Publications
DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"DNA double helix, a tiny electromotor." Nature Nanotechnology 18:238-242 (2023).
"A DNA turbine powered by a transmembrane potential across a nanopore." Nature Nanotechnology (2023).
"A DNA turbine powered by a transmembrane potential across a nanopore." Nature Nanotechnology (2023).
"Molecular Determinants of Current Blockade Produced by Peptide Transport Through a Nanopore." ACS Nanosci. Au (2023).
"Molecular Determinants of Current Blockade Produced by Peptide Transport Through a Nanopore." ACS Nanosci. Au (2023).
"A Marcus-Type Inverted Region in the Translocation Kinetics of a Knotted Protein." The Journal of Physical Chemistry Letters:10719-10726 (2023).
"Molecular Determinants of Current Blockade Produced by Peptide Transport Through a Nanopore." ACS Nanosci. Au (2023).
"A Marcus-Type Inverted Region in the Translocation Kinetics of a Knotted Protein." The Journal of Physical Chemistry Letters:10719-10726 (2023).
"A DNA turbine powered by a transmembrane potential across a nanopore." Nature Nanotechnology (2023).
"A DNA turbine powered by a transmembrane potential across a nanopore." Nature Nanotechnology (2023).
"A Marcus-Type Inverted Region in the Translocation Kinetics of a Knotted Protein." The Journal of Physical Chemistry Letters:10719-10726 (2023).
"Molecular Determinants of Current Blockade Produced by Peptide Transport Through a Nanopore." ACS Nanosci. Au (2023).
"Molecular Determinants of Current Blockade Produced by Peptide Transport Through a Nanopore." ACS Nanosci. Au (2023).
"Molecular Determinants of Current Blockade Produced by Peptide Transport Through a Nanopore." ACS Nanosci. Au (2023).
"A Marcus-Type Inverted Region in the Translocation Kinetics of a Knotted Protein." The Journal of Physical Chemistry Letters:10719-10726 (2023).
"A DNA turbine powered by a transmembrane potential across a nanopore." Nature Nanotechnology (2023).
"Molecular Determinants of Current Blockade Produced by Peptide Transport Through a Nanopore." ACS Nanosci. Au (2023).
"A DNA turbine powered by a transmembrane potential across a nanopore." Nature Nanotechnology (2023).
"Molecular Determinants of Current Blockade Produced by Peptide Transport Through a Nanopore." ACS Nanosci. Au (2023).
"A Marcus-Type Inverted Region in the Translocation Kinetics of a Knotted Protein." The Journal of Physical Chemistry Letters:10719-10726 (2023).
"Molecular Determinants of Current Blockade Produced by Peptide Transport Through a Nanopore." ACS Nanosci. Au (2023).
"A Marcus-Type Inverted Region in the Translocation Kinetics of a Knotted Protein." The Journal of Physical Chemistry Letters:10719-10726 (2023).
"Molecular Determinants of Current Blockade Produced by Peptide Transport Through a Nanopore." ACS Nanosci. Au (2023).
"A DNA turbine powered by a transmembrane potential across a nanopore." Nature Nanotechnology (2023).
"A Marcus-Type Inverted Region in the Translocation Kinetics of a Knotted Protein." The Journal of Physical Chemistry Letters:10719-10726 (2023).
"Molecular Determinants of Current Blockade Produced by Peptide Transport Through a Nanopore." ACS Nanosci. Au (2023).
"A DNA turbine powered by a transmembrane potential across a nanopore." Nature Nanotechnology (2023).
"Molecular Determinants of Current Blockade Produced by Peptide Transport Through a Nanopore." ACS Nanosci. Au (2023).
"A DNA turbine powered by a transmembrane potential across a nanopore." Nature Nanotechnology (2023).
"A Marcus-Type Inverted Region in the Translocation Kinetics of a Knotted Protein." The Journal of Physical Chemistry Letters:10719-10726 (2023).
"A DNA turbine powered by a transmembrane potential across a nanopore." Nature Nanotechnology (2023).
"A Marcus-Type Inverted Region in the Translocation Kinetics of a Knotted Protein." The Journal of Physical Chemistry Letters:10719-10726 (2023).
"A DNA turbine powered by a transmembrane potential across a nanopore." Nature Nanotechnology (2023).
"A Marcus-Type Inverted Region in the Translocation Kinetics of a Knotted Protein." The Journal of Physical Chemistry Letters:10719-10726 (2023).
"A DNA turbine powered by a transmembrane potential across a nanopore." Nature Nanotechnology (2023).
"A DNA turbine powered by a transmembrane potential across a nanopore." Nature Nanotechnology (2023).
"A DNA turbine powered by a transmembrane potential across a nanopore." Nature Nanotechnology (2023).
"A DNA turbine powered by a transmembrane potential across a nanopore." Nature Nanotechnology (2023).
"A DNA turbine powered by a transmembrane potential across a nanopore." Nature Nanotechnology (2023).
"A DNA turbine powered by a transmembrane potential across a nanopore." Nature Nanotechnology (2023).
"A Marcus-Type Inverted Region in the Translocation Kinetics of a Knotted Protein." The Journal of Physical Chemistry Letters:10719-10726 (2023).
"A Marcus-Type Inverted Region in the Translocation Kinetics of a Knotted Protein." The Journal of Physical Chemistry Letters:10719-10726 (2023).
"Molecular Determinants of Current Blockade Produced by Peptide Transport Through a Nanopore." ACS Nanosci. Au (2023).
"Molecular Determinants of Current Blockade Produced by Peptide Transport Through a Nanopore." ACS Nanosci. Au (2023).
"A DNA turbine powered by a transmembrane potential across a nanopore." Nature Nanotechnology (2023).
"A DNA turbine powered by a transmembrane potential across a nanopore." Nature Nanotechnology (2023).
"Molecular Determinants of Current Blockade Produced by Peptide Transport Through a Nanopore." ACS Nanosci. Au (2023).
"A DNA turbine powered by a transmembrane potential across a nanopore." Nature Nanotechnology (2023).
"Molecular Determinants of Current Blockade Produced by Peptide Transport Through a Nanopore." ACS Nanosci. Au (2023).
"Molecular Determinants of Current Blockade Produced by Peptide Transport Through a Nanopore." ACS Nanosci. Au (2023).
"A Marcus-Type Inverted Region in the Translocation Kinetics of a Knotted Protein." The Journal of Physical Chemistry Letters:10719-10726 (2023).
"A DNA turbine powered by a transmembrane potential across a nanopore." Nature Nanotechnology (2023).
"A DNA turbine powered by a transmembrane potential across a nanopore." Nature Nanotechnology (2023).
"A Marcus-Type Inverted Region in the Translocation Kinetics of a Knotted Protein." The Journal of Physical Chemistry Letters:10719-10726 (2023).
"A Marcus-Type Inverted Region in the Translocation Kinetics of a Knotted Protein." The Journal of Physical Chemistry Letters:10719-10726 (2023).
"Molecular Determinants of Current Blockade Produced by Peptide Transport Through a Nanopore." ACS Nanosci. Au (2023).
"Molecular Determinants of Current Blockade Produced by Peptide Transport Through a Nanopore." ACS Nanosci. Au (2023).
"Molecular Determinants of Current Blockade Produced by Peptide Transport Through a Nanopore." ACS Nanosci. Au (2023).
"Molecular Determinants of Current Blockade Produced by Peptide Transport Through a Nanopore." ACS Nanosci. Au (2023).
"A DNA turbine powered by a transmembrane potential across a nanopore." Nature Nanotechnology (2023).
"A Marcus-Type Inverted Region in the Translocation Kinetics of a Knotted Protein." The Journal of Physical Chemistry Letters:10719-10726 (2023).
"A DNA turbine powered by a transmembrane potential across a nanopore." Nature Nanotechnology (2023).
"A Marcus-Type Inverted Region in the Translocation Kinetics of a Knotted Protein." The Journal of Physical Chemistry Letters:10719-10726 (2023).
"Molecular Determinants of Current Blockade Produced by Peptide Transport Through a Nanopore." ACS Nanosci. Au (2023).
"A DNA turbine powered by a transmembrane potential across a nanopore." Nature Nanotechnology (2023).
"Molecular Determinants of Current Blockade Produced by Peptide Transport Through a Nanopore." ACS Nanosci. Au (2023).
"A Marcus-Type Inverted Region in the Translocation Kinetics of a Knotted Protein." The Journal of Physical Chemistry Letters:10719-10726 (2023).
"A Marcus-Type Inverted Region in the Translocation Kinetics of a Knotted Protein." The Journal of Physical Chemistry Letters:10719-10726 (2023).
"Molecular Determinants of Current Blockade Produced by Peptide Transport Through a Nanopore." ACS Nanosci. Au (2023).
"A Marcus-Type Inverted Region in the Translocation Kinetics of a Knotted Protein." The Journal of Physical Chemistry Letters:10719-10726 (2023).
"A DNA turbine powered by a transmembrane potential across a nanopore." Nature Nanotechnology (2023).
"Molecular Determinants of Current Blockade Produced by Peptide Transport Through a Nanopore." ACS Nanosci. Au (2023).
"A Marcus-Type Inverted Region in the Translocation Kinetics of a Knotted Protein." The Journal of Physical Chemistry Letters:10719-10726 (2023).
"A DNA turbine powered by a transmembrane potential across a nanopore." Nature Nanotechnology (2023).
"Molecular Determinants of Current Blockade Produced by Peptide Transport Through a Nanopore." ACS Nanosci. Au (2023).
"A Marcus-Type Inverted Region in the Translocation Kinetics of a Knotted Protein." The Journal of Physical Chemistry Letters:10719-10726 (2023).
"A DNA turbine powered by a transmembrane potential across a nanopore." Nature Nanotechnology (2023).
"Molecular Determinants of Current Blockade Produced by Peptide Transport Through a Nanopore." ACS Nanosci. Au (2023).
"Molecular Determinants of Current Blockade Produced by Peptide Transport Through a Nanopore." ACS Nanosci. Au (2023).
"Molecular Determinants of Current Blockade Produced by Peptide Transport Through a Nanopore." ACS Nanosci. Au (2023).
"Molecular Determinants of Current Blockade Produced by Peptide Transport Through a Nanopore." ACS Nanosci. Au (2023).
"A Marcus-Type Inverted Region in the Translocation Kinetics of a Knotted Protein." The Journal of Physical Chemistry Letters:10719-10726 (2023).
"Molecular Determinants of Current Blockade Produced by Peptide Transport Through a Nanopore." ACS Nanosci. Au (2023).
"A DNA turbine powered by a transmembrane potential across a nanopore." Nature Nanotechnology (2023).
"Molecular Determinants of Current Blockade Produced by Peptide Transport Through a Nanopore." ACS Nanosci. Au (2023).
"Molecular Determinants of Current Blockade Produced by Peptide Transport Through a Nanopore." ACS Nanosci. Au (2023).
"A DNA turbine powered by a transmembrane potential across a nanopore." Nature Nanotechnology (2023).
"A DNA turbine powered by a transmembrane potential across a nanopore." Nature Nanotechnology (2023).
"A Marcus-Type Inverted Region in the Translocation Kinetics of a Knotted Protein." The Journal of Physical Chemistry Letters:10719-10726 (2023).
"A DNA turbine powered by a transmembrane potential across a nanopore." Nature Nanotechnology (2023).
"A Marcus-Type Inverted Region in the Translocation Kinetics of a Knotted Protein." The Journal of Physical Chemistry Letters:10719-10726 (2023).
"A Marcus-Type Inverted Region in the Translocation Kinetics of a Knotted Protein." The Journal of Physical Chemistry Letters:10719-10726 (2023).
"Molecular Determinants of Current Blockade Produced by Peptide Transport Through a Nanopore." ACS Nanosci. Au (2023).
"A Marcus-Type Inverted Region in the Translocation Kinetics of a Knotted Protein." The Journal of Physical Chemistry Letters:10719-10726 (2023).
"A Marcus-Type Inverted Region in the Translocation Kinetics of a Knotted Protein." The Journal of Physical Chemistry Letters:10719-10726 (2023).
"A Marcus-Type Inverted Region in the Translocation Kinetics of a Knotted Protein." The Journal of Physical Chemistry Letters:10719-10726 (2023).
"Molecular Determinants of Current Blockade Produced by Peptide Transport Through a Nanopore." ACS Nanosci. Au (2023).
"Molecular Determinants of Current Blockade Produced by Peptide Transport Through a Nanopore." ACS Nanosci. Au (2023).
"A DNA turbine powered by a transmembrane potential across a nanopore." Nature Nanotechnology (2023).
"Molecular Determinants of Current Blockade Produced by Peptide Transport Through a Nanopore." ACS Nanosci. Au (2023).
"A DNA turbine powered by a transmembrane potential across a nanopore." Nature Nanotechnology (2023).
"Molecular Determinants of Current Blockade Produced by Peptide Transport Through a Nanopore." ACS Nanosci. Au (2023).
"A DNA turbine powered by a transmembrane potential across a nanopore." Nature Nanotechnology (2023).
"A Marcus-Type Inverted Region in the Translocation Kinetics of a Knotted Protein." The Journal of Physical Chemistry Letters:10719-10726 (2023).
"A Marcus-Type Inverted Region in the Translocation Kinetics of a Knotted Protein." The Journal of Physical Chemistry Letters:10719-10726 (2023).
"A Marcus-Type Inverted Region in the Translocation Kinetics of a Knotted Protein." The Journal of Physical Chemistry Letters:10719-10726 (2023).
"A Marcus-Type Inverted Region in the Translocation Kinetics of a Knotted Protein." The Journal of Physical Chemistry Letters:10719-10726 (2023).
"A Marcus-Type Inverted Region in the Translocation Kinetics of a Knotted Protein." The Journal of Physical Chemistry Letters:10719-10726 (2023).
"A Marcus-Type Inverted Region in the Translocation Kinetics of a Knotted Protein." The Journal of Physical Chemistry Letters:10719-10726 (2023).
"Molecular Determinants of Current Blockade Produced by Peptide Transport Through a Nanopore." ACS Nanosci. Au (2023).
"A DNA turbine powered by a transmembrane potential across a nanopore." Nature Nanotechnology (2023).
"A DNA turbine powered by a transmembrane potential across a nanopore." Nature Nanotechnology (2023).
"A DNA turbine powered by a transmembrane potential across a nanopore." Nature Nanotechnology (2023).
"A DNA turbine powered by a transmembrane potential across a nanopore." Nature Nanotechnology (2023).
"Molecular Determinants of Current Blockade Produced by Peptide Transport Through a Nanopore." ACS Nanosci. Au (2023).
"A Marcus-Type Inverted Region in the Translocation Kinetics of a Knotted Protein." The Journal of Physical Chemistry Letters:10719-10726 (2023).
"A Marcus-Type Inverted Region in the Translocation Kinetics of a Knotted Protein." The Journal of Physical Chemistry Letters:10719-10726 (2023).
"A DNA turbine powered by a transmembrane potential across a nanopore." Nature Nanotechnology (2023).
"A Marcus-Type Inverted Region in the Translocation Kinetics of a Knotted Protein." The Journal of Physical Chemistry Letters:10719-10726 (2023).
"Molecular Determinants of Current Blockade Produced by Peptide Transport Through a Nanopore." ACS Nanosci. Au (2023).
"Molecular Determinants of Current Blockade Produced by Peptide Transport Through a Nanopore." ACS Nanosci. Au (2023).
"A DNA turbine powered by a transmembrane potential across a nanopore." Nature Nanotechnology (2023).
"Molecular Determinants of Current Blockade Produced by Peptide Transport Through a Nanopore." ACS Nanosci. Au (2023).
"A DNA turbine powered by a transmembrane potential across a nanopore." Nature Nanotechnology (2023).
"Molecular Determinants of Current Blockade Produced by Peptide Transport Through a Nanopore." ACS Nanosci. Au (2023).
"A Marcus-Type Inverted Region in the Translocation Kinetics of a Knotted Protein." The Journal of Physical Chemistry Letters:10719-10726 (2023).
"Molecular Determinants of Current Blockade Produced by Peptide Transport Through a Nanopore." ACS Nanosci. Au (2023).
"Molecular Determinants of Current Blockade Produced by Peptide Transport Through a Nanopore." ACS Nanosci. Au (2023).
"A Marcus-Type Inverted Region in the Translocation Kinetics of a Knotted Protein." The Journal of Physical Chemistry Letters:10719-10726 (2023).
"A DNA turbine powered by a transmembrane potential across a nanopore." Nature Nanotechnology (2023).
"A DNA turbine powered by a transmembrane potential across a nanopore." Nature Nanotechnology (2023).
"A DNA turbine powered by a transmembrane potential across a nanopore." Nature Nanotechnology (2023).
"A Marcus-Type Inverted Region in the Translocation Kinetics of a Knotted Protein." The Journal of Physical Chemistry Letters:10719-10726 (2023).
"A Marcus-Type Inverted Region in the Translocation Kinetics of a Knotted Protein." The Journal of Physical Chemistry Letters:10719-10726 (2023).
"A DNA turbine powered by a transmembrane potential across a nanopore." Nature Nanotechnology (2023).
"Molecular Determinants of Current Blockade Produced by Peptide Transport Through a Nanopore." ACS Nanosci. Au (2023).
"A Marcus-Type Inverted Region in the Translocation Kinetics of a Knotted Protein." The Journal of Physical Chemistry Letters:10719-10726 (2023).
"A DNA turbine powered by a transmembrane potential across a nanopore." Nature Nanotechnology (2023).
"Molecular Determinants of Current Blockade Produced by Peptide Transport Through a Nanopore." ACS Nanosci. Au (2023).
"A Marcus-Type Inverted Region in the Translocation Kinetics of a Knotted Protein." The Journal of Physical Chemistry Letters:10719-10726 (2023).
"A DNA turbine powered by a transmembrane potential across a nanopore." Nature Nanotechnology (2023).
"Molecular Determinants of Current Blockade Produced by Peptide Transport Through a Nanopore." ACS Nanosci. Au (2023).
"A Marcus-Type Inverted Region in the Translocation Kinetics of a Knotted Protein." The Journal of Physical Chemistry Letters:10719-10726 (2023).
"A DNA turbine powered by a transmembrane potential across a nanopore." Nature Nanotechnology (2023).
"A Marcus-Type Inverted Region in the Translocation Kinetics of a Knotted Protein." The Journal of Physical Chemistry Letters:10719-10726 (2023).
"Molecular Determinants of Current Blockade Produced by Peptide Transport Through a Nanopore." ACS Nanosci. Au (2023).
"A Marcus-Type Inverted Region in the Translocation Kinetics of a Knotted Protein." The Journal of Physical Chemistry Letters:10719-10726 (2023).
"Molecular Determinants of Current Blockade Produced by Peptide Transport Through a Nanopore." ACS Nanosci. Au (2023).
"A Marcus-Type Inverted Region in the Translocation Kinetics of a Knotted Protein." The Journal of Physical Chemistry Letters:10719-10726 (2023).
"A DNA turbine powered by a transmembrane potential across a nanopore." Nature Nanotechnology (2023).
"A DNA turbine powered by a transmembrane potential across a nanopore." Nature Nanotechnology (2023).
"A Marcus-Type Inverted Region in the Translocation Kinetics of a Knotted Protein." The Journal of Physical Chemistry Letters:10719-10726 (2023).
"A Marcus-Type Inverted Region in the Translocation Kinetics of a Knotted Protein." The Journal of Physical Chemistry Letters:10719-10726 (2023).
"A Marcus-Type Inverted Region in the Translocation Kinetics of a Knotted Protein." The Journal of Physical Chemistry Letters:10719-10726 (2023).
"Molecular Determinants of Current Blockade Produced by Peptide Transport Through a Nanopore." ACS Nanosci. Au (2023).
"Molecular Determinants of Current Blockade Produced by Peptide Transport Through a Nanopore." ACS Nanosci. Au (2023).
"Molecular Determinants of Current Blockade Produced by Peptide Transport Through a Nanopore." ACS Nanosci. Au (2023).
"A Marcus-Type Inverted Region in the Translocation Kinetics of a Knotted Protein." The Journal of Physical Chemistry Letters:10719-10726 (2023).
"A Marcus-Type Inverted Region in the Translocation Kinetics of a Knotted Protein." The Journal of Physical Chemistry Letters:10719-10726 (2023).
"A DNA turbine powered by a transmembrane potential across a nanopore." Nature Nanotechnology (2023).
"Molecular Determinants of Current Blockade Produced by Peptide Transport Through a Nanopore." ACS Nanosci. Au (2023).
"Molecular Determinants of Current Blockade Produced by Peptide Transport Through a Nanopore." ACS Nanosci. Au (2023).
"Molecular Determinants of Current Blockade Produced by Peptide Transport Through a Nanopore." ACS Nanosci. Au (2023).
"A Marcus-Type Inverted Region in the Translocation Kinetics of a Knotted Protein." The Journal of Physical Chemistry Letters:10719-10726 (2023).
"A Marcus-Type Inverted Region in the Translocation Kinetics of a Knotted Protein." The Journal of Physical Chemistry Letters:10719-10726 (2023).
"Molecular Determinants of Current Blockade Produced by Peptide Transport Through a Nanopore." ACS Nanosci. Au (2023).
"A Marcus-Type Inverted Region in the Translocation Kinetics of a Knotted Protein." The Journal of Physical Chemistry Letters:10719-10726 (2023).
"Molecular Determinants of Current Blockade Produced by Peptide Transport Through a Nanopore." ACS Nanosci. Au (2023).
"A Marcus-Type Inverted Region in the Translocation Kinetics of a Knotted Protein." The Journal of Physical Chemistry Letters:10719-10726 (2023).
"Molecular Determinants of Current Blockade Produced by Peptide Transport Through a Nanopore." ACS Nanosci. Au (2023).
"Molecular Determinants of Current Blockade Produced by Peptide Transport Through a Nanopore." ACS Nanosci. Au (2023).
"A Marcus-Type Inverted Region in the Translocation Kinetics of a Knotted Protein." The Journal of Physical Chemistry Letters:10719-10726 (2023).
"A DNA turbine powered by a transmembrane potential across a nanopore." Nature Nanotechnology (2023).
"Molecular Determinants of Current Blockade Produced by Peptide Transport Through a Nanopore." ACS Nanosci. Au (2023).
"A DNA turbine powered by a transmembrane potential across a nanopore." Nature Nanotechnology (2023).
"Molecular Determinants of Current Blockade Produced by Peptide Transport Through a Nanopore." ACS Nanosci. Au (2023).
"A Marcus-Type Inverted Region in the Translocation Kinetics of a Knotted Protein." The Journal of Physical Chemistry Letters:10719-10726 (2023).
"A Marcus-Type Inverted Region in the Translocation Kinetics of a Knotted Protein." The Journal of Physical Chemistry Letters:10719-10726 (2023).
"A DNA turbine powered by a transmembrane potential across a nanopore." Nature Nanotechnology (2023).
"A Marcus-Type Inverted Region in the Translocation Kinetics of a Knotted Protein." The Journal of Physical Chemistry Letters:10719-10726 (2023).
"Molecular Determinants of Current Blockade Produced by Peptide Transport Through a Nanopore." ACS Nanosci. Au (2023).
"A Marcus-Type Inverted Region in the Translocation Kinetics of a Knotted Protein." The Journal of Physical Chemistry Letters:10719-10726 (2023).
"A DNA turbine powered by a transmembrane potential across a nanopore." Nature Nanotechnology (2023).
"A DNA turbine powered by a transmembrane potential across a nanopore." Nature Nanotechnology (2023).
"A Marcus-Type Inverted Region in the Translocation Kinetics of a Knotted Protein." The Journal of Physical Chemistry Letters:10719-10726 (2023).
"A Marcus-Type Inverted Region in the Translocation Kinetics of a Knotted Protein." The Journal of Physical Chemistry Letters:10719-10726 (2023).
"A Marcus-Type Inverted Region in the Translocation Kinetics of a Knotted Protein." The Journal of Physical Chemistry Letters:10719-10726 (2023).
"A DNA turbine powered by a transmembrane potential across a nanopore." Nature Nanotechnology (2023).
"A Marcus-Type Inverted Region in the Translocation Kinetics of a Knotted Protein." The Journal of Physical Chemistry Letters:10719-10726 (2023).
"