FuelCellsWorks

The Fuel Cells and Hydrogen Joint Undertaking (FCH JU) stakeholders’ general assembly will take place on 26 and 27 October in Brussels, Belgium.

First organised in 2008 to mark the launch of the FCH JU, the stakeholders’ general assembly is an annual event designed to inform all interested parties about the activities of the FCH JU and acquire feedback for future planning of the programme. It is also a key platform for European and global stakeholders across sectors to come together to examine and assess the current position of this emerging industry.

The Stakeholders’ General Assembly 2009 is focused on:
- the progress of the FCH JU after its first year of operation and on forward planning of the research agenda;
- an analysis of the market, as well as the political developments affecting the commercialisation of fuel cell and hydrogen technologies.

For further information, please visit:
http://ec.europa.eu/research/fch/index_en.cfm?pg=sga2009

Hydrogen sits prominently at the top left corner of Mendeleev’s imposing periodic table of the elements. It is our most abundant element by far (more than 90% by number) and across the sciences hydrogen’s presence is ubiquitous. This is potently revealed in hydrogen’s role in the chemical combinations that form molecules, liquids, and solids and its proclivities for other elements, which result in stoichiometries largely guided by familiar bonding rules. The rules generally assume the elements have their standard valences (while acknowledging possible deeper complexity arising from the “nonvalence” electrons); but for “normal” conditions we should be able to anticipate how most simple molecules will form.

In a paper appearing in Physical Review Letters [1], Timothy Strobel, Maddury Somayazulu, and Russell Hemley at the Carnegie Institute in Washington, DC, in the US, present a phase diagram of a hydrogen-based compound under pressure that calls into question some of the rules of thumb guiding the bonding of hydrogen. They study the well-known industrial compound, silicon tetrahydride (silane, or SiH₄), mixed with H₂ and discover a new, well-ordered solid compound, SiH₄(H₂)₂, forming at pressures above ~7.5 GPa. The bonding of hydrogen in this compound is substantially weaker than other known hydrogen based compounds. And, given that SiH₄ consists of silicon, which typically will be associated with four covalent bonds, and hydrogen, which prefers one, we are certainly challenged to understand how SiH₄(H₂)₂ can be taking up so much hydrogen. Indeed, it is some 89% hydrogen. Moreover, the measurements of Strobel et al. suggest that we may now have at hand a system based on the simplest element in the periodic table, in which we can study not only a pressure induced metal-insulator transition, but also quantum diffusion and, potentially, superconductivity.

It should be emphasized that the group is not studying SiH₄+H₂ under what we might term “normal” conditions, since they are applying pressures of up to 35 GPa. By doing so, they compress the SiH₄+H₂ mixture into a new solid and a new chemical form which, as mentioned, does not have a bond arrangement that would usually be observed at atmospheric pressure. The H₂ covalent bond is typically viewed as robust and a source of the rich physics of its condensed state [2], but in SiH₄(H₂)₂ some of its bonds are significantly weaker than in other molecular compounds. The explanation for the large hydrogen content in SiH₄(H₂)₂ appears to be associated with the fact that the standard bonding states of hydrogen are actually vulnerable to significant modification when, under fairly dense conditions, an intruder such as silicon encroaches upon them, even in quite small amounts.

With x-ray diffraction, the group shows that the newly discovered SiH₄(H₂)₂ has a high-symmetry, face-centered-cubic (fcc) based structure (inset, Fig. 1). For ordered basis atoms, and assuming an independent electron picture, we know that twelve valence electrons (four from Si, eight from H) per crystallographic unit cell can then, in principle, fill six bands. This means SiH₄(H₂)₂ could also be an insulator, which in fact, it appears to be, at least at lower pressures. However, it is possible that the systematic increase in density under pressure would cause the bands to overlap and if so it is worth understanding more fully the nature of the “bonds” just prior to this overlap of bands.

We already know that pure, solid, hydrogen turns black under pressure—indicating that it is on its way to becoming a metal—but this only occurs under about tenfold compression, which requires in excess of 300 GPa in pressure [3]. It takes only about one tenth of this pressure to darken SiH₄ [4, 5, 6]. Similarly, Strobel et al. are finding that SiH₄(H₂)₂ also blackens in a comparable pressure range; but given that Si is embedded in a hydrogen environment at the level of just over 10 atomic percent, this finding indicates an average electron rearrangement that is both extensive and possibly quite subtle.

Hydrogen possesses no core (or nonvalence) electrons and so it, and many hydrogen-based compounds, occupy a somewhat special position in our efforts to understand electronic structure. The nuclei (protons for ¹H) usually take up time-average positions, which are almost invariably assumed fixed, and these critically reflect the time average charge densities taken up by the electrons. Optical experiments, such as the Raman effect, can probe the momentary departures from the average positions, and it then reveals information on the collective dynamics of the protons and hence the underlying structure. This is one technique Strobel et al. use to follow the structural progression in the SiH_n system as they change the pressure.

Hydrogen, as an isolated molecule H₂, is also a highly quantum system. The protons have zero-point energies equivalent to over 1000 K per proton and, as Strobel et al. have observed, the standard assumption of fixed average positions, so common in electronic structure calculations, actually seems to fail. The system they study is ideally suited to systematic deuteration [6], in this case through the addition of D₂ (i.e., ²H) to SiH₄ (rather than of H₂, i.e., ¹H). This allows them to check any role that nuclear mass might have on subsequent electron arrangement. Deuteration doubles the mass of hydrogen (and changes the fundamental quantum statistics) but does not change any of the basic underlying interactions. So, what do the data show? As the Raman spectrum in Fig. 1 reveals, instead of the H and D nuclei remaining quiescently at their “expected” and initial average sites, they literally exchange positions (see caption, Fig. 1). Similar behavior has recently been observed in another dense quantum solid, in fact one that again contains hydrogen [7].

These notably quantum characteristics may play an interesting role in the structural phase transition that occur when, by thermal means, high hydrides might be agitated sufficiently to take up liquid forms. In terms of hydrogen concentration the data so far are scant, but broadly consider how the hydrogen content may affect the melting point of various silicon compounds at one atmosphere: SiH₀ (i.e., pure silicon) melts at 1687 K, SiH₄ at 88 K, and SiH_∞ (i.e., pure hydrogen) at 14 K. Semiconducting SiH₀ forms a higher density metallic state on melting and, as might be expected from the Clausius-Clapeyron law, its melting point declines with pressure, in fact by close to 40% near 15 GPa. The present experiments, primarily with SiH₄(H₂)₂, or SiH₈, are already reaching 35 GPa, and the suggestion is that it may be illuminating to pursue structural studies to somewhat higher temperatures (and to even higher hydrogen concentration, for example, in SiH₁₂) in search of a corresponding fluid. For example, it could be especially revealing to find a sign of an extensive liquid metallic domain in a hydrogen-rich system. Further, if at constant pressure, a rapid decline in melting point as a function of increasing hydrogen concentration was to be observed, but to extremely low temperatures, it would indicate a progressive link beyond an initially eutectic form to the near ground-state quantum liquid metallic phase of hydrogen, which has already been mooted.

In addition to becoming metallic at moderate densities, SiH₄ has also been observed to then undergo a transition to a superconducting state [5] (interestingly the standard valence electron count of SiH₄ is identical to that of MgB₂ [6]). If the reported darkening of SiH₄(H₂)₂ happens also to presage the onset of a metallic state, we might surely ask if metallic SiH₄(H₂)₂ could also be a superconductor? If so, then deuteration experiments could again be helpful in determining whether the underlying mechanism for superconductivity is attributable to the familiar coupling of electrons to lattice dynamics. For this mechanism the superconducting transition temperature is generally expected to drop for a heavier isotope, but this is not what happens, for example, in the hydrogen bearing Pd-H system. Rather, in alloys of palladium-hydrogen (Pd-¹H), palladium-deuterium (Pd-²H), and even palladium-tritium (Pd-³H), the hydrogenic isotope effect is dramatically inverse [8]. This type of behavior has also been predicted to occur for superconductivity in pure metallic hydrogen [9].

At the length scales of interest to the condensed matter sciences, extended systems can be viewed as assemblies of positively charged nuclei embedded in neutralizing equivalents of much lighter but highly quantum and Fermionic electrons. At this level, all interactions are strictly Coulombic and, as Dirac showed 80 years ago [10], the fundamental quantum mechanical problem can be established exactly. All of the electrons are involved and the role of high-pressure physics has been to force those nominally “valence” electrons into the regions between the nuclei (and away from the cores with their locally spherical symmetry). Eventually, relentless increase of pressure can literally strip away the traditionally “nonvalence” electrons from the nuclei, as we know happens in stellar, and some planetary, interiors.

Solving the all-electron problem within the Born-Oppenheimer approximation (least well satisfied, as it turns out, for hydrogen) has involved an enormous level of effort since Dirac’s time, both in experimental and theoretical terms, and in the domains of chemistry, condensed matter physics, and elsewhere. The later notable advances in electronic density functional techniques and other electronic structure calculational methods actually allow us to ask whether stoichiometries and combinations of light element binaries other than those associated with common valences could in fact be predicted? This seems to be the case now, even for combinations of hydrogen with another Group I element [11], but it is clearly an area open for wider exploration.

Though perhaps fanciful when considered at the 140 year mark, we might wonder about Mendeleev’s further progress had he benefited from some very extensive additional data [12]. The properties and regularity of the elements in various compounds led, in part, to his ability to systematize them. But, of course, these regularities were observed at atmospheric pressures. Suppose Mendeleev had also been in command of similar data from combinations corresponding to, say, four- to fivefold condensed phase compressions? The appearance of different sequences of regularities in higher density compounds may have indicated electron distributions significantly altered from those at one atmosphere. More generally the concept of a precise valence, already known to fluctuate in some binary systems, might then begin to appear to be a low-density construct. With the ability of pressure to reduce average internuclear separations considerably, it leaves us with the question: In the end, will there be any rigorous difference between valence and core electrons as pressure inexorably drives systems towards plasma states, hydrogen being a prominent case [13]?

The paper from Strobel et al. demonstrates the critical ongoing importance of experiment in addressing these questions, even while acknowledging great strides made in electronic structure calculations. And the pressure variable is also seen to continue to hold very considerable promise in illuminating the electronic and structural physics of systems with ever increasing densities.

Acknowledgments

Support of the National Science Foundation under Grant DMR 09-0907425 is gratefully acknowledged.

Illustration: Alan Stonebraker, adapted from T. Strobel et al., Phys. Rev. Lett. (2009)

Figure 1: (Inset) The face-centered-cubic (fcc) based structure of the newly discovered compound SiH₄(H₂)₂, in which 8 out of 9 atoms are hydrogen. The blue spheres indicate SiH₄ units (which may not have definite orientations) and the red spheres represent H₂ pairs (with also as yet unknown orientational physics). (Raman spectrum, right) SiH₄(H₂)₂ at 8 GPa and an average electron density 50% greater than that of silane shows excitations characteristic of molecular hydrogen (H₂) and plausibly connected with the placement of the H₂ pairs. (Spectrum, left) The deuterated system SiH₄(D₂)₂ again shows excitations characteristic of the D₂ molecule. (Spectrum, middle) The presence of the mixed isotope pair HD means that there is time dependent migration of H from the blue regions into the red regions (and D can be migrated into the blue regions).

WASHINGTON, D.C.  - Congressman Mike Rogers and Congressman Spencer Bachus (AL-06) announced that Auburn University will receive $1.5 million for defense research work under the House version of the FY10 Defense Appropriations bill.

The university will use the funds for its logistical fuel processor program, which examines the use of fuel cells as a power source for military equipment.  The sophisticated communications, electronics, and related equipment now being used in combat situations depend on reliable power supplies.  The program’s goal is to help the army take commonly available diesel or jet fuels and use them in fuel cell systems that are smaller, lighter, less costly, and more energy-efficient than traditional combustion engines.

Congressman Rogers said, “Auburn is an institution on the cutting edge in fuel cell research for the military which could eventually translate to greater energy-efficiency for civilian use.  While we still have several steps to go in the legislative process, Congressman Bachus and I will work to ensure this important funding continues to receive strong support in Congress.”

Congressman Bachus said, “This technology, although developed for the military, could have widespread civilian application.  Domestically, such technology could ultimately lead to cleaner-burning, fuel efficient automobiles and trucks while at the same time reducing our dependence on foreign oil.”

The Director of Public Communications for Auburn University, Brian Keeter, said, “Innovations in fuel technology enhance the capabilities of the U.S. Army, and we appreciate the support Congressmen Bachus and Rogers provide to one of Auburn University’s top research programs.”

The defense measure was passed by the House yesterday.  Appropriations bills need the approval of the House and Senate and the President’s signature before becoming law.

AMHERST, Mass. – In their most recent experiments with Geobacter, the sediment-loving microbe whose hairlike filaments help it to produce electric current from mud and wastewater, Derek Lovley and colleagues at the University of Massachusetts Amherst supervised the evolution of a new strain that dramatically increases power output per cell and overall bulk power. It also works with a thinner biofilm than earlier strains, cutting the time to reach electricity-producing concentrations on the electrode.

“This new study shows that output can be boosted and it gives us good insights into what it will take to genetically select a higher-power organism.” The work, supported by the Office of Naval Research and the U.S. Department of Energy, is described in the August issue of the journal, Biosensors and Bioelectronics, now available online.

Findings open the door to improved microbial fuel cell architecture and should lead to “new applications that extend well beyond extracting electricity from mud,” Lovley says. In the new experiments, the UMass Amherst researchers adapted the microbe’s environment, which pushed it to adapt more efficient electric current transfer methods.

“In very short order we increased the power output by eight-fold, as a conservative estimate,” says Lovley. “With this, we’ve broken through the plateau in power production that’s been holding us back in recent years.” Now, planning can move forward to design microbial fuel cells that convert waste water and renewable biomass to electricity, treat a single home’s waste while producing localized power (especially attractive in developing countries), power mobile electronics, vehicles and implanted medical devices, and drive bioremediation of contaminated environments.

Geobacter’s hairlike pili are extremely fine, only 3 to 5 nanometers in diameter or about 20,000 times finer than a human hair, and more than a thousand times longer than they are wide. Nevertheless, they are strong. Nicknamed nanowires for their role in moving electrons, pili are the secret to this particular microbe’s ability to produce electric current from organic waste and sediment. Geobacter’s pili seem critical for forming the biofilm which aids transfer of the electron products to iron in soil and sediment. In nature, bacteria colonies form gluey biofilms to anchor to a surface such as a tooth or an underwater rock, providing a living environment near a food source.

The Geobacter biofilm’s “fortuitous” electron-transferring skill, the product of natural selection, suggested a pathway to Lovley―a way he might use selective pressure to increase its capacity to produce power. He and colleagues grew Geobacter as usual on a graphite electrode, providing acetate as food and allowing a colony to form the biologically active slime, or biofilm where electron transfer takes place across the nanowires. But for this new experiment they added a tiny, 400-millivolt “pushback” current in the electrode that forced Geobacter to press harder to get rid of its electrons.

The result of providing a more challenging environment, within five short months, Lovley notes, was evolution of a beefed-up microorganism that can press at least eight times more electric current across the electrode than the original strain. “I’m really happy with this outcome,” the microbiologist notes. “It’s exceptionally fast feedback to us and a very satisfying result.” He adds, “I’m still a little amazed that they make electricity, but I’m happy to be exploring how to harness that ability. I’m sure there’ll be applications developed in the future that we can’t even envision right now.”

Lovley’s first experiments with the anaerobic microbe, Geobacter, which he and colleagues discovered in sediment under the Potomac River in 1987, explored its use in decontaminating soil due to its ability to respire iron and other metals the way we breathe oxygen. Geobacter showed promise for a variety of bioremediation tasks, but the microbiologists further discovered in 2002 that it could produce electricity from the organic matter found in soils, sediments and wastewater. This ability appeared to be a feature of the electrically conductive pili, discovered in 2005. Together, these discoveries have led to intense research on how to harness the microbes for producing electricity in microbial fuel cells.

Microbial fuel cells, which convert fuel to electricity without combustion, consist of an electrode known as an anode that accepts electrons from the microorganisms, and another electrode known as a cathode, which transfers electrons onto oxygen. Electrons flow between the anode and the cathode to provide the current that can be harvested to power electronic devices.