2,695 research outputs found
How mobile are dye adsorbates and acetonitrile molecules on the surface of TiO2 nanoparticles? A quasi-elastic neutron scattering study
Motions of molecules adsorbed to surfaces may control the rate of charge transport within monolayers in systems such as dye sensitized solar cells. We used quasi-elastic neutron scattering (QENS) to evaluate the possible dynamics of two small dye moieties, isonicotinic acid (INA) and bis-isonicotinic acid (BINA), attached to TiO2 nanoparticles via carboxylate groups. The scattering data indicate that moieties are immobile and do not rotate around the anchoring groups on timescales between around 10 ps and a few ns (corresponding to the instrumental range). This gives an upper limit for the rate at which conformational fluctuations can assist charge transport between anchored molecules. Our observations suggest that if the conformation of larger dye molecules varies with time, it does so on longer timescales and/or in parts of the molecule which are not directly connected to the anchoring group. The QENS measurements also indicate that several layers of acetonitrile solvent molecules are immobilized at the interface with the TiO2 on the measurement time scale, in reasonable agreement with recent classical molecular dynamics results
Decoupling polymer, water and ion transport dynamics in ion-selective membranes for fuel cell applications
Ion conducting polymer membranes are designed for applications ranging from separation and dialysis, to energy conversion and storage technologies. A key application is in fuel cells, where the semi-permeable polymer membrane plays several roles. In a fuel cell, electrical power is generated from the electrochemical reaction between oxygen and hydrogen, catalysed by metal nanoparticles at the cathode and anode sites. The polymer membrane permits the selective transport of H+ or OH− to enable completion of the electrode half-reactions, plays a major role in the management of water that is necessary for the conduction process and is a product in the reactions, and provides a physical barrier against leakage across the cell. All of these functions must be optimised to enable high conduction efficiency under operational conditions, including high temperatures and aggressive chemical environments, while ensuring a long lifetime of the fuel cell. Polymer electrolyte membranes used in current devices only partially meet these stringent requirements, with ongoing research to assess and develop improved membranes for a more efficient operation and to help realise the transition to a hydrogen-fuelled energy economy. A key fundamental issue to achieving these goals is the need to understand and control the nature of the strongly coupled dynamical processes involving the polymer, water and ions, and their relationship to the conductivity, as a function of temperature and other environmental conditions. This can be achieved by using techniques that give access to information across a wide range of timescales. Given the complexity of the dynamical map in these systems, unravelling and disentangling the various processes involved can be accessed by applying the “serial decoupling” approach introduced by Angell and co-workers for ion-conducting glasses and polymers. Here we introduce this concept and propose how it can be applied to proton- and anion-conducting fuel cell membranes using two main classes of these materials as examples
Derivation of Matrix Product Ansatz for the Heisenberg Chain from Algebraic Bethe Ansatz
We derive a matrix product representation of the Bethe ansatz state for the
XXX and XXZ spin-1/2 Heisenberg chains using the algebraic Bethe ansatz. In
this representation, the components of the Bethe eigenstates are expressed as
traces of products of matrices which act on , the tensor
product of auxiliary spaces. By changing the basis in , we
derive explicit finite-dimensional representations for the matrices. These
matrices are the same as those appearing in the recently proposed matrix
product ansatz by Alcaraz and Lazo [Alcaraz F C and Lazo M J 2006 {\it J. Phys.
A: Math. Gen.} \textbf{39} 11335.] apart from normalization factors. We also
discuss the close relation between the matrix product representation of the
Bethe eigenstates and the six-vertex model with domain wall boundary conditions
[Korepin V E 1982 {\it Commun. Math. Phys.}, \textbf{86} 391.] and show that
the change of basis corresponds to a mapping from the six-vertex model to the
five-vertex model.Comment: 24 pages; minor typos are correcte
Decoupled molecular and inorganic framework dynamics in CH3NH3PbCl3
The organic-inorganic lead halide perovskites are composed of organic
molecules imbedded in an inorganic framework. The compounds with general
formula CHNHPbX (MAPbX) display large photovoltaic
efficiencies for halogens =Cl, Br, and I in a wide variety of sample
geometries and preparation methods. The organic cation and inorganic framework
are bound by hydrogen bonds that tether the molecules to the halide anions, and
this has been suggested to be important to the optoelectronic properties. We
have studied the effects of this bonding using time-of-flight neutron
spectroscopy to measure the molecular dynamics in CHNHPbCl
(MAPbCl). Low-energy/high-resolution neutron backscattering reveals
thermally-activated molecular dynamics with a characteristic temperature of
95\,K. At this same temperature, higher-energy neutron spectroscopy
indicates the presence of an anomalous broadening in energy (reduced lifetime)
associated with the molecular vibrations. By contrast, neutron powder
diffraction shows that a spatially long-range structural phase transitions
occurs at 178\,K (cubic tetragonal) and 173\,K (tetragonal
orthorhombic). The large difference between these two temperature
scales suggests that the molecular and inorganic lattice dynamics in MAPbCl
are actually decoupled. With the assumption that underlying physical mechanisms
do not change with differing halogens in the organic-inorganic perovskites, we
speculate that the energy scale most relevant to the photovoltaic properties of
the lead-halogen perovskites is set by the lead-halide bond, not by the
hydrogen bond.Comment: (10 pages, 5 figures, to be published in Physical Review Materials
Crystal electric field and possible coupling with phonons in Kondo lattice CeCuGa3
We investigate the magnetic and crystal electric field (CEF) states of the
Kondo lattice system CeCuGa3 by muon spin relaxation (muSR), neutron
diffraction, and inelastic neutron scattering (INS) measurements. A
noncentrosymmetric BaNiSn3-type tetragonal crystal structure (space group I4mm)
is inferred from x-ray as well as from neutron powder diffraction. The
low-temperature magnetic susceptibility and heat capacity data show an anomaly
near 2.3 - 2.5~K associated with long range magnetic ordering, which is further
confirmed by muSR and neutron diffraction data. The neutron powder diffraction
collected at 1.7 K shows the presence of magnetic Bragg peaks indexed by an
incommensurate magnetic propagation vector k = (0.148, 0.148, 0) and the
magnetic structure is best described by a longitudinal spin density wave with
ordered moments lying in ab-plane. An analysis of the INS data based on a CEF
model reveals the presence of two magnetic excitations near 4.5 meV and 6.9
meV. The magnetic heat capacity data suggest an overall CEF splitting of 20.7
meV, however the excitation between 20 and 30 meV is very broad and weak in our
INS data, but could provide an evidence of CEF level in this energy range in
agreement with the magnetic entropy. Our analysis of INS data based on the
CEF-phonon model indicates that the two excitations at 4.5 meV and 6.9 meV have
their origin in CEF-phonon coupling (i.e. splitting of one CEF peak into two
peaks, called vibron), with an overall splitting of 28.16 meV, similar to the
case of CeCuAl3 and CeAuAl3.Comment: 13 pages, 14 figure
- …