The Contribution of Charge Separation in Triplet State Formation in Zinc Dipyrrin Photosensitizers

Dzaye, Irene Yayra

04 May 2020

About 85% of the world’s energy is derived from non-renewable sources—coal, petroleum, and natural gas. Solar photocatalysis is one way to potentially generate renewable fuels. Zinc dipyrrin complexes have the potential to be efficient sensitizers for reductive photochemistry, but their ability to form long-lived triplet excited states needs further investigation. The overall aim of this research is to compare the photophysical properties zinc and boron dipyrrin complexes and investigate the role of the charge separated state in triplet state formation. This presentation will describe the synthesis and purification of zinc and boron dipyrrin complexes and their photophysical characterization, including fluorescence quantum yields in a series of solvents and their emission at low temperatures.

Zinc dipyrrin complexes

sensitizers

photophysical properties

Inorganic Chemistry

Investigating the Role of Charge Separation in Triplet State Formation in Zinc Dipyrrin Photosensitizers

Dzaye, Irene Y

01 May 2021

About 85% of the world’s energy is derived from non-renewable sources—coal, petroleum, and natural gas. Solar photocatalysis is one way to potentially generate cheap renewable fuels by harnessing energy from the sun using a photosensitizer and converting it into chemical energy. The efficiency of a photosensitizer depends on its capacity to form a prolonged triplet excited state. Zinc dipyrrin complexes have the potential to be efficient sensitizers for reductive photochemistry, but their ability to form long-lived triplet excited states still needs extensive research. The overall aim of this research is to probe the role charge separation plays in the formation of triplet state in metal complexes of dipyrrin photosensitizers. The specific objectives are to synthesize and characterize zinc and boron dipyrrin complexes, analyze their photophysical properties—such as steady state spectroscopy, low temperature emission spectroscopy—and quantify their triplet states using time-resolved transient absorption spectroscopy.

photosensitizers

triplet excited state

reductive photochemistry

zinc dipyrrin complexes

Inorganic Chemistry

Investigating The Role of Charge Separation in Triplet State Formation in Zinc Dipyrrin Photosensitizers

Dzaye, Irene Yayra

18 March 2021

About 85% of the world’s energy is derived from non-renewable sources—coal, petroleum, and natural gas. Solar photocatalysis is one way to potentially generate cheap renewable fuels by harnessing energy from the sun and converting it into chemical energy. Photosensitizers serve as materials that absorb and store sunlight in the form of chemical energy. The efficiency of a photosensitizer depends on its capacity to form a prolonged triplet excited state. Zinc dipyrrin complexes have the potential to be efficient sensitizers for reductive photochemistry, but their ability to form long-lived triplet excited states still needs extensive research. The overall aim of this research is to probe the role charge separation plays in the formation of triplet state in metal complexes of dipyrrin photosensitizers. The specific objectives are to synthesize and characterize zinc and boron dipyrrin complexes, analyze their photophysical properties—such as steady-state spectroscopy, low-temperature emission spectroscopy—and quantify their triplet states using time-resolved transient absorption spectroscopy.

Zinc dipyrrin complexes

photosensitizers

charge separated state

Inorganic Chemistry

Renewable Energy