Melamine powder (C3H6N6) is an industrial raw material. Its illegal addition to food has caused severe health crises, making research on its molecular properties crucial for detection and degradation.
Theoretical Framework: Density Functional Theory (DFT) with the B3PW91/6-31+(d,p) basis set—validated to yield results closest to experimental values (average error = 0.00324 Å for bond lengths).
External Electric Field: Applied along the N-C bond direction (1C-7N), with intensity ranging from 0 to 0.010 a.u. (1 a.u. = 5.14225×10¹¹ V·m⁻¹).
Calculated Indicators: Bond length, total energy, dipole moment, HOMO-LUMO energy gap, infrared (IR) spectrum, and N-C bond dissociation potential energy surface (PES).
Molecular Model: Optimized ground-state structure of melamine (Figure 1) constructed via Gaussian 09W and GaussView 5.0.
Validation: Bond length calculations at B3PW91/6-31+(d,p) showed minimal deviation from experimental data, confirming computational reliability.
External electric fields induce differential changes in melamine’s bond lengths:
Total Energy: Decreases linearly with increasing electric field—from -446.3683 Hartree (0 a.u.) to -446.3743 Hartree (0.010 a.u.), indicating enhanced molecular stability in stronger fields.
Dipole Moment: Monotonically increases from 0 Debye (non-polar molecule) to 3.0305 Debye (0.010 a.u.), as external fields induce charge separation, strengthening molecular polarity.
| 0 | -446.36830301 | 1.00529 | 1.35316 | 0.0000 |
| 0.002 | -446.36853299 | 1.00481 | 1.35675 | 0.6084 |
| 0.004 | -446.36924999 | 1.00447 | 1.36026 | 1.2147 |
| 0.006 | -446.37044323 | 1.00417 | 1.36382 | 1.8197 |
| 0.008 | -446.37211312 | 1.00396 | 1.36753 | 2.4253 |
| 0.010 | -446.37425803 | 1.00377 | 1.37131 | 3.0305 |
HOMO-LUMO Gap: Narrows significantly with increasing electric field—from 6.84 eV (0 a.u.) to 5.52 eV (0.010 a.u.) (Table 2).
Orbital Energy Changes:
LUMO energy decreases (enhancing electron-accepting ability), with a faster rate at higher fields.
HOMO energy increases (weakening electron-binding ability), leading to reduced energy gap and higher chemical reactivity—facilitating molecular excitation and chemical reactions.
| 0 | -0.24267 | 0.00889 | 6.84 |
| 0.004 | -0.24174 | -0.00320 | 6.49 |
| 0.008 | -0.24094 | -0.02529 | 5.85 |
| 0.010 | -0.23998 | -0.03701 | 5.52 |
External electric fields induce a significant redshift in melamine’s IR spectrum:
Key Vibrations: The NH symmetric stretch (NH sym-str) and the NH asymmetric stretch (NH asym-str) exhibit decreasing frequencies with increasing field strength.
Mechanism: Field-induced charge redistribution weakens NH bond vibration energy, shifting absorption peaks to lower wavenumbers (redshift) without altering IR intensity—providing a theoretical basis for electric field-assisted IR detection of melamine.
N-C Bond Cleavage: The potential energy surface (PES) of N-C bond dissociation gradually loses its bound state as the electric field increases.
Dissociation Tendency: The N7−C1 bond (which lengthens with field strength) exhibits a reduced dissociation barrier, making it more prone to cleavage—offering insights for electric field-assisted melamine degradation.
The field-induced IR redshift and dipole moment changes can optimize melamine detection methods (e.g., IR spectroscopy), improving sensitivity and selectivity for trace melamine in food or environmental samples.
The weakened N7−C1 bond and reduced dissociation barrier suggest potential for electric field-assisted melamine degradation—guiding the development of efficient, low-cost pollution control technologies.
The DFT-based methodology and systematic data provide a framework for studying other toxic molecules under external fields, advancing environmental chemistry research.
Melamine Under External Electric Fields (0~0.010 a.u.) exert profound, predictable effects on melamine’s molecular properties: differential bond length changes, reduced total energy, enhanced polarity, narrowed energy gap, IR redshift, and easier N-C bond cleavage. These findings bridge computational chemistry and practical applications, providing critical theoretical support for melamine detection optimization and degradation technology development.
As concerns about melamine pollution persist, this research opens new avenues for environmental monitoring and pollution control—proving that external electric fields can be a powerful tool for manipulating toxic molecular behavior.
Tech Blog How to Slow Down Melamine Reactor Temperature Difference Rise Rate Melamine production via high-pressure processes (3rd-5th generation) relies heavily on reactor long-cycle operation.
Tech Blog Melamine Under External Electric Fields: Physical Properties & Infrared Spectrum Characteristics Melamine powder (C3H6N6) is an industrial raw material. Its illegal addition to
Tech Blog Factors Affecting color of High Pressure Melamine Melamine is a critical organic chemical intermediate widely used in resins, flame retardants, and construction materials.
JINGJIANG MELAMINE POWDER
© JINJIANG MELAMINE