Simple Phenazine‐Based Compounds Realizing Superior Multicolored Emission

Abstract: are commonly found in Cu [3][4][5][6] and noble metal (e.g., Ir, Pt) complexes. [7][8][9][10][11][12] Comparing with fluorescence materials, the predominant advantage of phosphorescence materials is their internal quantum efficiency that can approach 100%. [13][14][15] However, high cost is a barrier which cannot be circumvented for commercial manufacture. Besides above two categories of materials, pure organic molecules, for instance, thermally activated delayed fluorescence (TADF) materials, are regarded as … Show more

“…For the synthesis procedures please refer to the previous work 14 and supporting information. On the one hand, we previously found that the oscillator strength of S 1 approaches zero if the dihedral angle is vertical, which means S 1 may no longer be an ideal emissive state.…”

“…Kasha's rule 1 is extensively observed in luminescence fields, [2][3][4] such as in fluorescent molecular rotors, 3,5-8 bioimaging [9][10][11][12][13] and organic light-emitting diodes (OLEDs), [14][15][16][17] in which the excitons return to the ground state from the lowest singlet S 1 (for phosphorescence this process occurs from T 1 ). To date, most organic luminescent materials follow this rule and their photophysical properties can be precisely simulated using quantum chemical calculations.…”

“…18,19,22,[26][27][28][29][30][31][32][33] Additionally, almost all studies focus on the transition from low to high excited states rather than the other way around, which cannot dialectically expose the nature of Kasha's rule. [5][6][7][8][9]20,21,[23][24][25]34 In a previous work, we reported a series of phenazine-based compounds 14 to explore the connection between the electronic configuration of the excited state and the molecular configuration. The results show that the emission of phenazine-based compounds could undergo a bathochromic-shift with the increase of electron-donating ability of the donor.…”

“…In a previous work, we reported a series of phenazine-based compounds 14 to explore the connection between the electronic configuration of the excited state and the molecular configuration. The results show that the emission of phenazine-based compounds could undergo a bathochromic-shift with the increase of electron-donating ability of the donor.…”

Suppression and utilization of Kasha's rule: realizing the transformation from blue to near-infrared emission

“…For the synthesis procedures please refer to the previous work 14 and supporting information. On the one hand, we previously found that the oscillator strength of S 1 approaches zero if the dihedral angle is vertical, which means S 1 may no longer be an ideal emissive state.…”

“…Kasha's rule 1 is extensively observed in luminescence fields, [2][3][4] such as in fluorescent molecular rotors, 3,5-8 bioimaging [9][10][11][12][13] and organic light-emitting diodes (OLEDs), [14][15][16][17] in which the excitons return to the ground state from the lowest singlet S 1 (for phosphorescence this process occurs from T 1 ). To date, most organic luminescent materials follow this rule and their photophysical properties can be precisely simulated using quantum chemical calculations.…”

“…18,19,22,[26][27][28][29][30][31][32][33] Additionally, almost all studies focus on the transition from low to high excited states rather than the other way around, which cannot dialectically expose the nature of Kasha's rule. [5][6][7][8][9]20,21,[23][24][25]34 In a previous work, we reported a series of phenazine-based compounds 14 to explore the connection between the electronic configuration of the excited state and the molecular configuration. The results show that the emission of phenazine-based compounds could undergo a bathochromic-shift with the increase of electron-donating ability of the donor.…”

“…In a previous work, we reported a series of phenazine-based compounds 14 to explore the connection between the electronic configuration of the excited state and the molecular configuration. The results show that the emission of phenazine-based compounds could undergo a bathochromic-shift with the increase of electron-donating ability of the donor.…”

Suppression and utilization of Kasha's rule: realizing the transformation from blue to near-infrared emission

“…Generally, the host materials with carbazole units exhibit high energy level, conforming to the design strategy for blue or deep blue emitters. 23 However, when the acceptor unit is connected with stronger electron-donating donors, the compounds will undergo a serious red-shift due to the intramolecular charge transfer (ICT) effect, 24 which is unfavorable for the design of deep blue D–A type TADF materials. Therefore, introducing host materials with weak electron-donating ability into molecules is effective to limit the red-shift of deep blue TADF emitters.…”

New strategy for developing deep blue TADF materials with narrow emission and CIE_y < 0.06 employing host materials as donors

Near‐infrared Piezochromic Materials at High Pressure