Dalton Transactions Blog

Carbon-modified zinc nanorod array has impoved sensing ability

Chinese scientists have developed a highly efficient and chemically stable hydrazine sensor using carbon modified zinc oxide nanorods.  Hydrazine is highly neurotoxic and carcinogenic and can cause severe damage to the liver, lungs and kidneys.  It is used extensively in industry, and for safety considerations a reliable hydrazine sensor is highly desirable.

To find out why this new sensor is special, read Jacob Bush’s news article at Highlights in Chemical Science or access the full article:

http://dx.doi.org/10.1039/c0DT00258e nanorod array-based hydrazine electrochemical sensor with improved sensitivity and stability
Jinping Liu, Yuanyuan Li, Jian Jiang and Xintang Huang, Dalton Trans., 2010, Advance Article
DOI: 10.1039/C0DT00258E

A robust catalyst that produces hydrogen from ammonia-boranes with high efficiency under atmospheric conditions has been developed by Spanish scientists.

The search for new energy sources to substitute depleting fossil fuels and decrease greenhouse gas emissions is a high priority. One of the best pollution-free alternatives to coal and oil is hydrogen However; a different and very important concern arises with using hydrogen: safety.

Incorporating hydrogen into chemical compounds, such as ammonia-borane (NH₃BH₃), that can store and release it in a controlled manner could be a way of overcoming safety issues. Catalysts based on metals including titanium, ruthenium or rhodium can efficiently release up to one equivalent of hydrogen gas, but it must be carried out under an inert atmosphere.

3 equivalents of hydrogen are released from the ammonia-borane store

Now Maria Angeles Garralda and her team at University of Pais Vasco in Spain have demonstrated the first homogenous catalysis reaction using an iridium catalyst for hydrolysing ammonia-boranes, which produces up to three equivalents of hydrogen in a very efficient reaction. As well as being more efficient than previous systems, the iridium catalyst has the added advantage that it is stable in water and air, so does not require an inert atmosphere.

‘The fact that this system was not active under anhydrous conditions and was, however, extremely efficient and stable in the presence of water was very surprising,’ says Maria Angeles Garralda. ‘The great stability in the presence of air and water and the great activity of this homogeneous catalyst will help to understand the mechanisms of hydrogen production’.

The understanding of the mechanism of this type of reactions is vital for the future development of more efficient and cheaper catalysts to generate hydrogen in fuel cells.

‘This homogenous catalytic system suggests that finer control over rate and product distribution might be possible in the future,’ points out Andrew Weller, an expert on organometallic chemistry and catalysis at University of Oxford, UK. ‘Ultimately, energy efficient re-hydrogenation strategies and cheaper, long-lived, immobilised catalysts are key targets; and research such as presented here suggests new avenues by which the latter of these goals might be achieved.’

Lorena Tomas Laudo

A hydridoirida-Β-diketone as an efficient and robust homogeneous catalyst for the hydrolysis of ammonia–borane or amine–borane adducts in air to produce hydrogen
Roberto Ciganda, María A. Garralda, Lourdes Ibarlucea, Elena Pinilla and M. Rosario Torres, Dalton Trans., 2010
DOI: 10.1039/c0dt00091d

New Hot article published describing new insights into the mechanism of enzymatic activation of dioxygen by metal active sites, elucidated by high-pressure experiments:

Reinvestigation of the formation of a mononuclear Fe(III) hydroperoxido complex using high pressure kinetics
Thomas Nebe, Alexander Beitat, Christian Würtele, Carlos Dücker-Benfer, Rudi van Eldik, Christine J. McKenzie and Siegfried Schindler,  Dalton Trans., 2010
DOI: 10.1039/c0dt00247j

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