3 research outputs found
Investigation of a copper(i) biquinoline complex for application in dye-sensitized solar cells
What difference does a thiophene make? Evaluation of a 4,4′-bis(thiophene) functionalised 2,2′-bipyridyl copper(I) complex in a dye-sensitized solar cell
AbstractThe synthesis of a 4,4′-bis(2-thienyl-5-carboxylic acid) functionalised 2,2′-bipyridine ligand and corresponding copper(I) complex is described and its application in a dye-sensitized solar cell (DSSC) is studied. The positioning of the thiophene groups appears favourable from DFT analysis and a best efficiency of 1.41% was obtained with this dye, for a 0.3 cm2 cell area DSSC. Two absorbance bands are observed in the electronic absorption spectrum of the copper(I) complex at 316 nm and 506 nm, with ε values of 50,000 M−1 cm−1 and 9030 M−1 cm−1, respectively. Cyclic voltammetry and electrochemical impedance spectroscopy are also used to provide a detailed analysis of the dye and assess its functionality in a DSSC
Charge separation at disordered semiconductor heterojunctions from random walk numerical simulations
Many recent advances in novel solar cell technologies are based on charge separation in disordered
semiconductor heterojunctions. In this work we use the Random Walk Numerical Simulation (RWNS)
method to model the dynamics of electrons and holes in two disordered semiconductors in contact.
Miller–Abrahams hopping rates and a tunnelling distance-dependent electron–hole annihilation mechanism
are used to model transport and recombination, respectively. To test the validity of the model,
three numerical ‘‘experiments’’ have been devised: (1) in the absence of constant illumination, charge
separation has been quantified by computing surface photovoltage (SPV) transients. (2) By applying a
continuous generation of electron–hole pairs, the model can be used to simulate a solar cell under
steady-state conditions. This has been exploited to calculate open-circuit voltages and recombination
currents for an archetypical bulk heterojunction solar cell (BHJ). (3) The calculations have been extended to
nanostructured solar cells with inorganic sensitizers to study, specifically, non-ideality in the recombination rate.
The RWNS model in combination with exponential disorder and an activated tunnelling mechanism for
transport and recombination is shown to reproduce correctly charge separation parameters in these three
‘‘experiments’’. This provides a theoretical basis to study relevant features of novel solar cell technologies