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Main Authors: Patra, Sanjoy, Sivanarayan, Jibin, Bhat, Vivek N., Maret, Philip D., Bhattacharyya, Atandrita, Ghosh, Sayan, Hariharan, Mahesh, Tiwari, Vivek
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2605.10838
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author Patra, Sanjoy
Sivanarayan, Jibin
Bhat, Vivek N.
Maret, Philip D.
Bhattacharyya, Atandrita
Ghosh, Sayan
Hariharan, Mahesh
Tiwari, Vivek
author_facet Patra, Sanjoy
Sivanarayan, Jibin
Bhat, Vivek N.
Maret, Philip D.
Bhattacharyya, Atandrita
Ghosh, Sayan
Hariharan, Mahesh
Tiwari, Vivek
contents 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.
format Preprint
id arxiv_https___arxiv_org_abs_2605_10838
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle State Localization and Selective Charge Filtering Near a Null Point
Patra, Sanjoy
Sivanarayan, Jibin
Bhat, Vivek N.
Maret, Philip D.
Bhattacharyya, Atandrita
Ghosh, Sayan
Hariharan, Mahesh
Tiwari, Vivek
Chemical Physics
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.
title State Localization and Selective Charge Filtering Near a Null Point
topic Chemical Physics
url https://arxiv.org/abs/2605.10838