# 科学家发现液态水中两种结构的分子级证据

- 来源：Hacker News 热门（buzzing.cc 中文翻译）
- 作者：wglb
- 发布时间：2026-06-30 15:38
- AIHOT 分数：17
- AIHOT 链接：https://aihot.virxact.com/items/cmr0d5hc900sbslol8k75aj7j
- 原文链接：https://phys.org/news/2026-06-scientists-molecular-evidence-liquid.html

## AI 摘要

一项6月25日发表于《自然·物理学》的研究，通过分子动力学模拟和无监督深度学习，为液态水的“二态模型”提供了分子级证据。研究使用自动编码器分析水分子局部构型，在不预设条件下识别出两种微观结构：密度更高、更无序的结构A与密度更低、更有序的结构B。两种结构在宽温压范围内（包括近室温）均存在。该结果支持水在深过冷区存在液-液相变和第二临界点的假说，有助于解释水在4°C密度最大等反常现象。

## 正文

June 25, 2026 feature

Scientists find molecular-level evidence for two structures in liquid water

by Tejasri Gururaj, Phys.org

edited by Gaby Clark, reviewed by Robert Egan

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Evidence of two local structures in liquid water. Credit: Nature Physics (2026). DOI: 10.1038/s41567-026-03301-8

A study published in Nature Physics provides new molecular-level evidence from simulations that liquid water is not a single uniform substance, but a constantly shifting mixture of two distinct microscopic structures.

The idea that water might exist in two distinct structural states is not new. For decades, scientists have theorized that liquid water is composed of two interconvertible local structures—one denser and more disordered, the other less dense and more ordered.

This "two-state model" has been invoked to explain water's many anomalous properties, including why it becomes easier to compress as it cools and why it reaches maximum density at 4°C (39°F) rather than at its freezing point. But the model has remained controversial because direct molecular-level evidence for the two structures has been elusive.

Phys.org spoke to corresponding author Prof. Xiao Cheng Zeng from City University of Hong Kong about the study and its findings.

"I have been very interested in the topic of phase transitions since I was a graduate student," said Zeng. "I started theoretical research on freezing of liquids when I was a postdoc, but I was always hoping to study freezing of water one day. Since then, I have been particularly interested in the topic of liquid-liquid transition in water."

Yet despite decades of theoretical work, direct molecular-level evidence for the two structures has remained out of reach.

Rotational perspective of a 3D plot of probability distributions P(ρlocal, PCI, PCII) of water local structures at 1,800 bar/188 K. Credit: Nature Physics (2026). DOI: 10.1038/s41567-026-03301-8

Molecular-level proof

Central to the two-state model is a hypothesized phenomenon known as the liquid-liquid phase transition (LLPT). The idea is that in the deeply supercooled regime, water splits into two macroscopically distinct liquid phases: a high-density liquid and a low-density liquid.

The boundary between them is thought to terminate at a "second critical point." This deeply supercooled region is so hard to study experimentally because water crystallizes rapidly. Much of the evidence for the LLPT has therefore come from computational studies.

Previously, a 2025 Nature Physics study made progress by using a deep neural network to map the location of this critical point.

"According to the two-state hypothesis, liquid water can be viewed as a mixture of two distinct structures, A and B. But no one has ever seen a genuine 'pure A' or 'pure B' liquid water. Indeed, due to the lack of direct molecular-level evidence, this model has been a subject of debate," said Zeng.

The problem is not just experimental, according to the researchers. Even in simulations, traditional methods that measure local density and energy differences between molecules failed to cleanly separate the two structures. What was needed was a way to let the data reveal the hidden molecular fingerprint of each structure—without any human assumptions about what that fingerprint should look like.

Left: dynamic evolution of a 3D probability distribution P(ρlocal, PCI, PCII) of water local structures during LLPT. Right: time evolution of average local density (ρsystem) in an MD simulation at 1,800 bar/188 K. Credit: Nature Physics (2026). DOI: 10.1038/s41567-026-03301-8

Unsupervised learning

To find this fingerprint, the team turned to an unsupervised deep learning approach—one that could extract hidden structural information from the data without any predefined assumptions about what the two structures should look like.

"It is practically impossible for humans to intuitively guess or manually construct such complex, nonlinear, and nearly orthogonal physical parameters," said Zeng. "We need AI's help to learn and [then] uncover these hidden physical characteristics."

The model was trained on approximately 74 million local water-molecule configurations drawn from massive molecular dynamics simulations using the TIP4P/Ice water model. This is a widely used and accurate computational model of water across a broad range of temperatures and pressures. Roughly 17% of the training data came from the liquid-liquid phase transition region, while the rest came from outside it to ensure the model learned from diverse conditions.

The architecture was an autoencoder. The encoder took the local structure of each water molecule as input and learned to predict two physically meaningful quantities: local density and local potential energy. The decoder then took these outputs and searched for hidden physical characteristics, mathematical values the model assigned to each molecule that went beyond what density and energy alone could capture.

To guide this search without introducing bias, the researchers set two loose mathematical constraints. Alpha controlled the linear correlation of the hidden characteristic with local density, and phi controlled the geometric angle of that relationship.

By systematically varying these, they effectively rotated their viewing angle of the data, searching for the configuration at which the two structures—if they existed—would reveal themselves most clearly.

Two structures and interconversion

When the model found the optimal configuration, two distinct clusters emerged, suggesting two local structures: Structure A, denser and more disordered, and Structure B, less dense and more ordered. The simulations found these patterns across a broad range of temperatures and pressures, including some close to room-temperature conditions.

Typical reaction (A ⇌ B) pathways in several regions of the P/T phase diagram. Credit: L. Li et al./Nature Physics. https://doi.org/10.1038/s41567-026-03301-8.

But the study revealed something beyond support for the existence of the two structures. The way Structure A and Structure B interconvert depends on where the system sits in the phase diagram. In the high-density liquid phase, the interconversion proceeds via an "upper semi-loop" pathway through a single transition state. In the low-density liquid phase, it follows a different "lower semi-loop" pathway through a different transition state.

Near the liquid-liquid phase boundary, where the two liquid phases compete most intensely, these two pathways combine into a complex three-dimensional "full-loop" reaction pathway involving three transition states. As the system moves away from the boundary and one phase begins to dominate, this full loop degenerates back into a simpler single-pathway semi-loop.

"The transformation between Structure A and Structure B is not a simple 'back-and-forth' process," said Zeng. "The interconversion pathways of the two structures are different under different states of water. This microscopic dynamic process is extremely difficult to identify using traditional theoretical methods."

Future work

The findings provide strong molecular-level evidence for the two-state model of water, with the bimodal feature in the data offering a structural signature of the two distinct local states. But questions remain.

"A crucial immediate step is to decode the physical interpretability of the two hidden physical characteristics revealed by the AI, and to seek their experimental verification," said Zeng.

Beyond fundamental physics, the researchers suggest the findings could have broader implications, from understanding how water behaves in biological cells and membranes to shedding light on geological processes in confined environments.

Written for you by our author Tejasri Gururaj, edited by Gaby Clark, and fact-checked and reviewed by Robert Egan—this article is the result of careful human work. We rely on readers like you to keep independent science journalism alive. If this reporting matters to you, please consider a donation (especially monthly). You'll get an ad-free account as a thank-you.

Publication details

Liwen Li et al, Evidence for the generic existence of two local structures in liquid water, Nature Physics (2026). DOI: 10.1038/s41567-026-03301-8.

Journal information: Nature Physics

Key concepts

Phase transitionsStructural propertiesClassical fluidsMolecular dynamics

Who's behind this story?

Tejasri Gururaj

Freelance science writer with MS in Physics. Explores diverse scientific disciplines through research-driven writing. Full profile →

Gaby Clark

MA in English, copy editor since 2021 with experience in higher education and health content. Dedicated to trustworthy science news. Full profile →

Robert Egan

Bachelor's in mathematical biology, Master's in creative writing. Well-traveled with unique perspectives on science and language. Full profile →

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Citation: Scientists find molecular-level evidence for two structures in liquid water (2026, June 25) retrieved 30 June 2026 from https://phys.org/news/2026-06-scientists-molecular-evidence-liquid.html

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