铁酸盐
纳米颗粒
矿物
微晶
水溶液
化学工程
化学
碳纤维
材料科学
纳米尺度
盐(化学)
溶解
粒子(生态学)
冰的形成
氢
分解
矿物学
冰晶
化学反应
纳米技术
转化(遗传学)
作者
Tao Luo,Tao Chen,Tra My Bui Thi,James A. Behan,Crispin Hetherington,Khalil Hanna,Jean‐François Boily
出处
期刊:Science
[American Association for the Advancement of Science]
日期:2026-07-09
卷期号:393 (6807): 212-216
被引量:1
标识
DOI:10.1126/science.aee9519
摘要
Polycrystalline ice formation concentrates mineral nanoparticles into liquid boundaries between growing ice crystals. Here we show that minutes of freezing dictate iron mineral fate over subsequent months of aqueous aging. A single freeze-thaw cycle irreversibly aggregates ferrihydrite through converging physical and chemical mechanisms. Freeze concentration collapses electrostatic barriers while cryosuction strips hydration layers and compresses nanoparticles into micrometer-scale planar aggregates. Chemical evidence points to interfacial (hydr)oxo bridging, alongside hydrogen bonding, that resists disaggregation. These mechanisms lock nanoparticles into mesocrystal-like assemblages that retain their nanoscale identity but inhibit dissolution-reprecipitation to goethite, instead favoring solid-state transformation to hematite. Ice formation thus acts as a geochemical reactor, driving aggregation and interfacial bonding that redirect iron speciation, with broad implications for nutrient cycling and carbon preservation across the cryosphere.
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