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Main Authors: Bhunia, Soumyadip, Gao, Yueze, Woolley, Jack, Milverton, Ross, Anderson, Harry L, Pandya, Raj
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2602.20401
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author Bhunia, Soumyadip
Gao, Yueze
Woolley, Jack
Milverton, Ross
Anderson, Harry L
Pandya, Raj
author_facet Bhunia, Soumyadip
Gao, Yueze
Woolley, Jack
Milverton, Ross
Anderson, Harry L
Pandya, Raj
contents Carbyne-the one-dimensional sp-hybridised allotrope of carbon-has long been predicted to exhibit unique properties, yet its synthesis remains elusive. To probe its behaviour, finite sp-carbon chains such as cumulenes and polyynes have been studied, but work to date has focused almost exclusively on short, linear systems far from the infinite carbyne limit and without considering topology. Here, we investigate long (48-carbon) linear and cyclic polyynes using steady-state and ultrafast, temperature- and polarization-resolved optical and vibrational spectroscopy. We find highly delocalized ground states in both topologies, with Peierls distortions markedly weaker than in short chains. In contrast, excited states undergo rapid self-localisation, with the localisation pathway and subsequent intersystem crossing strongly dependent on chain length and topology. Unlike shorter polyynes, excited-state structural rearrangements are minimal, and comparison with theoretical predictions shows that properties, such as Huang-Rhys factors, have plateaued by 48 carbons. Our results reveal how topology influences the electronic dynamics of long polyynes and refines our understanding of sp-carbon systems approaching the carbyne limit
format Preprint
id arxiv_https___arxiv_org_abs_2602_20401
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Electronic dynamics in long linear and cyclic polyynes towards the carbyne limit
Bhunia, Soumyadip
Gao, Yueze
Woolley, Jack
Milverton, Ross
Anderson, Harry L
Pandya, Raj
Mesoscale and Nanoscale Physics
Materials Science
Carbyne-the one-dimensional sp-hybridised allotrope of carbon-has long been predicted to exhibit unique properties, yet its synthesis remains elusive. To probe its behaviour, finite sp-carbon chains such as cumulenes and polyynes have been studied, but work to date has focused almost exclusively on short, linear systems far from the infinite carbyne limit and without considering topology. Here, we investigate long (48-carbon) linear and cyclic polyynes using steady-state and ultrafast, temperature- and polarization-resolved optical and vibrational spectroscopy. We find highly delocalized ground states in both topologies, with Peierls distortions markedly weaker than in short chains. In contrast, excited states undergo rapid self-localisation, with the localisation pathway and subsequent intersystem crossing strongly dependent on chain length and topology. Unlike shorter polyynes, excited-state structural rearrangements are minimal, and comparison with theoretical predictions shows that properties, such as Huang-Rhys factors, have plateaued by 48 carbons. Our results reveal how topology influences the electronic dynamics of long polyynes and refines our understanding of sp-carbon systems approaching the carbyne limit
title Electronic dynamics in long linear and cyclic polyynes towards the carbyne limit
topic Mesoscale and Nanoscale Physics
Materials Science
url https://arxiv.org/abs/2602.20401