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sci_form/charges_eeq/
charges.rs

1//! EEQ Charge Model — Core
2//!
3//! Electronegativity equalization with geometry-dependent coordination
4//! numbers and Coulomb damping. Solves a constrained linear system
5//! to yield charge-neutral partial charges.
6
7use nalgebra::DMatrix;
8use serde::{Deserialize, Serialize};
9
10/// EEQ per-element parameters.
11#[derive(Debug, Clone, Copy, Serialize, Deserialize)]
12pub struct EeqParams {
13    /// Electronegativity chi (eV).
14    pub chi: f64,
15    /// Chemical hardness eta (eV).
16    pub eta: f64,
17    /// Charge radius for Coulomb damping (Å).
18    pub r_eeq: f64,
19    /// Covalent radius for CN (Å).
20    pub r_cov: f64,
21}
22
23/// Configuration for EEQ calculations.
24#[derive(Debug, Clone, Serialize, Deserialize)]
25pub struct EeqConfig {
26    /// Total molecular charge.
27    pub total_charge: f64,
28    /// Regularization parameter for near-singular systems.
29    pub regularization: f64,
30}
31
32impl Default for EeqConfig {
33    fn default() -> Self {
34        Self {
35            total_charge: 0.0,
36            regularization: 1e-10,
37        }
38    }
39}
40
41/// Result of EEQ charge calculation.
42#[derive(Debug, Clone, Serialize, Deserialize)]
43pub struct EeqChargeResult {
44    /// Partial charges per atom.
45    pub charges: Vec<f64>,
46    /// Fractional coordination numbers per atom.
47    pub coordination_numbers: Vec<f64>,
48    /// Total charge (should match config).
49    pub total_charge: f64,
50}
51
52/// Get EEQ parameters for an element by atomic number.
53pub fn get_eeq_params(z: u8) -> EeqParams {
54    match z {
55        1 => EeqParams {
56            chi: 2.20,
57            eta: 13.6,
58            r_eeq: 0.80,
59            r_cov: 0.32,
60        },
61        5 => EeqParams {
62            chi: 2.04,
63            eta: 8.30,
64            r_eeq: 1.40,
65            r_cov: 0.85,
66        },
67        6 => EeqParams {
68            chi: 2.55,
69            eta: 10.0,
70            r_eeq: 1.30,
71            r_cov: 0.77,
72        },
73        7 => EeqParams {
74            chi: 3.04,
75            eta: 14.5,
76            r_eeq: 1.20,
77            r_cov: 0.75,
78        },
79        8 => EeqParams {
80            chi: 3.44,
81            eta: 13.4,
82            r_eeq: 1.10,
83            r_cov: 0.73,
84        },
85        9 => EeqParams {
86            chi: 3.98,
87            eta: 17.4,
88            r_eeq: 1.00,
89            r_cov: 0.71,
90        },
91        14 => EeqParams {
92            chi: 1.90,
93            eta: 8.15,
94            r_eeq: 1.75,
95            r_cov: 1.17,
96        },
97        15 => EeqParams {
98            chi: 2.19,
99            eta: 10.5,
100            r_eeq: 1.60,
101            r_cov: 1.10,
102        },
103        16 => EeqParams {
104            chi: 2.58,
105            eta: 10.4,
106            r_eeq: 1.50,
107            r_cov: 1.04,
108        },
109        17 => EeqParams {
110            chi: 3.16,
111            eta: 13.0,
112            r_eeq: 1.40,
113            r_cov: 0.99,
114        },
115        35 => EeqParams {
116            chi: 2.96,
117            eta: 11.8,
118            r_eeq: 1.55,
119            r_cov: 1.14,
120        },
121        53 => EeqParams {
122            chi: 2.66,
123            eta: 10.5,
124            r_eeq: 1.70,
125            r_cov: 1.33,
126        },
127        26 => EeqParams {
128            chi: 1.83,
129            eta: 7.90,
130            r_eeq: 1.70,
131            r_cov: 1.24,
132        },
133        29 => EeqParams {
134            chi: 1.90,
135            eta: 7.73,
136            r_eeq: 1.60,
137            r_cov: 1.32,
138        },
139        30 => EeqParams {
140            chi: 1.65,
141            eta: 9.39,
142            r_eeq: 1.65,
143            r_cov: 1.22,
144        },
145        // Extended TM coverage
146        22 => EeqParams {
147            chi: 1.54,
148            eta: 6.83,
149            r_eeq: 1.80,
150            r_cov: 1.47,
151        }, // Ti
152        24 => EeqParams {
153            chi: 1.66,
154            eta: 6.77,
155            r_eeq: 1.75,
156            r_cov: 1.39,
157        }, // Cr
158        25 => EeqParams {
159            chi: 1.55,
160            eta: 7.43,
161            r_eeq: 1.73,
162            r_cov: 1.39,
163        }, // Mn
164        27 => EeqParams {
165            chi: 1.88,
166            eta: 7.86,
167            r_eeq: 1.67,
168            r_cov: 1.26,
169        }, // Co
170        28 => EeqParams {
171            chi: 1.91,
172            eta: 7.64,
173            r_eeq: 1.65,
174            r_cov: 1.21,
175        }, // Ni
176        44 => EeqParams {
177            chi: 2.20,
178            eta: 7.36,
179            r_eeq: 1.75,
180            r_cov: 1.46,
181        }, // Ru
182        46 => EeqParams {
183            chi: 2.20,
184            eta: 8.34,
185            r_eeq: 1.70,
186            r_cov: 1.39,
187        }, // Pd
188        47 => EeqParams {
189            chi: 1.93,
190            eta: 7.58,
191            r_eeq: 1.72,
192            r_cov: 1.45,
193        }, // Ag
194        78 => EeqParams {
195            chi: 2.28,
196            eta: 8.96,
197            r_eeq: 1.72,
198            r_cov: 1.36,
199        }, // Pt
200        79 => EeqParams {
201            chi: 2.54,
202            eta: 9.23,
203            r_eeq: 1.70,
204            r_cov: 1.36,
205        }, // Au
206        // Main group additions
207        3 => EeqParams {
208            chi: 0.98,
209            eta: 5.39,
210            r_eeq: 2.10,
211            r_cov: 1.28,
212        }, // Li
213        11 => EeqParams {
214            chi: 0.93,
215            eta: 5.14,
216            r_eeq: 2.40,
217            r_cov: 1.66,
218        }, // Na
219        12 => EeqParams {
220            chi: 1.31,
221            eta: 7.65,
222            r_eeq: 2.00,
223            r_cov: 1.41,
224        }, // Mg
225        13 => EeqParams {
226            chi: 1.61,
227            eta: 5.99,
228            r_eeq: 1.90,
229            r_cov: 1.21,
230        }, // Al
231        19 => EeqParams {
232            chi: 0.82,
233            eta: 4.34,
234            r_eeq: 2.75,
235            r_cov: 2.03,
236        }, // K
237        20 => EeqParams {
238            chi: 1.00,
239            eta: 6.11,
240            r_eeq: 2.31,
241            r_cov: 1.76,
242        }, // Ca
243        _ => EeqParams {
244            chi: 2.20,
245            eta: 10.0,
246            r_eeq: 1.50,
247            r_cov: 1.00,
248        },
249    }
250}
251
252/// Compute fractional coordination number for each atom.
253///
254/// Uses a Fermi-type counting function:
255/// CN_i = Σ_{j≠i} 1 / (1 + exp(-16 * (r_cov_ij/r_ij - 1)))
256pub fn fractional_coordination(elements: &[u8], positions: &[[f64; 3]]) -> Vec<f64> {
257    let n = elements.len();
258    let mut cn = vec![0.0; n];
259
260    for i in 0..n {
261        let pi = get_eeq_params(elements[i]);
262        for j in (i + 1)..n {
263            let pj = get_eeq_params(elements[j]);
264            let r_cov_ij = pi.r_cov + pj.r_cov;
265            let dx = positions[i][0] - positions[j][0];
266            let dy = positions[i][1] - positions[j][1];
267            let dz = positions[i][2] - positions[j][2];
268            let r_ij = (dx * dx + dy * dy + dz * dz).sqrt();
269
270            if r_ij < 1e-10 {
271                continue;
272            }
273
274            let f = 1.0 / (1.0 + (-16.0 * (r_cov_ij / r_ij - 1.0)).exp());
275            cn[i] += f;
276            cn[j] += f;
277        }
278    }
279
280    cn
281}
282
283/// Coulomb interaction kernel with Gaussian damping.
284fn gamma_damped(r_ij: f64, r_eeq_i: f64, r_eeq_j: f64) -> f64 {
285    if r_ij < 1e-10 {
286        return 0.0;
287    }
288    let sigma_ij = (r_eeq_i * r_eeq_i + r_eeq_j * r_eeq_j).sqrt();
289    let arg = std::f64::consts::SQRT_2 / sigma_ij * r_ij;
290    erf_approx(arg) / r_ij
291}
292
293/// Approximate error function (Abramowitz & Stegun 7.1.26).
294pub(crate) fn erf_approx(x: f64) -> f64 {
295    let a1 = 0.254829592;
296    let a2 = -0.284496736;
297    let a3 = 1.421413741;
298    let a4 = -1.453152027;
299    let a5 = 1.061405429;
300    let p = 0.3275911;
301
302    let sign = if x < 0.0 { -1.0 } else { 1.0 };
303    let x = x.abs();
304    let t = 1.0 / (1.0 + p * x);
305    let y = 1.0 - (((((a5 * t + a4) * t) + a3) * t + a2) * t + a1) * t * (-x * x).exp();
306    sign * y
307}
308
309/// Compute EEQ charges by solving the extended linear system.
310///
311/// [η + γ   1] [q]   [−χ]
312/// [1^T     0] [λ] = [Q ]
313pub fn compute_eeq_charges(
314    elements: &[u8],
315    positions: &[[f64; 3]],
316    config: &EeqConfig,
317) -> EeqChargeResult {
318    let n = elements.len();
319
320    if n == 0 {
321        return EeqChargeResult {
322            charges: vec![],
323            coordination_numbers: vec![],
324            total_charge: config.total_charge,
325        };
326    }
327
328    if n == 1 {
329        return EeqChargeResult {
330            charges: vec![config.total_charge],
331            coordination_numbers: vec![0.0],
332            total_charge: config.total_charge,
333        };
334    }
335
336    let cn = fractional_coordination(elements, positions);
337
338    let dim = n + 1;
339    let mut a = DMatrix::zeros(dim, dim);
340    let mut b_vec = vec![0.0; dim];
341
342    let params: Vec<EeqParams> = elements.iter().map(|&z| get_eeq_params(z)).collect();
343
344    for i in 0..n {
345        a[(i, i)] = params[i].eta + config.regularization;
346
347        for j in (i + 1)..n {
348            let dx = positions[i][0] - positions[j][0];
349            let dy = positions[i][1] - positions[j][1];
350            let dz = positions[i][2] - positions[j][2];
351            let r_ij = (dx * dx + dy * dy + dz * dz).sqrt();
352            let gij = gamma_damped(r_ij, params[i].r_eeq, params[j].r_eeq);
353            a[(i, j)] = gij;
354            a[(j, i)] = gij;
355        }
356
357        a[(i, n)] = 1.0;
358        a[(n, i)] = 1.0;
359
360        let cn_correction = -0.1 * (cn[i] - 2.0);
361        b_vec[i] = -(params[i].chi + cn_correction);
362    }
363
364    b_vec[n] = config.total_charge;
365
366    let b_nalg = nalgebra::DVector::from_vec(b_vec);
367    let solution = a.lu().solve(&b_nalg);
368
369    let charges = match solution {
370        Some(sol) => (0..n).map(|i| sol[i]).collect(),
371        None => vec![0.0; n],
372    };
373
374    let total: f64 = charges.iter().sum();
375
376    EeqChargeResult {
377        charges,
378        coordination_numbers: cn,
379        total_charge: total,
380    }
381}
382
383#[cfg(test)]
384mod tests {
385    use super::*;
386
387    fn water_positions() -> Vec<[f64; 3]> {
388        vec![[0.0, 0.0, 0.0], [0.757, 0.586, 0.0], [-0.757, 0.586, 0.0]]
389    }
390
391    #[test]
392    fn test_coordination_number_water() {
393        let elements = [8, 1, 1];
394        let pos = water_positions();
395        let cn = fractional_coordination(&elements, &pos);
396        assert!(cn[0] > 1.5, "O CN = {}", cn[0]);
397        assert!(cn[1] > 0.5 && cn[1] < 1.5, "H CN = {}", cn[1]);
398    }
399
400    #[test]
401    fn test_eeq_charge_neutrality() {
402        let elements = [6, 6, 8, 1, 1, 1, 1, 1];
403        let pos = [
404            [0.0, 0.0, 0.0],
405            [1.54, 0.0, 0.0],
406            [2.57, 1.03, 0.0],
407            [-0.63, 0.89, 0.0],
408            [-0.63, -0.89, 0.0],
409            [1.54, -0.63, 0.89],
410            [1.54, -0.63, -0.89],
411            [3.52, 0.93, 0.0],
412        ];
413        let config = EeqConfig::default();
414        let result = compute_eeq_charges(&elements, &pos, &config);
415        assert!(
416            result.total_charge.abs() < 0.01,
417            "Charge not neutral: {}",
418            result.total_charge
419        );
420    }
421
422    #[test]
423    fn test_eeq_oxygen_negative() {
424        let elements = [8, 1, 1];
425        let pos = water_positions();
426        let config = EeqConfig::default();
427        let result = compute_eeq_charges(&elements, &pos, &config);
428        assert!(result.charges[0] < 0.0, "O charge = {}", result.charges[0]);
429        assert!(result.charges[1] > 0.0, "H charge = {}", result.charges[1]);
430    }
431
432    #[test]
433    fn test_gamma_damped_asymptotic() {
434        let g = gamma_damped(10.0, 1.0, 1.0);
435        assert!((g - 0.1).abs() < 0.01, "gamma(10) = {}, expected ~0.1", g);
436    }
437}