1. Chemical context

Several energetic materials and high-nitro­gen materials have been generated from heterocyclic C-bromo­nitrilimines based on the well-known 3-amino-5-nitro-1,2,4-triazole (ANTA) moiety (Gettings et al., 2021; Thoenen et al., 2022). The 1,2,4-triazole heterocycle contains two carbons, which enable addition of substituents such as C-amino and C-nitro to the backbone. Furthermore, these same carbons may form an exocyclic C—C bond, bridging two 1,2,4-triazoles together (Dippold & Klapötke, 2013). The bridged motifs may also be linked by nitro­gen chains including N—N (azo) (Yount et al., 2020, 2021) and N=N—N (triazene) (Feng et al., 2021; Jiang et al., 2023).

Energetic materials such as 4,4′,5,5′-tetra­amino-3,3′-azo-bis-1,2,4-triazole (TAABT) and its nitrated derivative (DNDAABT) are azo-bridged 1,2,4-triazoles (Yount et al., 2020, 2021). Azo-bridged triazoles are less toxic and have a lower environmental impact than most metal-based primary energetic materials such as lead azide (Türker, 2016). Other researchers studied azo- and triazene-bridged 1,2,3-triazoles, finding improved performance (thermal stability, insensitivity, and higher crystal density) of the azo-bridged analog compared to the triazene (Feng et al., 2021).

There are a few known routes to effectively synthesize triazene-bridged triazoles. In an early synthesis, a diazo­nium solution prepared from 3-amino-5-nitro­samino-1,2,4-triazole treated with 3,5-di­amino-1,2,4-triazole (guanazole) formed 1,3-bis­[3-(5-amino-1,2,4-triazol­yl)]triazene (Hauser, 1964). In this reaction, the triazene bridge is formed by the diazo­nium of the first compound and amine of guanazole (Fig. 1, top). In another synthesis, 5-azido-4-(di­methyl­amino)-1-methyl-1,2,4-triazolium hexa­fluorido­phosphate reacts with the carbene of a triazolium salt to form the triazene bridge (Laus et al., 2016) (Fig. 1, bottom). Similar nitro­gen-rich catenated structures featuring triazene-bridged 1,2,4-triazoles have been used as ligands coordinated with metal complexes (copper, palladium, and nickel; Hanot et al., 1994, 1999). In a recent paper, Ma's research group obtained both 5,5′-di­nitro-3,3′-triazene-1,2,4-triazole and 5-nitro-3,3′-triazene-1,2,4-triazole via diazo­nium-N-coupling reactions (Jiang et al., 2023). From both of these triazene-bridged 1,2,4-triazoles, several more energetic salts (potassium, ammonium, hydrazinium, and hydroxyl­ammonium) were reported, demonstrating good sensitivities, thermal stabilities, and high calculated detonation properties (Jiang et al., 2023).

Figure 1 Triazene-bridged 1,2,4-triazoles obtained by reacting 5-amino-4H-1,2,4-triazole-3-diazo­nium with guanazole (top). Alternatively, the azido-substituted 1,2,4-triazole reacting with the carbene forms a triazene bridge (bottom).

In this manuscript we report a rare triazene-bridged nitro-1,2,4-triazole as a cocrystal with tri­ethyl­ammonium nitrate.

2. Structural commentary

The title compound 3 is a cocrystal of the triazene and tri­ethyl­ammonium nitrate having a chemical composition of C₄H₃N₁₁O₄·C₆H₁₆N·NO₃ and possessing one tri­ethyl­ammonium cation, one nitrate anion, and the triazene mol­ecule (Fig. 2). Compound 3 crystallizes in the triclinic system (space group P) and four independent chemically identical copies of each of the constituent parts are present (Z′ = 4, Z = 8), with pseudo-translations along the b-axis direction. Exact translational symmetry is broken by a slight modulation of one of the triazene mol­ecule pairs and nitrate ions, and by disorder of some of the tri­ethyl­ammonium cations (see Supra­molecular features section for details). A common atom-numbering scheme was used for the four moieties, with residue numbers 1 through 4 used to distinguish between chemically equivalent atoms.

Figure 2 View of the asymmetric unit of the structure of the tri­ethyl­ammonium nitrate cocrystal of 5,5′-(triaz-1-ene-1,3-di­yl)bis­(3-nitro-1H-1,2,4-triazole) (3) with the labeling scheme. Ellipsoids are drawn at the 50% probability level. Carbon-bound H atoms as well as labels for the tri­ethyl­ammonium C and minor moiety N atoms have been omitted for clarity. Hydrogen bonds within the asymmetric unit are shown as turquoise dashed lines. Those to symmetry-generated atoms are omitted.

Each of the four triazene mol­ecules consists of two 5-nitro-1,2,4-triazole rings linked together by three catenated nitro­gen atoms (triazene) in a trans geometry. Each of the mol­ecules carries three acidic nitro­gen-bound hydrogen atoms, one at one of the triazene N atoms (N1), and one at each of the triazole rings (N5 and N9), thus rendering the mol­ecules charge neutral (all triazene H atoms were well resolved in difference-density maps and positions are also supported by hydrogen-bonding considerations). All four triazene mol­ecules are close to planar, with the largest deviations from planarity being observed for the nitro oxygen atoms. Root mean square deviations from planarity for all C and N atoms are 0.0718, 0.0589, 0.0877 and 0.0550 Å for mol­ecules 1 through 4, respectively. The largest deviation from planarity is observed for nitro oxygen O1 of residue 3 [0.406 (4) Å]. Bond distances and angles of the triazene mol­ecules are in the expected ranges, and agree with those of related triazenes such as the dihydrate of the triazene of title compound 3 (Jiang et al., 2023). The N1—N2 bond length involving the protonated nitro­gen N1 with an average value of 1.336 Å is significantly (0.063 Å) longer than that of N2—N3 (1.273 Å), indicating localized single and double bonds for the triazene N₃ units. Differences between the values for the four mol­ecules are insignificant [values in the four mol­ecules are N1—N2 = 1.333 (3), 1.334 (3), 1.339 (3) and 1.337 (3) Å; those for N2–N3 are 1.272 (3), 1.269 (3), 1.273 (3) and 1.275 (3) Å]. A similar trend is observed for the C—N bonds of the triazoles, but differences are smaller, as expected due to partial delocalization of the single and double bonds in a triazole. The C—N bond lengths involving the protonated N atoms N5 and N9 range from 1.340 (3) to 1.353 (3) Å (average 1.347 Å), those of unprotonated atoms N6 and N10 at 1.301 (3) to 1.317 (3) Å (average 1.312 Å) are slightly (0.035 Å) shorter. Other bond distances in the triazoles follow a similar trend and are as expected, and confirm the localized nature of the acidic hydrogen atoms. In the related tripotassium salt of the title compound triazole (Jiang et al., 2023), which is fully deprotonated, bond distances differ much less. The triazene N—N bonds are virtually identical (1.301 and 1.304 Å), and all C—N bonds of the triazolate are clustered within a tight margin (1.324 to 1.353 Å).

Bond distances and angles within the nitrate anions are unexceptional. Two of the four triethyl ammonium cations (cations 1 and 4) are each disordered over three orientations (see Refinement section for details of the refinement strategy). The disorder involves inversion at the ammonium N atom, and variation of the ethyl torsion angles. Three close-to-trans C—N—C—C torsion angles are observed for cation 3 (not disordered) as well as the third moiety of cations 1 and 4. One ethyl group is rotated into a gauche orientation (while the other two maintain trans), which is observed for the not-disordered cation 2 and the major moieties of 1 and 4, the second and third moieties of 4, and the third moiety of 3. Again the second moiety of 1 is different, featuring one trans, one gauche and one anti orientation (with the two non-gauche ethyl groups rotated in opposite directions). Gauche-oriented methyl groups also differ by pointing either up or down relative to the direction of the N—H bond. The different conformations of the cations are shown in Fig. 3, and representative torsion angles are given in Table 1.

Figure 3 The various conformations of the tri­ethyl­ammonium cations. View along the N—H bond direction (top rows) and side-on views (bottom rows). The occupancy rates are given for disordered cations.

3. Supra­molecular features

The presence of four crystallographically independent repeat units warrants an investigation for the presence of pseudo-symmetry. Indeed, upon closer inspection a pseudo-translation becomes apparent that relates the components of the structure along the b-axis direction. When viewed down this direction, the components of residue 1 relate to those of residue 2, and those of 3 to those of 4. Translational symmetry is nearly perfectly obeyed for the triazene mol­ecules 1 and 2, while for mol­ecules 3 and 4 a slight shift by about half a bond length is observed (Fig. 4). The nitrate ions are also slightly modulated along [010]. For the cations, exact translational symmetry is also broken by the presence of disorder for cations 1 and 4, which is not present for the pseudotranslationally related cations 2 and 3. Exact translational symmetry is also absent when disorder is ignored, and only the most prevalent moieties are compared to each other. The cations are slightly shifted laterally with respect to each other, and modulated by differing torsion angles (see Table 1). Using default cutoff values PLATON (Spek, 2020) reports an 82% fit for translational symmetry along [010]. The absence of exact translational symmetry is also supported by the intensity of reflections affected by pseudotranslation, which are clearly observed. The average intensity of the satellite reflections is 4.8 (I/σ = 3.5), while the intensity for all reflections averages to 13.6 (I/σ = 4.6).

Figure 4 Modulation along the b-axis direction. Mol­ecules are color coded by residue numbers, with triazene mol­ecules and ions of residue 1 in red, of 2 in green, of 3 in blue and of 4 in dark yellow. Ellipsoids are drawn at the 20% probability level to better show modulation of atoms (minor moiety cations 1 and 4 are shown in stick mode).

Directional intra­molecular inter­actions are dominated by N—H⋯O and N—H⋯N hydrogen bonds of various kinds (Table 2). The triazene N—H group forms a bifurcated set of hydrogen bonds to atoms N4 and O2 of a neighboring mol­ecule. A reciprocal set of hydrogen bonds is formed from the other triazene, thus creating a pseudo-inversion-symmetric dimer (Fig. 5). Mol­ecules connected by hydrogen bonds are, however, symmetry-independent and not related by actual inversion symmetry. The dimers are formed between mol­ecule 1 and mol­ecule 3 (at −x, 2 − y, 1 − z), and between mol­ecule 2 and mol­ecule 4 (also at −x, 2 − y, 1 − z).

Table 2 Hydrogen-bond geometry (Å, °) D—H⋯A D—H H⋯A D⋯A D—H⋯A N1_1—H1_1⋯N4_2i 0.88 2.37 3.117 (3) 142 N1_1—H1_1⋯O1_2i 0.88 2.30 3.066 (3) 145 N5_1—H5_1⋯O5_1 0.88 1.87 2.745 (3) 173 N9_1—H9_1⋯O5_1 0.88 1.88 2.761 (3) 174 N13_1—H13_1⋯N12_1 1.00 2.60 3.565 (6) 162 N13_1—H13_1⋯O6_1 1.00 2.31 3.096 (6) 135 N13_1—H13_1⋯O7_1 1.00 2.26 3.249 (6) 169 C6_1—H6A_1⋯N8_4ii 0.98 2.69 3.650 (8) 168 C7_1—H7B_1⋯O4_4ii 0.99 2.55 3.387 (7) 142 C8_1—H8B_1⋯O6_2iii 0.98 2.58 3.518 (11) 161 C9_1—H9B_1⋯O6_2iii 0.99 2.44 3.222 (7) 136 N13B_1—H13B_1⋯N8_4ii 1.00 2.17 3.165 (6) 172 C5B_1—H5C_1⋯O2_3iv 0.99 2.64 3.629 (8) 173 C5B_1—H5D_1⋯N10_2iii 0.99 2.58 3.567 (7) 177 C7B_1—H7D_1⋯O6_1 0.99 2.62 3.547 (7) 156 C8B_1—H8D_1⋯O4_2iii 0.98 2.52 3.452 (11) 160 C9B_1—H9D_1⋯O2_2iv 0.99 2.53 3.146 (7) 120 C10B_1—H10D_1⋯O2_3iv 0.98 2.61 3.150 (8) 115 N13C_1—H13C_1⋯O6_1 1.00 2.29 3.27 (3) 167 N13C_1—H13C_1⋯O7_1 1.00 2.56 3.31 (2) 132 C5C_1—H5F_1⋯O2_2iv 0.99 2.55 3.32 (3) 135 C6C_1—H6H_1⋯N8_4ii 0.98 2.61 3.53 (3) 157 C6C_1—H6I_1⋯O7_1 0.98 2.52 3.34 (3) 141 C7C_1—H7F_1⋯O4_4ii 0.99 2.36 2.93 (2) 116 C9C_1—H9F_1⋯O6_2iii 0.99 2.33 3.20 (2) 147 N1_2—H1_2⋯N4_1i 0.88 2.35 3.096 (3) 143 N1_2—H1_2⋯O1_1i 0.88 2.27 3.035 (3) 145 N5_2—H5_2⋯O5_2 0.88 1.88 2.751 (3) 172 N9_2—H9_2⋯O5_2 0.88 1.89 2.770 (3) 177 N13_2—H13_2⋯N12_2 1.00 2.53 3.444 (3) 151 N13_2—H13_2⋯O6_2 1.00 1.96 2.933 (3) 164 N13_2—H13_2⋯O7_2 1.00 2.48 3.188 (3) 128 C5_2—H5A_2⋯O2_1 0.99 2.57 3.097 (4) 113 C9_2—H9A_2⋯O6_1iii 0.99 2.41 3.340 (5) 157 N1_3—H1_3⋯N4_4v 0.88 2.39 3.136 (3) 143 N1_3—H1_3⋯O2_4v 0.88 2.30 3.075 (3) 147 N5_3—H5_3⋯N12_3 0.88 2.70 3.523 (3) 157 N5_3—H5_3⋯O5_3 0.88 1.87 2.748 (4) 175 N9_3—H9_3⋯O5_3 0.88 1.86 2.743 (3) 178 N13_3—H13_3⋯N12_3 1.00 2.51 3.503 (3) 174 N13_3—H13_3⋯O6_3 1.00 2.14 3.068 (3) 153 N13_3—H13_3⋯O7_3 1.00 2.23 3.116 (3) 146 C5_3—H5A_3⋯O1_2iv 0.99 2.64 3.367 (4) 131 C7_3—H7B_3⋯O3_1vi 0.99 2.63 3.317 (4) 127 C9_3—H9A_3⋯O6_4vii 0.99 2.44 3.389 (4) 160 C9_3—H9B_3⋯O3_2vi 0.99 2.65 3.538 (4) 149 C10_3—H10B_3⋯O6_3 0.98 2.56 3.342 (4) 137 N1_4—H1_4⋯N4_3v 0.88 2.39 3.126 (3) 142 N1_4—H1_4⋯O2_3v 0.88 2.29 3.035 (3) 143 N5_4—H5_4⋯O5_4 0.88 1.86 2.732 (3) 169 N9_4—H9_4⋯O5_4 0.88 1.87 2.748 (3) 176 N13_4—H13_4⋯N12_4 1.00 2.65 3.505 (15) 144 N13_4—H13_4⋯O6_4 1.00 2.30 3.171 (16) 145 N13_4—H13_4⋯O7_4 1.00 2.34 3.019 (14) 124 C6_4—H6A_4⋯N10_3vii 0.98 2.59 3.52 (2) 157 C7_4—H7A_4⋯O3_1vi 0.99 2.63 3.410 (12) 136 C7_4—H7B_4⋯N10_3vii 0.99 2.68 3.394 (11) 129 C9_4—H9A_4⋯O1_3 0.99 2.62 3.203 (10) 118 C9_4—H9B_4⋯O7_4 0.99 2.53 3.096 (11) 116 C10_4—H10A_4⋯O1_1 0.98 2.59 3.158 (13) 117 C10_4—H10B_4⋯N6_2 0.98 2.54 3.219 (13) 126 N13B_4—H13B_4⋯N10_3vii 1.00 2.45 3.385 (9) 155 C5B_4—H5C_4⋯N8_2i 0.99 2.62 3.558 (11) 159 C5B_4—H5D_4⋯O1_1 0.99 2.54 3.286 (10) 132 C7B_4—H7C_4⋯O7_4 0.99 2.56 3.33 (2) 134 C7B_4—H7D_4⋯O3_2i 0.99 2.27 3.155 (17) 148 C9B_4—H9C_4⋯N12_4 0.99 2.70 3.666 (13) 166 C9B_4—H9C_4⋯O6_4 0.99 2.08 2.989 (12) 152 C9B_4—H9C_4⋯O7_4 0.99 2.64 3.540 (13) 151 C9B_4—H9D_4⋯O6_3vii 0.99 2.29 3.240 (13) 160 N13C_4—H13C_4⋯N12_4 1.00 2.63 3.626 (18) 176 N13C_4—H13C_4⋯O6_4 1.00 2.27 3.208 (18) 156 N13C_4—H13C_4⋯O7_4 1.00 2.31 3.208 (16) 149 C7C_4—H7F_4⋯O6_3vii 0.99 2.21 3.100 (13) 150 C8C_4—H8I_4⋯O6_4 0.98 2.63 3.48 (2) 146 C10C_4—H10G_4⋯O2_2 0.98 2.61 3.346 (17) 132 C10C_4—H10H_4⋯O1_3 0.98 2.56 3.18 (2) 122 Symmetry codes: (i) ; (ii) ; (iii) ; (iv) ; (v) ; (vi) ; (vii) .

Figure 5 Dimers formed by bifurcated N—H⋯N hydrogen bonds between triazene mol­ecules, as well as the N—H⋯O-bonded nitrate anions. Only atoms involved in hydrogen bonding are labeled for clarity. Mol­ecules 3 and 4 form an equivalent dimer.

Each of the triazenes is also hydrogen bonded via the tetra­zole N–H groups to atom O5 of one of the nitrate anions (Fig. 5). O5 acts as acceptor for two N–H⋯O hydrogen bonds from the same triazene-nitro­triazole mol­ecule. The nitrate ions thus bonded are nearly coplanar with the neutral mol­ecules, with only a slight tilt between their mean planes of 23.7 (2), 19.4 (2), 14.3 (2) and 17.1 (2)° for mol­ecule pairs 1 through 4, respectively.

Additional hydrogen bonds originate from the tri­ethyl­ammonium cations. These do, however, vary due to disorder of two of the four cations. The non-disordered cations of the major moieties as well as each minor moiety of the disordered cations do hydrogen bond in a bifurcated manner to O6 and O7 of the nitrate anions. Bonding parameters do vary with the hydrogen bonds to the second oxygen atom with some of the inter­actions being rather weak, rendering the hydrogen bonds nearly not bifurcated (see the hydrogen-bonding table for exact numerical values). The second moieties of both disordered cations are inverted at the nitro­gen atoms, thus breaking the hydrogen bond to the nitrate anions (weak C—H⋯O bonds are formed instead; see hydrogen-bonding Table 2). The ammonium N—H groups still form hydrogen bonds, but the acceptors are nitro­gen atoms of triazole rings: N8_4 at 1 − x, 1 − y, −z for cation 3B, and N10_3 at −x, 1 − y, −z for cation 1B.

The extensive hydrogen-bonding network facilitates a relatively high density of 1.516 g cm⁻³, but not quite as high as that of the dihydrate of 5,5′-(triaz-1-ene-1,3-di­yl)bis­(3-nitro-1H-1,2,4-triazole), which was reported as 1.765 g cm⁻³ (Jiang et al., 2023). These high densities and the high-nitro­gen content make this triazene-bridged 1,2,4-triazole of inter­est as a potential future energetic material, which already prompted a recent investigation of the energetic properties of some of its derivatives (Jiang et al., 2023).

4. Database survey

A structure search of the Cambridge Structural Database (CSD, v5.43, March 2022; Groom et al., 2016) for an R—NH—N=N—R unit yielded 347 hits, about equally distributed between linear triazenes and cyclic 1,2,3-triazoles. The most closely related hits are that of the dihydrate and of the tripotassium salt 3.5 hydrate of the triazene of title compound 3 (CSD refcodes DIFYOK and DIFYUQ, CCDC 2225841 and 2225842; Jiang et al., 2023). The dihydrate differs from the triazene in 3 by a rotation of one of the triazoles, which allows hydrogen bonding with a water mol­ecule, replacing the nitrate atom O5 in 3 via one N—H⋯O and one O—H⋯N hydrogen bond. In the tripotassium salt both triazolates are rotated, and the solitary nitro­gen atom of the triazolates bond together with the middle triazene N atom to a potassium ion. The nitro groups both also inter­act weakly via one O atom with this potassium ion.

5. Synthesis and crystallization

CAUTION! The described compound 3 may be an energetic material with sensitivity to various stimuli. While we encountered no issues in the handling of this material, proper protective measures (face shield, ear protection, body armor, Kevlar gloves, and earthed equipment) should be used at all times.

A single crystal of the title compound was obtained unintentionally as the product of an attempted synthesis of a heterocyclic C-bromo­nitrilimine. 3-Amino-5-nitro-1,2,4-triazole (ANTA, 1) was prepared according to the literature method (Manship et al., 2020). An aqueous solution of ANTA (100 mg, 0.775 mmol) was cooled to 273–278 K. A separate chilled solution of sodium nitrite (62 mg) dissolved in water (5 mL) and nitric acid (0.06 mL, 15.8 M) was prepared. The acidic solution was added to the cold mixture with stirring, forming the highly unstable diazo­nium inter­mediate (2). The cold reaction mixture was stirred overnight and the next day, then tri­ethyl­amine (80 mg, 0.775 mmol) was added to the mixture with stirring for a few hours. The mixture was then set aside for slow evaporation. After several days, a mixture of larger block-shaped and smaller rod-shaped crystals was obtained. The block-shaped crystals were identified via single-crystal XRD as sodium nitrate [space group Pc1, a = 5.0650 (3), c = 16.5957 (17) Å]. The rod-shaped crystals were those of the title compound, a cocrystal of tri­ethyl­ammonium nitrate and 5,5′-(triaz-1-ene-1,3-di­yl)bis­(3-nitro-1H-1,2,4-triazole) (3). No other solid products could be identified and the material was not analyzed further.

6. Refinement

Crystal data, data collection and structure refinement details are summarized in Table 3.

Table 3 Experimental details Crystal data Chemical formula C6H16N+·NO3−·C4H3N11O4 Mr 433.38 Crystal system, space group Triclinic, P Temperature (K) 150 a, b, c (Å) 13.2412 (6), 14.3856 (6), 21.3601 (11) α, β, γ (°) 108.186 (3), 99.785 (3), 91.272 (3) V (Å3) 3796.9 (3) Z 8 Radiation type Mo Kα μ (mm−1) 0.13 Crystal size (mm) 0.23 × 0.22 × 0.20   Data collection Diffractometer Bruker AXS D8 Quest diffractometer with PhotonII charge-integrating pixel array detector (CPAD) Absorption correction Multi-scan (SADABS; Krause et al., 2015) Tmin, Tmax 0.660, 0.746 No. of measured, independent and observed [I > 2σ(I)] reflections 58894, 18504, 10729 Rint 0.078 (sin θ/λ)max (Å−1) 0.667   Refinement R[F2 > 2σ(F2)], wR(F2), S 0.070, 0.222, 1.06 No. of reflections 18504 No. of parameters 1363 No. of restraints 1250 H-atom treatment H-atom parameters constrained Δρmax, Δρmin (e Å−3) 0.54, −0.31 Computer programs: APEX3 and SAINT (Bruker, 2020), SHELXT (Sheldrick, 2015a), SHELXL2019/2 (Sheldrick, 2015b) and ShelXle (Hübschle et al., 2011).

Four crystallographically independent triazene mol­ecules and four nitrate-tri­ethyl­ammonium ion pairs are present in the crystal structure. A common atom-naming scheme was used for all four equivalent moieties, which are distinguished by their respective residue numbers (RESI 1 through 4). Two of the four tri­ethyl­ammonium cations are threefold disordered by being either hydrogen bonded to nitrate oxygen atoms, or to triazole nitro­gen atoms, and by different folding of their ethyl groups. All tri­ethyl­ammonium moieties were restrained to have similar geometries. U_ij components of the ADPs for disordered atoms closer to each other than 2.0 Å were restrained to be similar. Subject to these conditions, the occupancy rates refined to 0.499 (3), 0.377 (2) and 0.124 (3) for moieties A, B and C of residue 1, and 0.374 (3), 0.307 (3) and 0.318 (3) for moieties A, B and C of residue 4.

H atoms were positioned geometrically and constrained to ride on their parent atoms. C—H bond distances were constrained to 0.99 and 0.98 Å for aliphatic CH₂ and CH₃ moieties, respectively. N—H bond distances were constrained to 0.88 Å for planar (sp²-hybridized) and to 1.00 Å for ammonium R₃N—H⁺ groups. Methyl CH₃ groups were allowed to rotate but not to tip to best fit the experimental electron density. U_iso(H) values were set to a multiple of U_eq(C/N) (1.5 for CH₃ and 1.2 for all other H atoms).