sodium) as well as light of appropriate wavelengths, multistate switching phenomena involving reversible oxidation-reduction and trans-cis isomerization have been achieved. Interestingly, the rate of this multistate photoswitching process becomes much faster compared to only two-state trans-cis isomerization of these complexes. Density functional theory (DFT) and time-dependent-DFT (TD-DFT) calculations are also performed to obtain a clear picture of the electronic environment of the complexes and also for the appropriate assignment of absorption and emission spectral bands.