An infrared imaging method for high-throughput combinatorial investigation of hydrogenation-dehydrogenation and new phase formation of thin films

Oguchi, Hiroyuki; Hattrick‐Simpers, Jason; Takeuchi, Ichiro; Heilweil, Edwin J.; Bendersky, Leonid A.

doi:10.1063/1.3184024

Cited by 14 publications

(16 citation statements)

References 49 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…It was further demonstrated that this technique could be used to monitor metal to semiconductor, as well as metal to metal transformations; this finding is important since many hydrogen storage materials can exhibit multiple decomposition steps, and not all of the products are insulating. 313,320 CCS libraries of hydrogen storage materials enable measurement of the thermodynamic properties, but to determine reaction kinetics, it is useful to employ thickness wedge libraries, where the importance of grain size on the reaction rates can be studied. Materials such as MgH 2 strongly inhibit the diffusion of hydrogen, and thus present a substantial barrier to efficient hydrogenation.…”

Section: Thin Film Combinatorial Workmentioning

confidence: 99%

Applications of high throughput (combinatorial) methodologies to electronic, magnetic, optical, and energy-related materials

Green

Takeuchi

Hattrick‐Simpers

2013

Journal of Applied Physics

223

189

View full text Add to dashboard Cite

High throughput (combinatorial) materials science methodology is a relatively new research paradigm that offers the promise of rapid and efficient materials screening, optimization, and discovery. The paradigm started in the pharmaceutical industry but was rapidly adopted to accelerate materials research in a wide variety of areas. High throughput experiments are characterized by synthesis of a "library" sample that contains the materials variation of interest (typically composition), and rapid and localized measurement schemes that result in massive data sets. Because the data are collected at the same time on the same "library" sample, they can be highly uniform with respect to fixed processing parameters. This article critically reviews the literature pertaining to applications of combinatorial materials science for electronic, magnetic, optical, and energy-related materials. It is expected that high throughput methodologies will facilitate commercialization of novel materials for these critically important applications. Despite the overwhelming evidence presented in this paper that high throughput studies can effectively inform commercial practice, in our perception, it remains an underutilized research and development tool. Part of this perception may be due to the inaccessibility of proprietary industrial research and development practices, but clearly the initial cost and availability of high throughput laboratory equipment plays a role. Combinatorial materials science has traditionally been focused on materials discovery, screening, and optimization to combat the extremely high cost and long development times for new materials and their introduction into commerce. Going forward, combinatorial materials science will also be driven by other needs such as materials substitution and experimental verification of materials properties predicted by modeling and simulation, which have recently received much attention with the advent of the Materials Genome Initiative. Thus, the challenge for combinatorial methodology will be the effective coupling of synthesis, characterization and theory, and the ability to rapidly manage large amounts of data in a variety of formats. V C 2013 AIP Publishing LLC. [http://dx

show abstract

Section: Thin Film Combinatorial Workmentioning

confidence: 99%

Applications of high throughput (combinatorial) methodologies to electronic, magnetic, optical, and energy-related materials

Green

Takeuchi

Hattrick‐Simpers

2013

Journal of Applied Physics

223

189

View full text Add to dashboard Cite

show abstract

“…In recent years normalized infrared (IR) emissivity imaging has been revealed to be a potent characterization tool for studying hydrogen storage in thin films [1,2]. In this measurement technique IR images of a thin film and of a hydrogen-inert reference material are recorded with an IR camera simultaneously during hydrogenation experiments.…”

Section: Introductionmentioning

confidence: 99%

Observation of phase transitions in hydrogenated Yttrium films via normalized infrared emissivity

Hattrick‐Simpers

Wang

Cao

et al. 2010

Journal of Alloys and Compounds

View full text Add to dashboard Cite

“…The NIRE system used here has been described in detail in a previous publication [12]. Briefly, the films were measured in a specially designed hydrogenation chamber fitted with a sapphire window.…”

Section: Methodsmentioning

confidence: 99%

A combinatorial characterization scheme for high-throughput investigations of hydrogen storage materials

Hattrick‐Simpers

Tan

Oguchi

et al. 2011

Science and Technology of Advanced Materials

View full text Add to dashboard Cite

In order to increase measurement throughput, a characterization scheme has been developed that accurately measures the hydrogen storage properties of materials in quantities ranging from 10 ng to 1 g. Initial identification of promising materials is realized by rapidly screening thin-film composition spread and thickness wedge samples using normalized IR emissivity imaging. The hydrogen storage properties of promising samples are confirmed through measurements on single-composition films with high-sensitivity (resolution <0.3 µg) Sievert's-type apparatus. For selected samples, larger quantities of up to ∼100 mg may be prepared and their (de)hydrogenation and micro-structural properties probed via parallel in situ Raman spectroscopy. Final confirmation of the hydrogen storage properties is obtained on ∼1 g powder samples using a combined Raman spectroscopy/Sievert's apparatus.

show abstract

An infrared imaging method for high-throughput combinatorial investigation of hydrogenation-dehydrogenation and new phase formation of thin films

Cited by 14 publications

References 49 publications

Applications of high throughput (combinatorial) methodologies to electronic, magnetic, optical, and energy-related materials

Applications of high throughput (combinatorial) methodologies to electronic, magnetic, optical, and energy-related materials

Observation of phase transitions in hydrogenated Yttrium films via normalized infrared emissivity

A combinatorial characterization scheme for high-throughput investigations of hydrogen storage materials

Contact Info

Product

Resources

About