Hydrogen/Fuel Ammonia

Hydrogen

Hydrogen does not emit CO₂ when burned. Furthermore, it can be created using a wide variety of techniques, such as by the electrolysis of water or by steam reforming. Consequently, it is attracting attention as a next-generation clean energy source.

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Quantitation of Hydrogen and Methane Dissolved in Hexanes, Toluene and Water

The amount of gases dissolved in a liquid solution may alter the functionality of the solution and affect the stability and reactivity of other dissolved components.
This article introduces analysis of hydrogen and methane in hexanes, toluene and water using the Shimadzu BID-2030

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Ammonia Fuel

Ammonia is attracting attention as a carbon-free energy source that does not emit CO₂ when burned. It is also expected to serve as a carrier for hydrogen energy.

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High-Sensitivity Analysis of Ammonia, Methylamine, and Trimethylamine in Environmental and Energy Fields

The dielectric barrier discharge ionization detector (BID) permits detection of nearly all compounds, except for helium and neon, at higher sensitivity than that possible with TCD and FID detectors. Here, we introduce examples of analysis at the ppm level of ammonia and methylamine in water, and of trimethylamine in water by GC-BID.

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Measurement of TOC in Ammonia Solution by TOC-VCSH

Photocatalysts and Artificial Photosynthesis

Artificial photosynthesis is a technology that uses a photocatalyst and sunlight to perform photosynthesis artificially. It can convert light energy into useful compounds and is expected to be used as a next-generation renewable energy source.

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Photocatalysts and Artificial Photosynthesis

This describes relevant Shimadzu analytical instruments and analysis examples from the photocatalyst and artificial photosynthesis fields. Examples of using a spectrophotometer, GC, or GCMS system to analyze or characterize reaction products are introduced.

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Hydrogen (H₂)-based steelmaking

About 14 % of Japan’s CO₂ emissions comes from the steel industry, making it one of the main sources of CO₂ emissions. Therefore, reducing the CO₂ emissions from steel production is very important. Hydrogen reduction steel manufacturing uses hydrogen gas as a reducing agent instead of coke to remove the oxygen from iron ore by binding it with hydrogen and emitting it as H₂O (water).

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State Analysis of Iron Oxide Scale

Removal of the oxidized scale that forms on the surface of steel products has a large influence on the surface properties of the products, research and development have been conducted to clarify the relationship between the growth rate of oxidized scale and the surface properties, high temperature adhesion, and the peelability of the scale.

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Simultaneous Analysis of Trace and Major Elements in Iron and Steel by ICPE-9820

Applicable Products

Measurement of Quantum Yield from Photocatalytic Carbon Dioxide Reduction Reactions

PQY-01 Photoreaction Evaluation System
Lightway
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Analysis of CO Generated from CO₂ Reduction Reactions

Gas Chromatograph
Nexis GC-2030
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High-Resolution Analysis of Various Gases

Fourier Transform Infrared Spectrophotometer
IRXross
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Measurement of Titanium Oxide Particle Size

$Laser Diffraction Particle Size Analyzer SALD-2300$
Laser Diffraction Particle Size Analyzer
SALD-2300
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Analysis of State of Oxidized Scale Generated on Steel Surfaces

Electron Probe Microanalyzer
EPMA-8050G
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Visualization of Photoinduced Charge Distribution

Scanning Probe Microscope/Atomic Force Microscope
SPM-Nanoa
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