Förster energy transfer mechanism and color tunability in three binary conjugated polymer blends

“…The nonradiative energy transfer depends on the overlap between the wave functions of the excited states of the donor and the acceptor, and therefore, it is directly related to the value of R DA . From the absorption, PL, PLQY measurements, and information about the measurement parameters, it is possible to calculate R 0 using the following equation: ,,, R 0 = 0.2108 true[ κ 2 normalΦ normalD 0 n − 4 ∫ 0 ∞ F normalD ( λ ) ε normalA ( λ ) λ 4 nobreak0em0.25em⁡ normald λ true] 1 / 6 where κ 2 is the orientation factor, Φ D 0 is the donor PLQY, n is the refraction index of the solvent, F D is the normalized spectral distribution of the donor emission, λ is the photon wavelength and ε A is the molar extinction coefficient of the acceptor. The constants used to calculate the Förster radius were: κ 2 = 2/3 , and n = 1.40496. , The PLQY was measured in solution using an integrating sphere, and the result was Φ D 0 = (61.9 ± 6.2)%; ε A (λ) was calculated from the absorption spectrum of L54, and the emission spectrum of L75 was used for F D (λ) and I D .…”

“…After calculating R 0 it is possible to calculate R DA by using the equation: ,,, R DA 6 = R 0 6 − true( 1 − I DA I normalD true) R 0 6 1 − I DA I D where I D is the emission of the donor and I DA is the emission of the donor in the presence of the acceptor. I D was obtained from the emission spectrum of L75, and I DA was obtained from the emission spectrum of the respective terpolymer or blend.…”

“…The concentration of the solution was kept at 1 × 10 –3 mg/mL for comparison with the lifetime results. By obtaining R 0 and R DA , it is possible to calculate the ETE using the following equation: ,, η = R 0 6 R DA 6 + R 0 6 Through these measurements and parameters, the Förster radius between L75 and L54 was obtained as R 0 = 42.6 Å, and then it was possible to calculate R DA for the terpolymers and the blends. Table shows the results of these calculations.…”

“…The nonradiative energy transfer depends on the overlap between the wave functions of the excited states of the donor and the acceptor, and therefore, it is directly related to the value of R DA . From the absorption, PL, PLQY measurements, and information about the measurement parameters, it is possible to calculate R 0 using the following equation: 27,28,34,35…”

“…The concentration of the solution was kept at 1 × 10 −3 mg/mL for comparison with the lifetime results. By obtaining R 0 and R DA , it is possible to calculate the ETE using the following equation: 27,28,34…”

Intramolecular Energy Transfer in the Terpolymer LaPPS76

“…The nonradiative energy transfer depends on the overlap between the wave functions of the excited states of the donor and the acceptor, and therefore, it is directly related to the value of R DA . From the absorption, PL, PLQY measurements, and information about the measurement parameters, it is possible to calculate R 0 using the following equation: ,,, R 0 = 0.2108 true[ κ 2 normalΦ normalD 0 n − 4 ∫ 0 ∞ F normalD ( λ ) ε normalA ( λ ) λ 4 nobreak0em0.25em⁡ normald λ true] 1 / 6 where κ 2 is the orientation factor, Φ D 0 is the donor PLQY, n is the refraction index of the solvent, F D is the normalized spectral distribution of the donor emission, λ is the photon wavelength and ε A is the molar extinction coefficient of the acceptor. The constants used to calculate the Förster radius were: κ 2 = 2/3 , and n = 1.40496. , The PLQY was measured in solution using an integrating sphere, and the result was Φ D 0 = (61.9 ± 6.2)%; ε A (λ) was calculated from the absorption spectrum of L54, and the emission spectrum of L75 was used for F D (λ) and I D .…”

“…After calculating R 0 it is possible to calculate R DA by using the equation: ,,, R DA 6 = R 0 6 − true( 1 − I DA I normalD true) R 0 6 1 − I DA I D where I D is the emission of the donor and I DA is the emission of the donor in the presence of the acceptor. I D was obtained from the emission spectrum of L75, and I DA was obtained from the emission spectrum of the respective terpolymer or blend.…”

“…The concentration of the solution was kept at 1 × 10 –3 mg/mL for comparison with the lifetime results. By obtaining R 0 and R DA , it is possible to calculate the ETE using the following equation: ,, η = R 0 6 R DA 6 + R 0 6 Through these measurements and parameters, the Förster radius between L75 and L54 was obtained as R 0 = 42.6 Å, and then it was possible to calculate R DA for the terpolymers and the blends. Table shows the results of these calculations.…”

“…The nonradiative energy transfer depends on the overlap between the wave functions of the excited states of the donor and the acceptor, and therefore, it is directly related to the value of R DA . From the absorption, PL, PLQY measurements, and information about the measurement parameters, it is possible to calculate R 0 using the following equation: 27,28,34,35…”

“…The concentration of the solution was kept at 1 × 10 −3 mg/mL for comparison with the lifetime results. By obtaining R 0 and R DA , it is possible to calculate the ETE using the following equation: 27,28,34…”

Intramolecular Energy Transfer in the Terpolymer LaPPS76

Effect of TiO2 nanoparticles on energy transfer mechanism in ternary nanocomposite conjugated polymer blend

Effect of Solvent on Optical Properties and Surface Topography of Nanocomposite Conjugated Polymer Thin Film