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State Localization and Selective Charge Filtering Near a Null Point

Chemical Physics 2026-05-12 v1

Abstract

Null points in synthetically tunable molecular aggregates are predicted to generate flat energy bands analogous to those known in strongly correlated condensed-matter physics. For chemistry, null points provide a powerful design principle for photovoltaic materials with selective charge filtering similar to photosynthesis. However, null points have never been experimentally verified because their defining prediction - state localization with selective electron or hole transfer - has remained unobserved. Here, using a donor-acceptor dyad as a minimal model, we provide the first experimental observation of a null point. Impulsive pump-probe measurements reveal charge separation through a near-instantaneously generated locally excited-charge transfer (LE-CT) intermediate that emerges upon solvent stabilization of CT states. Polarization anisotropy directly reveals state localization and selective charge-filtering, spanning balanced electron-hole transfer to selective hole filtering consistent with synthetic design. A generalized vibronic theory of null points explains these observations and identifies the ideal synthetic parameters for achieving null points which are protected from the vibrational bath.

Keywords

Cite

@article{arxiv.2605.10838,
  title  = {State Localization and Selective Charge Filtering Near a Null Point},
  author = {Sanjoy Patra and Jibin Sivanarayan and Vivek N. Bhat and Philip D. Maret and Atandrita Bhattacharyya and Sayan Ghosh and Mahesh Hariharan and Vivek Tiwari},
  journal= {arXiv preprint arXiv:2605.10838},
  year   = {2026}
}

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