We use midinfrared pulses with stable carrier-envelope phase offset to drive molecular vibrations in the charge transfer salt ET−F2TCNQ, a prototypical one-dimensional Mott insulator. We find that the Mott gap, which is probed resonantly with 10 fs laser pulses, oscillates with the pump field. This observation reveals that molecular excitations can coherently perturb the electronic on-site interactions (Hubbard U) by changing the local orbital wave function. The gap oscillates at twice the frequency of the vibrational mode, indicating that the molecular distortions couple quadratically to the local charge density
Competition between electron localization and delocalization in Mott insulators underpins the physic...
Competition between electron localization and delocalization in Mott insulators underpins the physic...
Competition between electron localization and delocalization in Mott insulators underpins the physic...
We use midinfrared pulses with stable carrier-envelope phase offset to drive molecular vibrations in...
We use midinfrared pulses with stable carrier-envelope phase offset to drive molecular vibrations in...
We use midinfrared pulses with stable carrier-envelope phase offset to drive molecular vibrations in...
Optical pulses at THz and mid-infrared frequencies tuned to specific vibrational resonances modulate...
Optical pulses at THz and mid-infrared frequencies tuned to specific vibrational resonances modulate...
Optical pulses at THz and mid-infrared frequencies tuned to specific vibrational resonances modulate...
Optical pulses at THz and mid-infrared frequencies tuned to specific vibrational resonances modulate...
Optical pulses at THz and mid-infrared frequencies tuned to specific vibrational resonances modulate...
Optical pulses at THz and mid-infrared frequencies tuned to specific vibrational resonances modulate...
Competition between electron localization and delocalization in Mott insulators underpins the physic...
Optical pulses at THz and mid-infrared frequencies tuned to specific vibrational resonances modulate...
Competition between electron localization and delocalization in Mott insulators underpins the physic...
Competition between electron localization and delocalization in Mott insulators underpins the physic...
Competition between electron localization and delocalization in Mott insulators underpins the physic...
Competition between electron localization and delocalization in Mott insulators underpins the physic...
We use midinfrared pulses with stable carrier-envelope phase offset to drive molecular vibrations in...
We use midinfrared pulses with stable carrier-envelope phase offset to drive molecular vibrations in...
We use midinfrared pulses with stable carrier-envelope phase offset to drive molecular vibrations in...
Optical pulses at THz and mid-infrared frequencies tuned to specific vibrational resonances modulate...
Optical pulses at THz and mid-infrared frequencies tuned to specific vibrational resonances modulate...
Optical pulses at THz and mid-infrared frequencies tuned to specific vibrational resonances modulate...
Optical pulses at THz and mid-infrared frequencies tuned to specific vibrational resonances modulate...
Optical pulses at THz and mid-infrared frequencies tuned to specific vibrational resonances modulate...
Optical pulses at THz and mid-infrared frequencies tuned to specific vibrational resonances modulate...
Competition between electron localization and delocalization in Mott insulators underpins the physic...
Optical pulses at THz and mid-infrared frequencies tuned to specific vibrational resonances modulate...
Competition between electron localization and delocalization in Mott insulators underpins the physic...
Competition between electron localization and delocalization in Mott insulators underpins the physic...
Competition between electron localization and delocalization in Mott insulators underpins the physic...
Competition between electron localization and delocalization in Mott insulators underpins the physic...