Multifunctional 3D nanoarchitectures for energy storage and conversion.

The design and fabrication of three-dimensional multifunctional architectures from the appropriate nanoscale building blocks, including the strategic use of void space and deliberate disorder as design components, permits a re-examination of devices that produce or store energy as discussed in this critical review. The appropriate electronic, ionic, and electrochemical requirements for such devices may now be assembled into nanoarchitectures on the bench-top through the synthesis of low density, ultraporous nanoarchitectures that meld high surface area for heterogeneous reactions with a continuous, porous network for rapid molecular flux. Such nanoarchitectures amplify the nature of electrified interfaces and challenge the standard ways in which electrochemically active materials are both understood and used for energy storage.

Imaging the morphology of solvent-free prepared MALDI samples.

Matrix-assisted laser desorption/ionization (MALDI) mass spectrometry is an important technique to characterize many different materials, including synthetic polymers. MALDI mass spectral data can be used to determine the polymer average molecular weights, repeat units, and end groups. The development of solvent-free sample preparation methods has enabled MALDI to analyze insoluble materials and, interestingly, can provide higher-quality mass spectral data.

Nanoscale conductivity mapping of hybrid nanoarchitectures: ultrathin poly(o-phenylenediamine) on mesoporous manganese oxide ambigels.

We use conductive-probe atomic force microscopy (CP-AFM) to characterize and image hybrid electrode structures comprising mesoporous manganese oxide (MnO2) ambigel nanoarchitectures coated with an ultrathin (<10 nm) electrodeposited layer of poly(o-phenylenediamine), PPD. Native MnO2 ambigel films, supported on indium tin oxide (ITO) substrates, exhibit spatially uniform conductivity that correlates well with the topography of the MnO2 film, confirming that the nanoscopic oxide network is effectively wired to the underlying ITO substrate. Following the self-limiting electrodeposition of the PPD coating onto the high-surface-area (>200 m2 g(-1)) MnO2 ambigel, the resulting hybrid structures display an approximately 20-fold reduction in conductivity, as determined from CP-AFM measurements.

Spatially resolved imaging of inhomogeneous charge transfer behavior in polymorphous molybdenum oxide. II. Correlation of localized coloration/insertion properties using spectroelectrochemical microscopy.

A newly developed spectroelectrochemical imaging approach for directly assessing lithium ion insertion energetics and kinetics in mixed-phase, polymorphous MoO3 is reported. Two variants of spectroelectrochemical microscopy were used to monitor insertion dynamics and to follow electrochemically induced phase transformations at specifically identified structural and compositional domains. Cyclovoltoabsorptometric (dOD/dE) measurements carried out in LiClO4/propylene carbonate solutions reveal that the lithium insertion is nonuniform and can be directly correlated with phase-segregated domains comprising alpha-MoO3, beta-MoO3, and intermixed alpha-/beta-MoO3.

Spatially resolved imaging of inhomogeneous charge transfer behavior in polymorphous molybdenum oxide. I. Correlation of localized structural, electronic, and chemical properties using conductive probe atomic force microscopy and Raman microprobe spectroscopy.

A detailed study of electrochemically deposited molybdenum oxide thin films has been carried out after they were sintered at 250 degrees C. Conductive probe atomic force microscopy (CP-AFM), Raman microscopy, and X-ray photoelectron spectroscopy (XPS) techniques were employed to assess the complex structural, electronic, and compositional properties of these films. Spatially resolved Raman microprobe spectroscopy studies reveal that sintered molybdenum oxide is polymorphous and phase segregated with three types of domains observed comprising orthorhombic alpha-MoO3, monoclinic beta-MoO3, and intermixed alpha-/beta-MoO3.

Spatially resolved measurement of inhomogeneous electrocoloration/insertion in polycrystalline molybdenum oxide thin films via chronoabsorptometric imaging.

A new integrated electrochemical and transmission optical microscopy approach is presented which allows for elucidation of inhomogeneous ion/charge-transfer behavior in polycrystalline electrochromic/insertion materials. Spatially resolved Li+ diffusion coefficients and ionic conductivities are determined from the time-lapsed optical density imaging response monitored during electrochemical potential-step perturbation. Non-uniform coloration changes and dispersed insertion kinetics are observed and associated with domain specific reactivity of polymorphous materials comprising alpha-MoO3 and beta-MoO3.