The team, led by Shigehisa Akine, constructed a triple-helical cobalt metallocryptand designed with flexible ligands that partially seal its internal cavity. This closed-cage architecture forces guest ions to enter and exit at an unusually sluggish pace, transforming a process that is typically instantaneous into a slow-motion sequence. Using nuclear magnetic resonance and circular dichroism spectroscopy, the researchers mapped exactly how the molecule alters its handedness—switching between right-handed and left-handed mirror images—when exposed to specific chemical inputs.
Kanazawa University Researchers Film Molecular Switches in Slow Motion
Molecular switches usually trigger structural changes too quickly for human observation, masking the mechanical steps between states. By engineering a cage-like molecule that reacts over several hours rather than milliseconds, researchers at Kanazawa University have captured a real-time view of how these systems fundamentally operate at the nanoscale.
This experiment resolves a long-standing debate in chemistry regarding how structural transitions occur. Scientists have historically questioned whether these changes follow an induced-fit model, where a guest triggers a change, or a conformational selection model, where the host chooses a pre-existing state. The study confirms that cesium ions drive the switch through conformational selection, binding preferentially to the less abundant left-handed form and shifting the entire population toward that structure. Beyond the discovery, the ability to engineer the response speed of these systems offers a blueprint for developing smarter materials, molecular machines, and advanced information storage devices.


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