Water to Ice: Energy and Structure
Description
Water's anomalous behavior upon freezing — ice is less dense than liquid water — has long been attributed to tetrahedral hydrogen bonding geometry. While this describes the crystal structure, it does not explain why low configurational entropy produces larger volume, nor why H₂O alone among hydrogen-bonded molecules exhibits this anomaly. Here we show that both questions are answered by Energy-Skeletal (E-S) field theory.
In the E-S framework, a Skeletal-field (S-field) encodes configurational information structure and is governed by the conservation law E + S = constant. The S-field density couples to molecular configurational entropy I_config: highly ordered ice (I_config ≈ 0.12) compresses the S-field, and volume must expand to conserve E+S. Liquid water's greater disorder (I_config ≈ 0.45) relaxes this compression, enabling denser packing. This yields the volume relation V ∝ χ = 1 + α_I(1 − I_config), with α_I = 0.18, predicting ρ_ice = 0.949 g/cm³ (observed: 0.917, error 3.5%) and T_max = 4.7°C (observed: 4.0°C).
Crucially, the E-S framework explains why H₂O is unique.
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Additional details
Identifiers
- Other
- Author Lyle Semple
Dates
- Submitted
-
2026-03-09Quantum Physics
References
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