Amorphous ice and liquid states of water

Water is the most important liquid for life on Earth. Although a water molecule is apparently simple, the hydrogen-bonded network keeping these molecules together and determining the many anomalous macroscopic properties of water, is still a puzzle.

Among different scenarios proposed to explain the anomalies in water, the most controversial issue is the hypothetical existence of two distinct liquid states: high- and low-density liquid (HDL, LDL). At ambient conditions the two structural components making up the two liquids fluctuate and cannot be studied as separate states. Rapid cooling of liquid water forms a low-density amorphous ice (LDA). High-density amorphous ice (HDA) can be made instead by pressure-induced amorphization of crystalline ice. A fascinating question arises: are the two amorphous ices the counterparts of the two proposed liquids states?

Modern X-ray scattering methods provide powerful tools to investigate both static structure and structural dynamics on different length- and timescales. Using X-rays, we have recently shown the diffusive character of HDL and LDL around their proposed glass transition temperatures at ambient pressure, but studies at elevated pressures are missing and challenging. With our current research we aim to develop new experimental in situ pathways to study amorphous ices and liquid water at elevated pressures.

Go to article about "Two liquids of water exist"

Figure illustrates a glass containing two water liquids that have different densities surrounded in a cold environment.

Research highlights:

Related publications:


This research is funded by the Ragnar Söderbergs Stiftelse as a Swedish Foundations' Starting Grant Fellow