"Phosphoric acid is vital in both biology and modern technology because of its exceptional ability to move electrical charge. Inside the human body and in devices such as fuel cells, this small molecule helps drive essential chemical reactions.
Scientists at the Department of Molecular Physics at the Fritz Haber
Every second, countless electrical charges flow through our bodies. These signals are essential for life. Processes such as
--cellular communication,
--energy conversion,
--and metabolism all rely on the carefully controlled movement of charged particles across membranes and within cells. In many ways, the transport of charge serves as a fundamental regulatory system.
Phosphoric acid (H3PO4) and related phosphate compounds are found throughout living organisms. They form the backbone of DNA and RNA, contribute to the structure of cell membranes, and are part of ATP, the molecule that stores and delivers energy in cells. These compounds are especially important for moving positive charges in biological systems.
Beyond biology, phosphoric acid also plays a significant technological role. It is used in certain types of batteries and in fuel cells. In these systems, engineers take advantage of one standout feature: its unusually high proton conductivity.
Protons carry a positive charge and can move through phosphate-containing materials in a stepwise fashion. They “jump” from one molecule to the next along networks of hydrogen bonds. This process, known as “proton-shuttling”, enables charges to travel extremely quickly.
Earlier research suggested that a specific negatively charged form of phosphoric acid could act as the starting point for the proton-shuttling sequence. This species is the deprotonated dimer
When the researchers compared their measurements with theoretical predictions, they found only partial agreement. Computational models had suggested that two structural forms should be equally likely. However, the experimental results clearly showed that the deprotonated phosphoric acid dimer adopts a single stable structure.
This structure is relatively rigid and presents high energy barriers for proton transfer. It contains three hydrogen bonds and features a shared oxygen atom that serves as an acceptor. Similar arrangements have been observed in other phosphoric acid-containing clusters, indicating that this hydrogen-bonding pattern may be common in such systems.
The study offers new insight into the molecular basis of phosphoric acid’s remarkable proton conductivity, “Nature’s proton highway.” By identifying a single stable structure for the key anionic dimer H3PO4·H2PO4- and revealing its distinct hydrogen-bonding motif, the researchers have clarified an important piece of the proton transport puzzle."
SciTechDaily
