Solar Energy Conversion: From Solar Fuels to Organic Photovoltaics and Nanomaterials
Solar fuels are attractive due to their renewable nature and environmental benefits and
complement stored electricity solutions. Understanding the mechanism involved in the initial steps involved in the photocatalytic system is vital to designing new sustainable photocatalytic systems. Photosensitizer is the part of the photocatalytic system that absorbs light and drives the charge generation process. Current state-of-the-art photosensitizers are not efficient enough and are not scalable due to the involvement of precious elements like Ru and Ir. In this project, we investigate the excited state dynamics of photosensitizers that are designed based on earth- abundant elements like Cu, Zn, and Zr. A wide range of spectroscopic tools are employed to obtain a complete picture of the initial steps involved in these molecules once they absorb photons. This includes transient absorption spectroscopy in the picosecond and nanosecond time regimes, time-correlated single photon counting, and other complementary steady-state
spectroscopic and electrochemical techniques.
Organic photovoltaics stand apart from their inorganic counterparts due to their flexibility, lightweight character, low cost, and transparency. While organic photovoltaics based on small molecules have manifested a competing power conversion efficiency of 19%, the practical application of these systems is limited because of their synthetic complexity and expensive large- scale production. A promising alternative is small molecules with a BODIPY core. However, the highest efficiency of these molecules lags by 10 % of the state-of-the-art molecules used in organic photovoltaics. One approach to dramatically increase the efficiency of these molecules is to find exciton recombination pathways and suppress them, wherever possible. This project aims to investigate the mechanism of exciton formation and its dynamics in organic molecules employing time-resolved spectroscopic techniques. In addition, novel nanomaterials are also investigated for applications in solar energy conversion.
Student-in-chief: Thabassum Nattikalungal – tnk (at) usc (dot) edu
Electronic Structure of Aromatic Anions in Ethereal Solvents
Liquid ammonia is a useful solvent in organic chemistry for its ability to stabilize carbanions. These carbanions are typically generated by adding sodium metal to liquid ammonia, which produces solvated electrons which then add to pi-conjugated species. Despite this often-used reagent, the mechanism of action—the principle behind how this reaction works—isn’t very well known.
Structurally, there are different motifs of the solvated electrons which depend on the concentration of alkali metal added. At dilute concentrations of 1 micromolar, the solvated electrons exist as discrete doublet species. At higher concentrations ~0.1 M, the electrons spin-pair to form the mysterious solvated dielectron. Higher concentrations afford a visually striking transition to the metallic state (Mott transition).
Can we measure the binding energies of these different species to understand how they form? Our preliminary work suggest yes, having created the first liquid microjet of neat cryogenic ammonia in vacuum to measure the X-ray photoelectron spectrum of liquid ammonia with our collaborators at BESSY II in Berlin. We have replicated this success with a liquid ammonia sampling system of our very own at USC for time-resolved studies. Work on the alkali metal solutions is continuing both at home and abroad, with the later aim of studying the electronic structure of carbanions otherwise inaccessible in the gas-phase.
Student-in-chief: Brandon Young – bmyoung (at) usc (dot) edu
The Role of Flanking Bases in DNA Photodamage
Light from the sun provides energy to sustain life on Earth. Unfortunately, it can also harm those same living organisms that seek the warmth of the day. A prevalent source of damage to DNA strands is from UV irradiation. Absorption of UV light can lead to the [2+2] cycloaddition of two neighboring thymines or cytosines, thus resulting in the formation of the cyclobutane pyrimidine dimers (CPDs). This is a common lesion in DNA which, upon replication, can lead to mutagenic and carcinogenic effects. Biophysical research on DNA damage by UV radiation often focuses on the role that primary structure plays in the formation of photoproducts. Although it is well known that the electronic excited states of nucleic acids are highly stable, less is known about the excited states dynamics of the oligomer or the role of secondary structure in the formation of CPDs. Previous investigations have demonstrated that bases adjacent to thymine affect the photochemical yield for the CPD formation. However, the role flanking bases have on the rate of CPD formation has yet to be determined.
The formation of CPDs occurs through two different pathways, depending on the stacking of the bases in the strand. When the bases are stacked and in a reactive configuration, the dimerization occurs through an ultrafast, singlet pathway. When the bases are not stacked and are free to move around, this allows the system to transition to a triplet state from which the CPD is formed. It has also been proposed that the presence of charge transfer (CT) states have an important role in regulating this latter dimerization process by either enhancing or impeding it.
The goal of this project is to initially characterize spectroscopic signatures of the CT state, the approach to the conical intersection that leads to dimerization, and the final CPD photoproduct. Transient absorption (TA) will be used to perform characterization of some of the spectroscopic signatures. Meanwhile, those signals not present in TA will be identified using femtosecond stimulated Raman spectroscopy. These experiments will be performed in different sequences to assess the role flanking bases and, in general, secondary structure have on the rates of CPD formation
As an NIH fellow, José seeks to add a new biological perspective on how a simple photochemical transformation in DNA can have a deeper impact on genome stability. When isolated, the CPD photoproduct has limited power to harm the genome. However, in regions of DNA called ‘satellites’, which are known for many instances of AA repetitive sequences, the presence of TT dimers is more profound. As part of a chemistry-biology interface in Dr. Irene Chiolo’s lab, he will study the accumulation of UV photodamage in satellite DNA.
Student-in-chief: José L. Godínez Castellanos
Photo: X-ray crystallographic depiction of the thymine CPD (highlighted in blue) in the complimentary strand of the DNA dodecamer duplex. McAteer, K., Jing, Y., Kao, J., Taylor, J.S., Kennedy, M.A. (1998) J Mol Biol 282: 1013-1032