Semiconductors group

Polymer transistor performance monitored by terahertz spectroscopy

(2006) 203-203

Authors:

J Lloyd-Hughes, T Richards, E Castro-Camus, H Sirringhaus, LM Herz, MB Johnston

Abstract:

Research on polymer-based transistors is leading to the development of flexible, printable circuitry, which will be extremely cost effective to manufacture. However, the longterm performance of state-of-the-art polymer field effect transistors (pFETs) is limited by device degradation. We show that terahertz spectroscopy is an ideal tool to probe polymer device performance. Specifically we have monitored charge carrier trapping at the polymer-insulator boundary of a pFET. From these results we show that device degradation is primarily caused by a trapping of holes in the channel of the pFET, rather than by a change in hole mobility.

Chirality-dependent boron-mediated growth of nitrogen-doped single-walled carbon nanotubes

Physical Review B - Condensed Matter and Materials Physics 72:20 (2005)

Authors:

JG Wiltshire, LJ Li, LM Herz, RJ Nicholas, M Glerup, JL Sauvajol, AN Khlobystov

Abstract:

A change in the relative abundance of single-walled carbon nanotubes, due to the presence of both nitrogen and boron during synthesis, has been identified through Raman and absorption spectroscopy. Raman spectroscopy shows that for two specific branches boron mediates the growth of smaller-diameter zigzag or near-zigzag nanotubes. We combine our experimental results with an improved Kataura model to identify two of the preferentially grown species as (16,0) and (14,1). © 2005 The American Physical Society.

The effects of supramolecular assembly on exciton decay rates in organic semiconductors.

J Chem Phys 123:8 (2005) 084902

Authors:

Clément Daniel, François Makereel, Laura M Herz, Freek JM Hoeben, Pascal Jonkheijm, Albertus PHJ Schenning, EW Meijer, Richard H Friend, Carlos Silva

Abstract:

We present time-resolved photoluminescence measurements on two series of oligo-p-phenylenevinylene (OPV) materials that are functionalized with quadruple hydrogen-bonding groups. These form supramolecular assemblies with thermotropic reversibility. The morphology of the assemblies depends on the way that the oligomers are functionalized; monofunctionalized OPVs (MOPVs) form chiral, helical stacks while bifunctionalized OPVs (BOPVs) form less organized structures. These are therefore model systems to investigate the effects of supramolecular assembly, the effects of morphology, and the dependence of oligomer length on the radiative and nonradiative rates of pi-conjugated materials. The purpose of this work is to use MOPV and BOPV derivatives as model systems to study the effect of intermolecular interactions on the molecular photophysics by comparing optical properties in the dissolved phase and the supramolecular assemblies. A simple photophysical analysis allows us to extract the intrinsic radiative and nonradiative decay rates and to unravel the consequences of interchromophore coupling with unprecedented detail. We find that interchromophore coupling strongly reduces both radiative and intrinsic nonradiative rates and that the effect is more pronounced in short oligomers.

Excitation migration along oligophenylenevinylene-based chiral stacks: delocalization effects on transport dynamics.

J Phys Chem B 109:21 (2005) 10594-10604

Authors:

D Beljonne, E Hennebicq, C Daniel, LM Herz, C Silva, GD Scholes, FJM Hoeben, P Jonkheijm, APHJ Schenning, SCJ Meskers, RT Phillips, RH Friend, EW Meijer

Abstract:

Atomistic models based on quantum-chemical calculations are combined with time-resolved spectroscopic investigations to explore the migration of electronic excitations along oligophenylenevinylene-based chiral stacks. It is found that the usual Pauli master equation (PME) approach relying on uncoherent transport between individual chromophores underestimates the excitation diffusion dynamics, monitored here by the time decay of the transient polarization anisotropy. A better agreement to experiment is achieved when accounting for excitation delocalization among acceptor molecules, as implemented in a modified version of the PME model. The same models are applied to study light harvesting and trapping in guest-host systems built from oligomers of different lengths.

Exciton migration in rigid-rod conjugated polymers: an improved Förster model.

J Am Chem Soc 127:13 (2005) 4744-4762

Authors:

Emmanuelle Hennebicq, Geoffrey Pourtois, Gregory D Scholes, Laura M Herz, David M Russell, Carlos Silva, Sepas Setayesh, Andrew C Grimsdale, Klaus Müllen, Jean-Luc Brédas, David Beljonne

Abstract:

The dynamics of interchain and intrachain excitation energy transfer taking place in a polyindenofluorene endcapped with perylene derivatives is explored by means of ultrafast spectroscopy combined with correlated quantum-chemical calculations. The experimental data indicate faster exciton migration in films with respect to solution as a result of the emergence of efficient channels involving hopping between chains in close contact. These findings are supported by theoretical simulations based on an improved Forster model. Within this model, the rates are expressed according to the Fermi golden rule on the basis of (i) electronic couplings that take account of the detailed shape of the excited-state wave functions (through the use of a multicentric monopole expansion) and (ii) spectral overlap factors computed from the simulated acceptor absorption and donor emission spectra with explicit coupling to vibrations (considered within a displaced harmonic oscillator model); inhomogeneity is taken into account by assuming a distribution of chromophores with different conjugation lengths. The calculations predict faster intermolecular energy transfer as a result of larger electronic matrix elements and suggest a two-step mechanism for intrachain energy transfer with exciton hopping along the polymer backbone as the limiting step. Injecting the calculated hopping rates into a set of master equations allows the modeling of the dynamics of exciton transport along the polyindenofluorene chains and yields ensemble-averaged energy-transfer rates in good agreement with experiment.