TY - JOUR
T1 - Visualizing Thermally Activated Conical Intersections Governing Non-Radiative Triplet Decay in a Ni(II) Porphyrin-Nanographene Conjugate with Variable Temperature Transient Absorption Spectroscopy
AU - Garcia-Orrit, Saül
AU - Vega-Mayoral, Víctor
AU - Chen, Qiang
AU - Serra, Gianluca
AU - Guizzardi, Michele
AU - Romano, Valentino
AU - Dal Conte, Stefano
AU - Cerullo, Giulio
AU - Di Mario, Lorenzo
AU - Kot, Mordechai
AU - Loi, Maria Antonietta
AU - Narita, Akimitsu
AU - Müllen, Klaus
AU - Tommasini, Matteo
AU - Cabanillas-González, Juan
N1 - Publisher Copyright:
© 2024 American Chemical Society.
PY - 2024/10/7
Y1 - 2024/10/7
N2 - Metalloporphyrins based on open-shell transition metals, such as Ni(II), exhibit typically fast excited-state relaxation. In this work, we shed light into the nonradiative relaxation mechanism in a nanographene-Ni(II) porphyrin conjugate. Variable temperature transient absorption and global fit analysis are combined to produce a picture of the relaxation pathways. At room temperature, photoexcitation of the lowest π-π* transition is followed by vibrational cooling in 1.6 ps, setting a short 20 ps temporal window wherein a small fraction of relaxed singlets radiatively decay to the ground state before intersystem crossing proceeds. Following intersystem crossing, triplets relax rapidly to the ground state (S0) in a few tens of picoseconds. By performing measurements at low temperature, we provide evidence for a competition between two terminal relaxation pathways from the lowest (metal-centered) triplet to the ground state: a slow ground state relaxation process proceeding in time scales beyond 1.6 ns and a faster pathway dictated by a sloped conical intersection, which is thermally accessible at room temperature from the triplet state. The overall triplet decay at a given temperature is dictated by the interplay of these two contributions. This observation bears significance in understanding the underlying fast relaxation processes in Ni-based molecules and related transition metal complexes, opening avenues for potential applications for energy harvesting and optoelectronics.
AB - Metalloporphyrins based on open-shell transition metals, such as Ni(II), exhibit typically fast excited-state relaxation. In this work, we shed light into the nonradiative relaxation mechanism in a nanographene-Ni(II) porphyrin conjugate. Variable temperature transient absorption and global fit analysis are combined to produce a picture of the relaxation pathways. At room temperature, photoexcitation of the lowest π-π* transition is followed by vibrational cooling in 1.6 ps, setting a short 20 ps temporal window wherein a small fraction of relaxed singlets radiatively decay to the ground state before intersystem crossing proceeds. Following intersystem crossing, triplets relax rapidly to the ground state (S0) in a few tens of picoseconds. By performing measurements at low temperature, we provide evidence for a competition between two terminal relaxation pathways from the lowest (metal-centered) triplet to the ground state: a slow ground state relaxation process proceeding in time scales beyond 1.6 ns and a faster pathway dictated by a sloped conical intersection, which is thermally accessible at room temperature from the triplet state. The overall triplet decay at a given temperature is dictated by the interplay of these two contributions. This observation bears significance in understanding the underlying fast relaxation processes in Ni-based molecules and related transition metal complexes, opening avenues for potential applications for energy harvesting and optoelectronics.
UR - http://www.scopus.com/inward/record.url?scp=85206239559&partnerID=8YFLogxK
U2 - 10.1021/acs.jpclett.4c02712
DO - 10.1021/acs.jpclett.4c02712
M3 - Article
C2 - 39374120
AN - SCOPUS:85206239559
SN - 1948-7185
VL - 15
SP - 10366
EP - 10374
JO - JOURNAL OF PHYSICAL CHEMISTRY LETTERS
JF - JOURNAL OF PHYSICAL CHEMISTRY LETTERS
IS - 41
ER -