Water is more homogeneous than expected

Water molecules are excited with X-ray light (blue). From the emitted light (purple) information on H-bonds can be obtained.

Water molecules are excited with X-ray light (blue). From the emitted light (purple) information on H-bonds can be obtained. © T. Splettstoesser/HZB

In order to explain the known anomalies in water, some researchers assume that water consists of a mixture of two phases even under ambient conditions. However, new X-ray spectroscopic analyses at BESSY II, ESRF and Swiss Light Source show that this is not the case. At room temperature and normal pressure, the water molecules form a fluctuating network with an average of 1.74 ± 2.1% donor and acceptor hydrogen bridge bonds per molecule each, allowing tetrahedral coordination between close neighbours.

Water at ambient conditions is the matrix of life and chemistry and behaves anomalously in many of its properties. Since Wilhelm Conrad Röntgen, two distinct separate phases have been argued to coexist in liquid water, competing with the other view of a single-phase liquid in a fluctuating hydrogen bonding network – the continuous distribution model. Over time, X-ray spectroscopic methods have repeatedly been interpreted in support of Röntgen’s postulate.

Three lightsources involved

An international team of researchers, led in their effort by Prof. A. Föhlisch from Helmholtz-Zentrum Berlin and the University of Potsdam, conducted quantitative and high-resolution X-ray spectroscopic multi-method investigations and analysis to address these diverging views at the light sources BESSY II, European Synchrotron Radiation Facility ESRF and Swiss Light Source.

Result: tetrahedral coordination

They establish that the X-ray spectroscopic observables can be fully and consistently described with continuous distribution models of near-tetrahedral liquid water at ambient conditions with 1.74 ± 2.1% donated and accepted H-bonds per molecule. In addition, across the full phase diagram of water, clear correlations to e.g. second shell coordination is established and the influence of ultrafast dynamics associated with X-ray matter interaction is separated and quantified.

Continous distribution model holds true

Can these X-ray spectroscopic conclusions on water at ambient conditions now also resolve the heavily debated question of the existence of a second critical point in the so-called "no man’s land" of supercooled water? This postulated second critical point is conceptually based on the extension of the established low- and high-density amorphous ice phases into purported low- and high-density liquid phases along a Widom line where the second critical point is found as the extrapolated divergence of stable and supercooled water‘s thermodynamic response functions around -45°C at atmospheric pressure.

From the physics of critical fluctuations, it is known, that well above a critical point one should view the state of matter as homogeneous. Incipient and large fluctuations are allowed as one approaches closely the phase boundary and the critical point: How close one has to approach it in energy and on what time scale to sense the divergence is not fully answered, but expectations from observations in solid state physics are that you have to be close to realize the 2-phase effects.

Even if the purported second critical point at -45°C and ambient pressure existed, the ambient conditions of liquid water in equilibrium would be by any means far away in temperature. Thus, the fluctuating continuous distribution model of near-tetrahedral liquid water at ambient conditions holds true independent of whether the second critical point of water in the supercooled region exists or not.

Text by Alexander Föhlisch

The study is published in the Proceedings der National Academy of Science, PNAS 2019: Compatibility of quantitative X-ray spectroscopy with continuous distribution models of water at ambient conditions. Johannes Niskanen, Mattis Fondell, Sebastian Eckert, Raphael M. Jay, Annette Pietzsch, Vinicius Vaz da Cruz, Alexander Föhlisch

DOI: 10.1073/pnas.1815701116

 

arö

  • Copy link

You might also be interested in

  • Optical innovations for solar modules - which are the most promising?
    Science Highlight
    28.03.2025
    Optical innovations for solar modules - which are the most promising?
    In 2023, photovoltaic systems generated more than 5% of the world’s electrical energy and the installed capacity doubles every two to three years. Optical technologies can further increase the efficiency of solar modules and open up new applications, such as coloured solar modules for facades. Now, 27 experts provide a comprehensive overview of the state of research and assess the most promising innovations. The report, which is also of interest to stakeholders in funding and science management, was coordinated by HZB scientists Prof. Christiane Becker and Dr. Klaus Jäger.
  • Catalysis research with the X-ray microscope at BESSY II
    Science Highlight
    27.03.2025
    Catalysis research with the X-ray microscope at BESSY II
    Contrary to what we learned at school, some catalysts do change during the reaction: for example, certain electrocatalysts can change their structure and composition during the reaction when an electric field is applied. The X-ray microscope TXM at BESSY II in Berlin is a unique tool for studying such changes in detail. The results help to develop innovative catalysts for a wide range of applications. One example was recently published in Nature Materials. It involved the synthesis of ammonia from waste nitrates.
  • BESSY II: Magnetic ‘microflowers’ enhance magnetic fields locally
    Science Highlight
    25.03.2025
    BESSY II: Magnetic ‘microflowers’ enhance magnetic fields locally
    A flower-shaped structure only a few micrometres in size made of a nickel-iron alloy can concentrate and locally enhance magnetic fields. The size of the effect can be controlled by varying the geometry and number of 'petals'. This magnetic metamaterial developed by Dr Anna Palau's group at the Institut de Ciencia de Materials de Barcelona (ICMAB) in collaboration with her partners of the CHIST-ERA MetaMagIC project, has now been studied at BESSY II in collaboration with Dr Sergio Valencia. Such a device can be used to increase the sensitivity of magnetic sensors, to reduce the energy required for creating local magnetic fields, but also, at the PEEM experimental station, to study samples under much higher magnetic fields than currently possible.