3.1.1. Collapse and aggregation in thermo­responsive polymer hydrogels

Thermo­responsive polymers in aqueous solution collapse from extended coils to compact globules when the temperature is raised above their cloud point (so-called because the solution becomes turbid due to the formation of the aggregates), displaying lower critical solution temperature (LCST) behaviour, an effect that can be exploited by cross-linking the polymers. The switching time and reversibility are of great importance for applications such as controlled ultra­filtration. Time-resolved SANS provides a wealth of information on the structural changes at the cloud point. A temperature jump across the cloud point has been achieved using a modified stopped-flow instrument (Grillo, 2009), pumping the solution, held below the cloud-point, from the reservoir into a sample cell held above the cloud point. Heating by a few kelvin typically takes 100–200 s. SANS measurements can be carried out with 100 ms resolution, and the runs are typically repeated to improve statistics. A dedicated setup for such experiments is shown in Fig. 1(a) (Adelsberger et al., 2012, 2013). SANS curves of a concentrated triblock copolymer solution, where the polymer has a thermo­responsive middle block and hydrophobic end blocks, undergo complex changes when the cloud point is crossed (Fig. 1b). Detailed information is obtained on the strength and timescale of the collapse of the thermo­responsive block which makes up the micellar shell and on aggregate growth (Fig. 1c). Such investigations have been carried out on various polymeric architectures (Meier-Koll et al., 2012; Adelsberger et al., 2012, 2013; Jaksch et al., 2014).

Figure 1 Time-resolved SANS during a temperature jump in a polymer solution. (a) Modified stopped-flow instrument. (b) SANS curves from a 200 mg ml−1 solution of poly­styrene-block-poly(N-isopropyl­acryl­amide)-block-poly­styrene triblock copolymer with fully deuterated poly­styrene blocks in D2O, for a temperature jump from 303 to 308 K. Temperatures below the cloud point (305.7 K) are shown in blue and above in red. (c) Plot showing the radii of the micelles (black circles) and the aggregate size (green triangles) with time. The dashed line marks the cloud point. (d) Schematic diagram of polymer collapse and aggregate formation. Adapted from Adelsberger et al. (2013).

3.1.2. Metal film preparation on nanostructured polymer surfaces

Nanostructured block copolymer thin films have been proposed as templates, guiding metal nanoparticles onto solid surfaces to create nanopatterns. Gold, for instance, has unique optoelectronic properties, and gold cluster assemblies are therefore promising candidates for solar cells and reflective or antireflective coatings. Knowledge of the mechanisms involved in nanoparticle formation and growth during metal sputtering onto nanostructured block copolymer thin films is important for identifying appropriate metal sputtering conditions. Early experiments were carried out in a stop–sputter mode, in which the metal was sputter-deposited onto the substrate at a certain deposition rate for a few seconds and two-dimensional GISAXS maps were collected after each sputtering step (Metwalli et al., 2008; Kaune et al., 2009; Buffet et al., 2011). Recently, real-time GISAXS data were acquired during the sputtering process (Schwartzkopf et al., 2013; Metwalli et al., 2013). In both types of experiment, and in combination with ex situ atomic force microscopy, structural information is gained regarding the shape, size and distribution of the metal nanoparticles, as well as their spatial ordering on the surface and the metal distribution along the film normal.

The in situ growth of cobalt metal on a laterally nano­structured polystyrene-block-polyisoprene diblock copolymer thin film was investigated in a real-time sputtering experiment (Metwalli et al., 2013). GISAXS images were taken during the sputtering process with a time resolution of 1 s at a sputter rate of 0.8 nm min⁻¹. The GISAXS data identified the onset of metal film formation through intensity oscillations along the film normal. The film thickness could be deduced and compared with the nominal sputter rate. Out-of-plane reflection peaks observed in the pure block copolymer thin film were reproduced in data from the cobalt nanoparticles, allowing three regimes to be distinguished: nucleation of atoms resulting in nanoparticle formation preferentially in the polystyrene domains, particle growth, and coalescence of neighbouring metal aggregates into a quasi-uniform metal layer. Other in situ real-time GISAXS experiments have studied metal deposition onto amorphous silicon oxide (Schwartzkopf et al., 2013) and materials for organic light-emitting diodes (Yu et al., 2013).

3.2.1. Structural changes as a function of pressure

In situ SAXS and WAXS measurements using a high-pressure cell, e.g. a diamond anvil cell (DAC), allow the relationship between nanoparticle distance and structure to be explored. To achieve these measurements, a number of experimental parameters need to be modified, such as the X-ray energy to minimize absorption by the diamond windows. In wurtzite CdSe supercrystals, the interparticle spacing was measured up to 10 GPa and its variation related to changes in the atomic structure of the nanoparticles (Wang et al., 2010).

3.2.2. GISAXS vapour sorption/desorption studies

Solvent can change the interaction between nanocrystals and represents another means for manipulating properties (Fig. 2). Films of PbS or PbSe nanocrystals modified with oleic acid form a body-centred tetragonal (b.c.t.) structure. When exposed to octane vapour, this undergoes a (reversible) symmetry transformation to a face-centred cubic (f.c.c.) structure within a few minutes, as shown using in situ GISAXS (Bian et al., 2011). In another in situ GISAXS experiment, the symmetry transformations on removing solvent from a swollen, and therefore disordered, film were addressed. The choice of solvent mediates the ligand–ligand interaction and modulates the timescale of interdigitation, and the solvent evaporation rate plays an important role in the final structure. Time-resolved GISAXS measurements are thus ideal to investigate the structural changes, with the results paving the way for engineering quantum crystals with desired properties.

Figure 2 In situ GISAXS patterns and corresponding structures of solvent vapour-mediated transformations in a PbS nanocrystal superlattice. (a) and (e) Disordered film in a saturated octane vapour environment. (b) Initial superlattice nucleation in a subsaturated vapour environment. (c) and (f) Face-centred cubic (f.c.c.) nanocrystal superlattice formed by drying the film. (d) and (g) Body-centred tetragonal (b.c.t.) nanocrystal superlattice formed by drying in the presence of He purge. (h) Molecular dynamics snapshot of two nanocrystals and (i) of ligands between facets of proximate nanocrystals. δ and LOA denote the interparticle distance and length of the oleic acid ligand, respectively. Reprinted with permission from Bian et al. (2011). Copyright (2011) American Chemical Society.

The self-assembly of non-spherical nanocrystals was investigated using Pt₃Cu₂ nanoctahedra capped with oleylamine (Zhang et al., 2012). In situ GISAXS revealed crystallization during controlled solvent evaporation in real time. As the suspension in hexane dried slowly in a solvent vapour treatment (SVT) chamber, the broad intensity distribution in the GISAXS data transformed into discrete Bragg spots which continuously changed position during drying. A critical concentration of nanocrystals was determined at which crystallization sets in, corresponding to a Kirkwood–Alder transition. The body-centred cubic (b.c.c.) lattice formed at the disorder-to-order transition shrinks down to the limit of steric hindrance, where the nanoctahedra arrange tip-to-tip. Subsequent swelling in solvent vapour reveals the process to be reversible and so defects present after initial drop-casting may be annealed. Thus, `smart' environmentally adaptable mat­erials for application in sensors and catalysis may be developed.

3.3.1. SCXRD vapour sorption studies

Peterson et al. (2014) investigated in situ the structure of a range of guest molecules within the same single crystal of Cu₃(1,3,5-benzene­tri­carboxylate)₂, a well known porous coordination framework with a broad range of applications. SCXRD data were collected on a crystal positioned inside a polyimide capillary with the top open. The capillary was mounted in the centre of a cryostream and the bottom either closed or connected to a tube of dry helium or helium/vapour flow. Data were collected at 293 K for the material equilibrated with different guest vapours, with the vapours introduced by bubbling helium through a glass vial of the selected guest liquid. The crystal was desolvated at 473 K under dry helium flow between the different vapours. Full data sets were collected for cyclohexane, methanol, ethanol, propan-1-ol, propan-2-ol, toluene, acetonitrile and tetrahydrofuran. Structural solution and refinement were successful for all vapour–host data and revealed the host structure, with difference Fourier methods used to locate the guests within the three pores, including interaction with the coordinatively un­saturated Cu^II sites. The structural measurements correlated with the vapour sorption measurements, delivering a detailed understanding of the underlying mechanisms responsible for adsorption behaviour and revealing a strong thermodynamic influence (both enthalpic and entropic), as well as size-exclusion effects.

3.3.2. NPD gas adsorption studies

Using NPD, McCormick et al. (2014) examined the novel ultramicroporous material Cu₃[C(CN)₂(CONH₂)⁻]₄. The 0.35 nm nanotube-like channels of this material and the unprecedented concentration of coordinatively unsaturated Cu^II sites result in selectivity of CO₂ over CH₄, which is useful for the industrial separation of CO₂ from natural gas. As neutron diffraction intensity does not reduce with scattering angle, relatively more fine structural information is gained than using X-rays and this, when combined with the neutron's isotopically dependent information, provides details of the CO₂ orientation in this mat­erial. Furthermore, neutrons readily penetrate the complex sample environment required for controlling the temperature of the host at the same time as gas delivery, making it easy to cover a range of temperature from very cold (about 10 K) to more moderate working conditions (313–348 K). The neutron penetration also provides information about the more industrially relevant `bulk' properties of the material and aids in accurate dosing with a known number of guest molecules.

NPD data were collected for ∼1 g of desolvated material, which was sequentially dosed with two concentrations of CO₂. While this approach has been used previously, this was the first time gas dosing, evacuation and measurement were achieved remotely from the instrument cabin. The sample cell was connected to a gas-delivery stick custom-designed for use with a top-loading cryofurnace. The sample was isolated with a valve that was opened upon connection to the gas-delivery stick, which has an isolation valve located external to the cryofurnace. A customized and automated manometric gas-delivery system was attached to the gas-delivery stick, enabling gas delivery to or evacuation of the sample. The temperature of the sample and gas-delivery line was controlled independently of the cryofurnace, allowing the sample to be left in place throughout the experiment (Fig. 3). Data for the empty and carbon-dioxide-loaded sample were collected for 30 min at 15 K, with the sample warmed to 300 K prior to dosing and the delivery line kept above the boiling point of CO₂ at that pressure. After gas adsorption, identified by a zero pressure reading, the sample was cooled over approximately 1 h, ensuring diffusion of the CO₂ molecules to their thermodynamic equilibrium positions and minimizing disorder. This experimental setup allows remote switching between types of gases and sample regeneration.

Figure 3 NPD experimental setup for examining porous sorbents, shown for the ultramicroporous Cu3[C(CN)2(CONH2)−]4 experiment of McCormick et al. (2014). The setup features full remote control once the sample is in place, with temperature control of the sample and gas dosing line.

Data were analysed using a combination of Rietveld and difference Fourier methods and molecular dynamics simulations. A close packing of single rows of CO₂ in the tubular nanostructure of Cu₃[C(CN)₂(CONH₂)⁻]₄ was revealed, in which the CO₂ was shown to interact with the Cu^II sites, revealing the mechanism of selectivity for CO₂.

Advances in neutron instrumentation, particularly large and fast area detectors, have led to the opportunity to collect real-time data. While in situ NPD data during guest adsorption by porous materials have been collected on a timescale of minutes using the setup in Fig. 3, the first non-equilibrium measurements were reported by Mulder et al. (2010). In this work, time-of-flight NPD was used to elucidate the storage mechanism of molecular hydrogen in the porous Cr(OH)(1,4-benzene­dicarboxylate) material. In situ NPD data were recorded every 10–15 min during loading and unloading of molecular deuterium at various temperatures (Fig. 4).

Figure 4 Non-equilibrium NPD data of molecular deuterium in Cr(OH)(1,4-benzenedicarboxylate). (Left) NPD data as a function of time, collected during loading at 25 K, cooling to 10 K and subsequent heating to 150 K, under a constant pressure of 2.0 bar of molecular deuterium. (Right) Lattice parameters extracted from these data. Reprinted and adapted with permission from Mulder et al. (2010). Copyright (2010) American Chemical Society.

This work also examined the Cr(OH)(1,4-benzene­dicarboxylate) structure equilibrated with known amounts of deuterium gas using a less automated approach than that used by McCormick et al. (2014). The delivery of gases with a low boiling point such as deuterium is less challenging experimentally than for gases with a higher boiling point (such as CO₂), because of the reduced heating of the system required to avoid freezing of the gas in the delivery line. Data for the non-equilibrium system collected during gas loading were obtained by exposing the sample to a constant pressure of 2.0 bar (1 bar = 100 000 Pa) of molecular deuterium. Here, neutrons are needed to measure the structure of hydrogen in the system, where insufficient scattering power is provided by X-rays which provide information dominated by the electron-heavy host. Rietveld refinements were performed using difference Fourier methods, with the deuterium molecule modelled as a spherically averaged point scatterer. This work found expected and significant `breathing' of the structure upon hydrogen loading and release. Interestingly, the breathing was found to be in the direction of the larger pore openings and opposite to that observed for water uptake. Such guest-dependent behaviour is best captured by studying the system under non-equilibrium conditions, where the system is performing close to its working conditions as a hydrogen-storage material.

3.3.3. SANS gas adsorption studies

The flexible pillared layered cyanide material Ni[1,2-bis(4-pyridyl)ethylene][Ni(CN)4] (NiBpeneNiCN) selectively adsorbs CO₂ over N₂. Interestingly, the rapid rise in the uptake of CO₂ by this material during separation from N₂ is accompanied by a dynamic structural transition, and this was investigated using in situ neutron diffraction in combination with IR spectroscopy (Kauffman et al., 2011). Here, the crystallographic detail of the material could not be obtained using traditional powder diffraction, due to peak broadening, presumably as a result of disorder. A SANS instrument was used to measure the 002 lattice spacing, which changed from ∼12.46 to 13.28 Å upon saturation of the material with CO₂ but not with pure N₂. This work revealed that the lattice changed only upon exposure to the preferentially adsorbed CO₂ and not N₂, indicating that the structural response observed in the 50:50 gas mixture is driven by CO₂.

3.3.4. QENS gas adsorption studies

The dynamic information obtained through neutron scattering is isotopically dependent, and neutron spectroscopy allows direct measurement of the local environment and the diffusional transport of the guest within the host. Using neutrons, both structure and dynamics can be measured simultaneously, enabling insights into the geometry of the guest motion and gaining details of the diffusion mechanism. Neutron spectroscopy measurements are typically slower than for diffraction, and therefore time-resolved measurements are relatively scarce. In situ neutron spectroscopy experiments investigating porous materials have been carried out for systems equilibrated at a variety of temperatures and guest concentration or pressure. Yang et al. (2011) used QENS to investigate concentration-dependent CO₂ and CH₄ diffusion in the highly stable porous material Zr₆O₄(OH)₄(1,4-benzenedicarboxylate)₁₂, known for its CO₂ selectivity. An activated sample was loaded into a rectangular aluminium cell fitted with a gas inlet allowing in situ adsorption, with the gas amounts determined mano­metrically, in an approach similar to that used by others such as Mulder et al. (2010) and with a more basic approach than that of McCormick et al. (2014). All parts of the gas-delivery system and sample were above 230 K during adsorption, with QENS data for the material with and without CO₂ collected without further cooling (i.e. at 230 K). The sample was re­activated in situ and data then collected as a function of CH₄ concentration. In contrast with CH₄, CO₂ is a totally coherent neutron scatterer, and the diffusion constant obtained using QENS for this molecule was derived from the reduction in elastic neutron scattering as a result of diffusion. Hence, this work derived the experimental self-diffusivity of CH₄ and the transport diffusivity of CO₂ in the material. The QENS results were calculated using molecular dynamics simulations, and in this way the mechanism of diffusion for both gases within the material could be extracted and was found to be significantly concentration dependent. The coupling of neutron scattering results with computational calculations is a powerful combination, often yielding the exact details of local processes, with the computational model validated against the experimental result for the average system.

3.4.1. Time-resolved neutron spectroscopy

Tricalcium silicate is the main component of ordinary Portland cement, and it hydrates to form crystalline calcium hydroxide and `calcium silicate hydrate', the latter product having variable stoichiometry. A typical time-resolved QENS data set for hydrating tricalcium silicate is shown in Fig. 5, where the central peak at zero energy transfer arises from immobile hydrogen in the reaction products, i.e. calcium hydroxide and some types of calcium silicate hydrate, and increases over time. In particular, calcium silicate hydrate is of great importance as it is the component responsible for strength development. In this experiment, the main component of cement, tricalcium silicate, was mixed with water and spectra collected every 33 min, with the data collection beginning 30 min after initial mixing.

Figure 5 Time-resolved data for the hydrating main component of ordinary Portland cement (tricalcium silicate). (Left) QENS spectra. (Right) Time evolution of the constrained hydrogen and immobile hydrogen (structural) components obtained using QENS (left), alongside the total heat evolved as measured using calorimetry. Adapted from Peterson (2010).

The hydrogen component that is considered immobile on the timescale accessible by the spectrometer, known as `structural' hydrogen, closely tracks the evolution of heat, as measured by calorimetry, for the first 2 d (Fig. 5). Two different calcium silicate hydrates have been found in setting cement, and both can be measured using QENS. Of the reaction products, the `structural' QENS component is associated with the formation of all of the calcium hydroxide and one of the calcium silicate hydrates. The less mobile hydrogen component, `constrained' hydrogen, is found in interlayer water in the smallest pores and adsorbed onto surfaces. Notably, this QENS component is associated with the formation of a high-surface-area calcium silicate hydrate phase. Hence, QENS measures all hydration products and not just those associated with the evolution of heat. Kinetic information on the formation rate of various products can be derived from such measurements and is invaluable for understanding the development of important properties such as strength (Peterson, 2010).

Although QENS is the major time-resolved neutron spectro­scopic technique used to study cement hydration, INS has also been used for this purpose. FitzGerald et al. (1999) first used INS to measure quantitatively the formation of calcium hydroxide during the hydration of a cementitious material by comparison of the INS spectrum for the hydrating sample with that for a calcium hydroxide reference material. The work enabled kinetic parameters for the hydration to be derived. Importantly, combining the INS results with the QENS results allowed the hydrogen content of the calcium silicate hydrate to be established. Extension of the time-resolved work to include the temperature dependency of calcium hydroxide evolution in the non-equilibrium system revealed that the hydrogen content of the calcium silicate hydrate decreased significantly at increased curing temperature, likely contributing to the altered strength.

3.4.2. Time-resolved SANS

The surface area of cement increases during setting, and real-time SANS and SAXS have been used to follow the fractal microstructural development in hydrating cement. Although the microstructural development measured by SAXS and SANS has been shown to follow the heat output initially, as with QENS this does not continue over extended periods (Allen & Thomas, 2007). The dense (inner product) calcium silicate hydrate phase, produced after approximately 24 h, has a morphology that is invisible to SANS and SAXS. These techniques are therefore easily able to follow the development of the less dense (outer product) calcium silicate hydrate, important in the development of strength. Such experiments have been used to examine, amongst others, the effect of additives such as the accelerant calcium chloride on the microstructural development, as shown by Thomas et al. (2009; Fig. 6).

Figure 6 Surface-area development of hydrating tricalcium silicate. (Left) Surface-area development, shown alongside heat output as measured using calorimetry. Reprinted with permission from Allen & Thomas (2007). Copyright (2007) Elsevier. (Right) Surface-area development with (circles) and without (squares) calcium chloride. Reprinted with permission from Thomas et al. (2009). Copyright (2009) American Chemical Society.

3.5.1. In operando synchrotron XRPD and pair-distribution function analysis

As structural changes in both the anode and cathode play an important role in overall battery performance, in situ X-ray diffraction has become an essential tool in rechargeable lithium-ion battery research. Given the importance of this research, particularly in understanding the phase and lattice-parameter evolution of electrode materials during charge and discharge, it was necessary to develop specialized electrochemical cells for experiments. Brant et al. (2013) presented a simple in situ cell design for this purpose (Fig. 7, right-hand side), derived from various in situ electrochemical cells developed over the last three decades. Importantly, the design uses components that are routinely available and can be machined in-house.

Figure 7 Specialist electrochemical cells for use in in situ transmission synchrotron XRPD experiments. (Left) The AMPIX cell for use in PDF experiments (Borkiewicz et al., 2012). (Right) Schematic diagram of a cell for traditional synchrotron XRPD [Brant et al. (2013). Reprinted with permission. Copyright Elsevier (2013)]. Exploded views (top) and assembled cell photos (bottom) are shown.

XRPD pair-distribution function (PDF) analyses of electrodes have been performed in operando during battery cycling (Hua et al., 2014). This study examined the CuF₂ cathode, of particle size ∼9 nm, where cathode pellets were assembled into the specialist AMPIX cell (Borkiewicz et al., 2012), shown in the left-hand part of Fig. 7, and Li metal was used as the counter-electrode. Total scattering data were collected in transmission geometry. The collection of high-quality total scattering data for PDF analysis requires careful subtraction of data for components other than the material of interest. In this study, data for a reference cell containing all cell components in the same mass ratio except the active material were collected under the same experimental conditions. In addition to background subtraction, further corrections for sample self-absorption, multiple scattering, X-ray polarization and Compton scattering were included to obtain the normalized total scattering structure function, and the PDF was generated via its direct Fourier transformation (Fig. 8). The data give a detailed insight into the local structural changes occurring in the cathode during electro­chemical function. Data at the beginning of the discharge were dominated by CuF₂, with peaks at ∼1.9 and 2.3 Å corresponding to equatorial and axial Cu—F bonds, respectively, reflecting a Jahn−Teller distortion for Cu²⁺. Broad features at ∼3.6 Å correspond to distances between Cu²⁺ cations, and between Cu²⁺ and F⁻ ions, in neighbouring octahedra. The PDF at the end of the discharge has peaks at ∼2.6, 3.6 and 4.4 Å, corresponding to Cu—Cu distances in the first, second and third coordination shell, respectively, for face-centred cubic (f.c.c.) Cu metal. The transformation from CuF₂ to Cu is also evident in intensity changes.

Figure 8 In operando PDFs for the CuF2 cathode during the first discharge, with initial and end states highlighted in bold. Black and red arrows indicate a decrease and an increase in intensity, respectively. Reprinted with permission from Hua et al. (2014). Copyright (2014) American Chemical Society.

3.5.2. In operando NPD

The possibility of using in operando powder diffraction to study not only the reaction mechanism and lattice-parameter evolution of electrodes, but also the insertion/extraction mechanism of charge carriers within these, is highly useful in battery development. In particular, NPD can be used to gain insights into lithium within electrodes, and consequently in operando NPD is attracting increasing attention in the lithium-ion battery research community. Such information is difficult to extract, and until recently was only demonstrated under equilibrium conditions with long collection times. The first real-time NPD in operando experiment was performed by Sharma et al. (2010) on a commercial lithium-ion battery. This work established the phase evolution of the cathode and anode. Since then, developments in experimental and analytical approaches have enabled the lithium occupancy and location within the cathode and anode to be extracted using in operando NPD, as demonstrated first by Sharma et al. (2013). This work used a prismatic battery with dimensions 5 × 36 × 70 mm composed of an aluminium casing, aluminium and copper current collectors, a graphite anode and the cathode mixture. Data were collected every 5 min for 21 h. Full Rietveld analysis of the data revealed the lithium location and amount during charge/discharge (Fig. 9). This work provided an unparalleled insight into the function of the cathode, explaining its relative ease of discharge compared with charge. The experiment paved the way for further work by Pang et al. (2014) using custom-designed batteries with an even further improved signal, achieved in part due to the use of deuterated electrolytes.

Figure 9 In operando NPD study of the Li1+yMn2O4 cathode. (Left) Time-dependent occupancy and location of lithium at the 8a and 16c crystallographic sites (black and red, respectively; total shown in blue). (Right) The diffusion path between the crystallographic sites during charge (green arrows) and discharge (blue arrows). Adapted from Sharma et al. (2013).

3.5.3. In operando neutron reflectometry

Integral to the function of a lithium-ion battery is the formation of the solid–electrolyte interface (SEI) layer, a self-forming passivation layer generated as a result of electrolyte instability with respect to the anode chemical potential. The SEI layer generates sufficient electronic resistance to limit further electrolyte decomposition. However, the continued slow growth of the layer leads to capacity fade, and therefore the layer is of great interest. Owejan, Owejan et al. (2012) first used neutron reflectometry to study the formation and structure of the layer in a lithium half-cell, as shown in Fig. 10. A requirement for neutron reflectometry is a flat and smooth surface, as it probes the average in-plane scattering length density profile. The half-cell of Owejan, Owejan et al. (2012) was configured with Cu as the `counter'-electrode to prevent Li reaction with the electrode, ensuring that all the electrochemical charge could be attributed to the decomposition of the electrolyte and SEI layer formation. Subsequently, Yonemura et al. (2014) developed a purpose-built cell for such experiments.

Figure 10 Neutron reflectivity data for a cell at open-cell voltage (OCV) and after ten cycles. Solid lines are the best fit. (Inset) The scattering length density (SLD) of Si, Cu, Ti and electrolyte, with SEI and TiSix layers. Reprinted with permission from Owejan, Owejan et al. (2012). Copyright (2012) American Chemical Society.

3.5.4. In operando charge-carrier distribution measurement

The macroscopic distribution of charge carriers throughout a battery is of great interest for the optimization of battery design, with neutron imaging methods offering the opportunity to obtain this information. Currently, neutron radiography is limited by spatial and temporal resolution, but developments in instrumentation are likely to improve this for in operando research. The spatial variation in discharge products across the bulk of a lithium–air electrode was reported using neutron tomography (Nanda et al., 2012). Neutron imaging finds a non-uniform lithium distribution across the electrode thickness, with a higher lithium concentration near the edges of the lithium–air electrode and a more uniform concentration at the centre, an observation attributed to polarization factors. Senyshyn et al. (2012) used neutron tomography to examine commercial lithium-ion cells of the 18650 type, an annular design where electrode layers are rolled around a central pin. This work revealed a pronounced contrast in the lithium distribution between the layers in the discharged state, attributed to inhomogeneities resulting from the significant amount of lithium situated inside the positive electrode, where the negative electrode (graphite) is nearly lithium free. During charge, this contrast vanished. Senyshyn et al. (2014) also used spatially resolved in operando diffraction in which a gauge volume was defined from which diffraction data were recorded, to probe these lithium distributions. Owejan, Gagliardo et al. (2012) achieved 14 µm spatial resolution in the neutron imaging of batteries using a specialist cell in which the lithium content during charge/discharge and the residual could be measured after each cycle. Changes in the lithium distribution in the battery during cycling and between cycles revealed differences between the lithium concentrations in the separator and current collector.

Another method of determining lithium concentration in materials is neutron depth profiling. Typically, the spatial resolution of neutron depth profiling for well defined homogeneous layers is tens of nanometres, with the main drawback being the limited depth that can be probed. Oudenhoven et al. (2012) showed for the first time that the evolution of the lithium distribution under dynamic conditions can be studied using neutron depth profiling. This was demonstrated in operando using a microbattery consisting of a thin-film solid-state stack. The differences between the neutron depth profiling data for the as-prepared electrode in the charged and discharged spectra directly revealed the changing lithium distribution.