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Journal logoCRYSTALLOGRAPHIC
COMMUNICATIONS
ISSN: 2056-9890
Volume 80| Part 6| June 2024| Pages 645-648
https://doi.org/10.1107/S2056989024004468

Synthesis and crystal structure of 2,9-di­amino-5,6,11,12-tetra­hydro­dibenzo[a,e]cyclo­octene

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Nichole Valdez,a* Eric Nagel,a Erica Redline,a Mark Rodriguez,a Chad Staiger,a Jason Duggera and Jeffrey Fosterb

aSandia National Laboratories, 1515 Eubank Blvd. SE, Albuquerque, NM 87123, USA, and bOak Ridge National Laboratory, 5200 1 Bethel Valley Rd., Oak Ridge, Tennessee 37831, USA
*Correspondence e-mail: nrvalde@sandia.gov

Edited by L. Van Meervelt, Katholieke Universiteit Leuven, Belgium (Received 30 April 2024; accepted 13 May 2024; online 21 May 2024)

The cis- form of di­amino­dibenzo­cyclo­octane (DADBCO, C16H18N2) is of inter­est as a negative coefficient of thermal expansion (CTE) material. The crystal structure was determined through single-crystal X-ray diffraction at 100 K and is presented herein.

CCDC reference: 2355133

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1. Chemical context

Thermoset polymers are high performance materials that demonstrate excellent chemical, thermal, and mechanical stability at low weight and cost, making them ubiquitous in a wide range of applications such as insulating layers, encapsulants, adhesives, barriers, and composites (Biron, 2013[Biron, M. (2013). Editor. Thermosets and Composites, 2nd ed., ch. 6 Composites, pp 299-243. Oxford: William Andrew Publishing. https://doi.org/10.1016/B978-1-4557-3124-4.00006-7]; Brostow et al., 2014[Brostow, W., Goodman, S. & Wahrmund, J. (2014). Handbook of Thermoset Plastics, 3rd ed., edited by H. Dodiuk & S. Goodman, ch. 8 Epoxies, pp 191-252. Boston: William Andrew Publishing. https://doi.org/10.1016/B978-1-4557-3107-7.00008-7]; Dickie et al., 1988[Dickie, R., Labana, S. & Bauer, R. (1988). Editors. Cross-Linked Polymers: Chemistry, Properties, and Applications, vol 367. Washington, D. C.: American Chemical Society. https://doi.org/10.1021/bk-1988-0367.fw001]; Pascault et al., 2002[Pascault, J., Sautereau, H., Verdu, J. & Williams, R. (2002). Thermosetting Polymers. New York: CRC Press. ISBN: 978-0429208072]; Guo, 2018[Guo, Q. (2018). Editor.Thermosets, 2nd ed., ch. 8-13. Amsterdam: Elsevier. ISBN: 978-0081010211]). Because these applications involve an inter­face between different materials, the thermal expansion behaviors of each constituent must be considered to achieve suitable performance. Most solid materials exhibit a positive coefficient of thermal expansion (CTE), the rate at which thermal expansion occurs during positive temperature change. Large differences in CTE between the various materials in composites and devices results in inter­nal thermomechanical stress at inter­faces, which in turn reduces service life and may initiate device failure (Okura et al., 2000[Okura, J., Shetty, S., Ramakrishnan, B., Dasgupta, A., Caers, J. F. J. M. & Reinikainen, T. (2000). Microelectron. Reliab. 40, 1173-1180.]; de Vreugd et al., 2010[Vreugd, J. de, Jansen, K., Ernst, L. & Bohm, C. (2010). Microelectron. Reliab. 50, 910-916.]).

[Scheme 1]

One strategy to mitigate CTE incompatibilities is the covalent incorporation of thermally activated contractile units into the polymer (Shen et al., 2013[Shen, X., Viney, C., Johnson, E., Wang, C. & Lu, J. (2013). Nat. Chem. 5, 1035-1041.]). These units counteract the thermal expansion during heating, reducing the CTE below that of the parent material. Materials capable of zero or even negative CTE are achievable with this method. Dibenzo­cyclo­octane (DBCO) is one such unit, which achieves a thermally activated volume decrease by undergoing a reversible twist-boat to chair conformational change (Shen et al., 2013[Shen, X., Viney, C., Johnson, E., Wang, C. & Lu, J. (2013). Nat. Chem. 5, 1035-1041.]; Wang et al., 2018[Wang, Z., Huang, Y., Guo, J., Li, Z., Xu, J., Lu, J. & Wang, C. (2018). Macromolecules, 51, 1377-1385.]; Fu et al., 2020[Fu, W., Alam, T., Li, J., Bustamante, J., Lien, T., Adams, R. W., Teat, S. J., Stokes, B., Yang, W., Liu, Y. & Lu, J. (2020). J. Am. Chem. Soc. 142, 16651-16660.]). Di­amino­dibenzo­cyclo­octane (DADBCO), an aminated derivative, is also able to undergo this CTE modifying conformational change. However, it was found that ep­oxy resins incorporating 2,2′-DADBCO (cis) demonstrated negative CTE behavior while those utilizing 2,3′-DADBCO (trans) did not (Foster et al., 2021[Foster, J., Staiger, C., Dugger, J. & Redline, E. (2021). ACS Macro Lett. 10, 940-944.]). These two materials are not differentiable by most characterization methods including IR, MS, and NMR. In addition, melting points are unreliable due to the difficulty of separation of these two isomers.

2. Structural Commentary

The cis-DADBCO mol­ecules (point group C2) crystallizes in the chair conformation in space group Pna21. The structure was determined at 100 K and is illustrated in Fig. 1[link]. The carbon rings are labeled as Ring 1: C11–C16 with nitro­gen N1 connected to Ring 1 at C16, Ring 2: C21–C26 with N2 connected to Ring 2 at C26. The center cyclo­octane contains carbon atoms: C12, C13, C31–C34, C22, C23. The plane of Ring 1 (C11–C16) makes a 59.9 (1)° angle with the plane that contains the four central atoms of the chair cyclo­octane, C31–34. Nitro­gen N1 is essentially planar with Ring 1 with a deviation from the plane of −0.025 (4) Å. The plane of Ring 2 (C21–26) makes a 56.7 (1)° angle with the aforementioned cyclo­octane plane. Nitro­gen N2 is essentially planar with Ring 2 with a deviation from the plane of 0.026 (4)°. The puckering parameters (Cremer & Pople, 1975[Cremer, D. & Pople, J. A. (1975). J. Am. Chem. Soc. 97, 1354-1358.]) of the center cyclo­octane are: total puckering amplitude Q = 0.906 (4) Å, q2 = 0.024 (4) Å φ2 = 146 (9)°, q3 = 0.906 (4) Å φ3 = 111.6 (2)°, q4 = −0.005 (4) Å.

[Figure 1]
Figure 1
Displacement ellipsoid plot of cis-DADBCO with atom labels. Ellipsoids are drawn at the 50% probability level.

3. Supra­molecular Features

Hydrogen bonding appears to be possible between the two amine groups from one independent mol­ecule to the next through hydrogen H1B on nitro­gen N2 to nitro­gen N1 (bond length 2.452 Å) and through hydrogen H2A on nitro­gen N2 to nitro­gen N1 (bond length 2.458 Å). This information is summarized in Table 1[link] and illustrated in Fig. 2[link]. N—H..π and C—H..π inter­actions are also included in Table 1[link].

Table 1
Hydrogen-bond geometry (Å, °)

Cg1 and Cg2 are the centroids of rings C11–C16 and C21–C26, respectively.
D—H⋯A D—H H⋯A DA D—H⋯A
N1—H1B⋯N2i 0.86 (4) 2.46 (4) 3.295 (5) 165 (4)
N2—H2A⋯N1ii 0.88 2.46 3.295 (5) 159
N2—H2BCg2iii 0.88 2.96 3.742 (4) 149
C14—H14⋯Cg1iv 0.95 2.84 3.572 (4) 135
C32—H32ACg1ii 0.99 2.78 3.640 (4) 145
Symmetry codes: (i) [-x+{\script{3\over 2}}, y-{\script{1\over 2}}, z+{\script{1\over 2}}]; (ii) [-x+1, -y+1, z-{\script{1\over 2}}]; (iii) [-x-{\script{1\over 2}}, y+{\script{3\over 2}}, z+{\script{1\over 2}}]; (iv) [-x+2, -y+1, z+{\script{1\over 2}}].
[Figure 2]
Figure 2
Hydrogen bonding in the crystal packing of the title compound. Incomplete mol­ecules in the range are omitted for clarity. Displacement ellipsoids are drawn at 50% probability.

4. Database survey

A search was performed on the Cambridge Structural Database (CSD Version 5.45, March 2024; Groom et al., 2016[Groom, C. R., Bruno, I. J., Lightfoot, M. P. & Ward, S. C. (2016). Acta Cryst. B72, 171-179.]) using ConQuest (Version 2024.1.0), and this aminated structure was not found. At time of submission there were eight 6,8,6 ring system entries in the CSD, with cyclo­octane as the central ring, no additional rings linked, and no chemical substitutions in the core 6,8,6 carbon rings. A search of the chemical formula also yielded no results. An overview of 6,8,6 ring systems can be found in Domiano et al. (1992[Domiano, P., Cozzini, P., Claramunt, R. M., Lavandera, J. L., Sanz, D. & Elguero, J. (1992). J. Chem. Soc. Perkin Trans. 2, pp. 1609-1620.]). The 6,8,6 motif also appears in circulene systems, see Miyoshi et al. (2022[Miyoshi, H., Sugiura, R., Kishi, R., Spisak, S. N., Wei, Z., Muranaka, A., Uchiyama, M., Kobayashi, N., Chatterjee, S., Ie, Y., Hisaki, I., Petrukhina, M. A., Nishinaga, T., Nakano, M. & Tobe, Y. (2022). Angew. Chem. Int. Ed. 61, e202115316.]).

5. Synthesis and crystallization

Synthesis of dibenzo­cyclo­octane (DBCO)

The synthesis of DBCO was carried out according to a literature procedure (Franck et al., 2012[Franck, G., Brill, M. & Helmchen, G. (2012). Org. Syn. 89, 55-65.]). An oven-dried three-necked round-bottom flask equipped with a stir bar was charged with lithium metal (3.30 g, 478 mmol, 2.5 equiv) and 100 mL of anhydrous THF in an Ar-filled glovebox. The flask was sealed with two rubber septa and vacuum adapter with a stopcock. The flask was removed from the glovebox and connected to a Schlenk line. The flask was fitted with a reflux condenser and pressure-equalizing addition funnel under N2 flow. A solution of α,α′-di­bromo-o-xylene (50.2 g, 190 mmol, 1 equiv) in 100 mL of anhydrous THF was prepared and transferred to the addition funnel. This solution was added dropwise to the Li suspension with vigorous stirring under an N2 atmosphere. After ∼1/4 of this solution had been added, the reaction mixture began to reflux, and the addition was paused to allow the exotherm to subside. After 5 min, the dropwise addition was resumed, taking 1 h to add the remaining solution. The addition funnel was replaced with a glass stopper and the reaction mixture was heated at reflux overnight under N2. Complete consumption of the starting material was confirmed by TLC in petroleum ether. The reaction flask was cooled in an ice bath and the reaction mixture was then carefully filtered over a glass frit to remove unreacted Li. The filtrate was concentrated in vacuo and was re-suspended in 200 mL of CH2Cl2. The resulting suspension was filtered over a pad of silica gel and the silica gel pad was washed with an additional 200 mL of CH2Cl2. The combined filtrates were dried over Na2SO4 and concentrated in vacuo, yielding 20.7 g of viscous yellow oil that solidified upon standing. The crude product was further purified via Kugelrohr distillation at 463 K under vacuum to afford the pure product as a white crystalline solid.

Synthesis of di­nitro dibenzo­cyclo­octane (DNDBCO)

DBCO (4.55 g, 21.9 mmol, 1 equiv) was dissolved in 200 mL of CH2Cl2 in a round-bottom flask equipped with a stir bar. The flask was fitted with a pressure-equalizing addition funnel and was placed in an ice bath. To the flask was added 25 mL HNO3 (∼20 equiv) dropwise via the addition funnel at 273 K. During the addition, the reaction mixture developed a deep red color. The flask was removed from the ice bath and allowed to warm to room temperature. The reaction mixture was stirred at room temperature for 2 h, during which time the color of the reaction mixture changed from deep red to yellow–orange. The reaction mixture was poured into a beaker containing 300 mL of cold deionized (DI) H2O to quench the reaction, and this biphasic mixture was transferred to a separatory funnel. The aqueous layer was discarded, and the organic layer was washed subsequently with DI H2O, saturated NaHCO3 solution (2×), and brine, dried over Na2SO4, filtered, and concentrated in vacuo. Upon further drying under vacuum, a yellow solid was obtained that was used in the next step without further purification.

Synthesis of di­amino dibenzo­cyclo­octane (DADBCO)

A three-necked round-bottom flask equipped with a stir bar was charged with 10% Pd/C (0.89 g, 5 mol% Pd relative to DNDBCO). The flask was fitted with two rubber septa and a vacuum adapter and was placed under an N2 atmosphere. To the flask was added 150 mL of MeOH followed by DNDBCO (5.05 g, 16.9 mmol, 1 equiv) under N2 flow. The rubber septa were replaced with vacuum adapters attached to H2-filled balloons, and the N2 atmosphere was exchanged for H2 via five vacuum/H2-back-fill cycles. The reaction mixture was then stirred overnight at room temperature under H2, over which time the solid DNDBCO slowly dissolved. The complete consumption of the starting material was confirmed by TLC in 2:1 hexa­ne/ethyl acetate. The reaction mixture was filtered over a pad of celite to remove the Pd/C and the filtrate was concentrated in vacuo. The resulting dark-red oil was re-dissolved in 1M HCl solution and was washed with CH2Cl2 (3×). The pH of the solution was then adjusted to pH >10 using ∼4M NaOH solution, and the precipitated product was extracted with EtOAc (2×). The combined EtOAc solutions were washed with DI H2O and brine, dried over Na2SO4, filtered, and concentrated in vacuo. Further drying under vacuum afforded the product as a light-pink solid (3.05 g, 76% yield). Note: DADBCO was obtained as a mixture of isomers, where the ratio of ortho/meta anilines was ∼2:3. The various isomers could be isolated via exhaustive silica gel chromatography, eluting with a gradient from 0–50% EtOAc in hexane. In particular, the 2,2′ and 2,3′ isomers were suspected as the last and second to last compounds that eluted from the column, respectively. A suitable crystal of the 2,2′ material was grown for XRD analysis by allowing a saturated hot toluene solution to cool to room temperature over several hours followed by further cooling to 273 K.

6. Refinement

Crystal data, data collection, and structure refinement details are summarized in Table 2[link]. The hydrogen atoms on N2 were placed with a riding-bond model, whereas the hydrogen atoms on N1 were placed manually to match observed electron density. The distance of the manually placed atoms was constrained with DFIX and for the hydrogen atoms on N1 the isotropic thermal parameters were refined without constraints. All other H atoms were generated via the riding-bond model and refined with U(H) = 1.2Ueq(C/N). The absolute structure was not determined due to the absence of heavy atoms (Flack parameter = 0.3), and the inversion twin law was used for refinement.

Table 2
Experimental details

Crystal data
Chemical formula C16H18N2
Mr 238.32
Crystal system, space group Orthorhombic, Pna21
Temperature (K) 100
a, b, c (Å) 8.8641 (3), 22.0075 (6), 6.2771 (2)
V3) 1224.52 (7)
Z 4
Radiation type Cu Kα
μ (mm−1) 0.59
Crystal size (mm) 0.1 × 0.1 × 0.01
 
Data collection
Diffractometer Bruker APEXII CCD
Absorption correction Multi-scan (SADABS; Krause et al., 2015[Krause, L., Herbst-Irmer, R., Sheldrick, G. M. & Stalke, D. (2015). J. Appl. Cryst. 48, 3-10.])
Tmin, Tmax 0.459, 0.754
No. of measured, independent and observed [I > 2σ(I)] reflections 39813, 2060, 1781
Rint 0.118
(sin θ/λ)max−1) 0.588
 
Refinement
R[F2 > 2σ(F2)], wR(F2), S 0.046, 0.106, 1.08
No. of reflections 2060
No. of parameters 173
No. of restraints 172
H-atom treatment H atoms treated by a mixture of independent and constrained refinement
Δρmax, Δρmin (e Å−3) 0.18, −0.22
Absolute structure Refined as an inversion twin
Absolute structure parameter 0.3 (12)
Computer programs: APEX2 and SAINT (Bruker, 2019[Bruker (2019). APEX2 and SAINT. Bruker AXS Inc., Madison, Wisconsin, USA.]), SHELXT (Sheldrick, 2015a[Sheldrick, G. M. (2015a). Acta Cryst. A71, 3-8.]), SHELXL (Sheldrick, 2015b[Sheldrick, G. M. (2015b). Acta Cryst. C71, 3-8.]), and OLEX2 (Dolomanov et al., 2009[Dolomanov, O. V., Bourhis, L. J., Gildea, R. J., Howard, J. A. K. & Puschmann, H. (2009). J. Appl. Cryst. 42, 339-341.]).

Supporting information

CCDC reference: 2355133

Crystal structure: contains datablock I. DOI: https://doi.org/10.1107/S2056989024004468/vm2301sup1.cif

Structure factors: contains datablock I. DOI: https://doi.org/10.1107/S2056989024004468/vm2301Isup2.hkl

PLATON outputs and SHELX plane calculations. DOI: https://doi.org/10.1107/S2056989024004468/vm2301sup3.docx

Supporting information file. DOI: https://doi.org/10.1107/S2056989024004468/vm2301Isup4.cml

checkCIF report


Computing details top

2,9-Diamino-5,6,11,12-tetrahydrodibenzo[a,e][8]annulene top
Crystal data top
C16H18N2Dx = 1.293 Mg m3
Mr = 238.32Cu Kα radiation, λ = 1.54178 Å
Orthorhombic, Pna21Cell parameters from 8510 reflections
a = 8.8641 (3) Åθ = 4.0–73.6°
b = 22.0075 (6) ŵ = 0.59 mm1
c = 6.2771 (2) ÅT = 100 K
V = 1224.52 (7) Å3Needle, clear light green
Z = 40.1 × 0.1 × 0.01 mm
F(000) = 512
Data collection top
Bruker APEXII CCD
diffractometer		1781 reflections with I > 2σ(I)
φ and ω scansRint = 0.118
Absorption correction: multi-scan
(SADABS; Krause et al., 2015)		θmax = 65.0°, θmin = 4.0°
Tmin = 0.459, Tmax = 0.754h = 1010
39813 measured reflectionsk = 2525
2060 independent reflectionsl = 67
Refinement top
Refinement on F2Hydrogen site location: mixed
Least-squares matrix: fullH atoms treated by a mixture of independent and constrained refinement
R[F2 > 2σ(F2)] = 0.046 w = 1/[σ2(Fo2) + (0.0353P)2 + 0.9951P]
where P = (Fo2 + 2Fc2)/3
wR(F2) = 0.106(Δ/σ)max < 0.001
S = 1.08Δρmax = 0.18 e Å3
2060 reflectionsΔρmin = 0.22 e Å3
173 parametersAbsolute structure: Refined as an inversion twin
172 restraintsAbsolute structure parameter: 0.3 (12)
Primary atom site location: shelXT
Special details top

Geometry. All esds (except the esd in the dihedral angle between two l.s. planes) are estimated using the full covariance matrix. The cell esds are taken into account individually in the estimation of esds in distances, angles and torsion angles; correlations between esds in cell parameters are only used when they are defined by crystal symmetry. An approximate (isotropic) treatment of cell esds is used for estimating esds involving l.s. planes.

Refinement. Refined as a 2-component inversion twin.

Fractional atomic coordinates and isotropic or equivalent isotropic displacement parameters (Å2) top
xyzUiso*/Ueq
N10.8644 (4)0.33304 (16)0.4674 (6)0.0276 (8)
H1A0.855 (5)0.325 (2)0.332 (4)0.058 (18)*
H1B0.950 (4)0.321 (2)0.516 (7)0.052 (16)*
N20.3459 (4)0.76938 (14)0.2091 (6)0.0295 (9)
H2A0.2937460.7486040.1142190.035*
H2B0.2845180.7937240.2795380.035*
C110.7832 (4)0.43707 (17)0.3906 (6)0.0205 (9)
H110.7500580.4243260.2537570.025*
C120.7645 (4)0.49766 (16)0.4496 (6)0.0181 (8)
C130.8118 (4)0.51680 (17)0.6518 (6)0.0186 (8)
C140.8763 (4)0.47369 (16)0.7896 (7)0.0211 (8)
H140.9089010.4859740.9272030.025*
C150.8932 (4)0.41367 (17)0.7284 (7)0.0228 (9)
H150.9352840.3852790.8256440.027*
C160.8497 (4)0.39431 (17)0.5276 (7)0.0217 (9)
C310.6953 (4)0.54170 (17)0.2940 (6)0.0195 (8)
H31A0.6924180.5224570.1515410.023*
H31B0.7609250.5779850.2840190.023*
C320.5330 (4)0.56256 (16)0.3539 (6)0.0192 (8)
H32A0.4670570.5564220.2284750.023*
H32B0.4952080.5357890.4688960.023*
C330.7993 (4)0.58216 (16)0.7233 (7)0.0214 (8)
H33A0.8364320.6086050.6069800.026*
H33B0.8666890.5881570.8472360.026*
C340.6377 (4)0.60340 (17)0.7861 (6)0.0217 (8)
H34A0.5728480.5670630.8022130.026*
H34B0.6429900.6237020.9266140.026*
C210.4468 (4)0.66922 (16)0.2906 (7)0.0205 (8)
H210.4184450.6565570.1514990.025*
C220.5171 (4)0.62758 (17)0.4262 (6)0.0182 (8)
C230.5629 (4)0.64650 (17)0.6289 (6)0.0213 (8)
C240.5334 (5)0.70611 (17)0.6907 (7)0.0269 (9)
H240.5640020.7192580.8282070.032*
C250.4600 (5)0.74720 (19)0.5557 (7)0.0287 (10)
H250.4397450.7874380.6024010.034*
C260.4170 (4)0.72879 (17)0.3533 (7)0.0235 (9)
Atomic displacement parameters (Å2) top
U11U22U33U12U13U23
N10.0259 (19)0.0224 (18)0.034 (2)0.0023 (15)0.0022 (17)0.0011 (16)
N20.0270 (18)0.0243 (18)0.037 (2)0.0035 (14)0.0119 (16)0.0037 (15)
C110.0109 (18)0.026 (2)0.025 (2)0.0010 (15)0.0004 (15)0.0018 (16)
C120.0108 (17)0.0217 (19)0.022 (2)0.0020 (15)0.0000 (16)0.0021 (16)
C130.0106 (17)0.0234 (18)0.022 (2)0.0013 (15)0.0018 (16)0.0004 (16)
C140.0129 (17)0.027 (2)0.023 (2)0.0011 (15)0.0004 (16)0.0019 (17)
C150.0153 (18)0.027 (2)0.026 (2)0.0022 (16)0.0008 (17)0.0042 (18)
C160.0179 (19)0.0185 (19)0.029 (2)0.0003 (15)0.0041 (17)0.0010 (17)
C310.0152 (18)0.0242 (19)0.019 (2)0.0001 (15)0.0003 (16)0.0019 (16)
C320.0140 (17)0.0197 (19)0.024 (2)0.0009 (14)0.0024 (16)0.0010 (15)
C330.0175 (18)0.0240 (19)0.023 (2)0.0017 (15)0.0000 (17)0.0019 (16)
C340.0232 (19)0.0210 (18)0.021 (2)0.0029 (16)0.0043 (17)0.0023 (16)
C210.0157 (18)0.0207 (18)0.025 (2)0.0007 (15)0.0031 (17)0.0004 (16)
C220.0141 (18)0.0189 (19)0.022 (2)0.0010 (14)0.0011 (16)0.0018 (15)
C230.0186 (19)0.0215 (19)0.024 (2)0.0000 (15)0.0030 (17)0.0006 (16)
C240.031 (2)0.023 (2)0.027 (2)0.0030 (18)0.0071 (17)0.0039 (18)
C250.032 (2)0.022 (2)0.032 (3)0.0022 (18)0.0055 (19)0.0045 (18)
C260.0185 (19)0.0217 (19)0.030 (2)0.0010 (16)0.0073 (17)0.0034 (17)
Geometric parameters (Å, º) top
N1—H1A0.87 (2)C31—C321.556 (5)
N1—H1B0.86 (2)C32—H32A0.9900
N1—C161.406 (5)C32—H32B0.9900
N2—H2A0.8817C32—C221.508 (5)
N2—H2B0.8824C33—H33A0.9900
N2—C261.419 (5)C33—H33B0.9900
C11—H110.9500C33—C341.557 (5)
C11—C121.394 (5)C34—H34A0.9900
C11—C161.404 (5)C34—H34B0.9900
C12—C131.401 (5)C34—C231.520 (5)
C12—C311.506 (5)C21—H210.9500
C13—C141.406 (5)C21—C221.398 (5)
C13—C331.511 (5)C21—C261.394 (5)
C14—H140.9500C22—C231.399 (6)
C14—C151.384 (5)C23—C241.393 (5)
C15—H150.9500C24—H240.9500
C15—C161.385 (6)C24—C251.400 (6)
C31—H31A0.9900C25—H250.9500
C31—H31B0.9900C25—C261.387 (6)
H1A—N1—H1B111 (4)C22—C32—C31116.1 (3)
C16—N1—H1A116 (3)C22—C32—H32A108.3
C16—N1—H1B107 (3)C22—C32—H32B108.3
H2A—N2—H2B109.3C13—C33—H33A108.4
C26—N2—H2A109.7C13—C33—H33B108.4
C26—N2—H2B109.6C13—C33—C34115.4 (3)
C12—C11—H11119.1H33A—C33—H33B107.5
C12—C11—C16121.9 (4)C34—C33—H33A108.4
C16—C11—H11119.1C34—C33—H33B108.4
C11—C12—C13119.5 (4)C33—C34—H34A108.5
C11—C12—C31119.5 (4)C33—C34—H34B108.5
C13—C12—C31121.0 (3)H34A—C34—H34B107.5
C12—C13—C14118.4 (4)C23—C34—C33115.1 (3)
C12—C13—C33122.2 (3)C23—C34—H34A108.5
C14—C13—C33119.3 (3)C23—C34—H34B108.5
C13—C14—H14119.4C22—C21—H21119.0
C15—C14—C13121.1 (4)C26—C21—H21119.0
C15—C14—H14119.4C26—C21—C22121.9 (4)
C14—C15—H15119.5C21—C22—C32118.7 (3)
C14—C15—C16121.1 (4)C21—C22—C23119.2 (3)
C16—C15—H15119.5C23—C22—C32121.9 (3)
C11—C16—N1121.1 (4)C22—C23—C34122.1 (3)
C15—C16—N1120.9 (4)C24—C23—C34119.3 (4)
C15—C16—C11117.9 (3)C24—C23—C22118.6 (4)
C12—C31—H31A108.7C23—C24—H24119.1
C12—C31—H31B108.7C23—C24—C25121.8 (4)
C12—C31—C32114.2 (3)C25—C24—H24119.1
H31A—C31—H31B107.6C24—C25—H25120.2
C32—C31—H31A108.7C26—C25—C24119.6 (4)
C32—C31—H31B108.7C26—C25—H25120.2
C31—C32—H32A108.3C21—C26—N2119.7 (4)
C31—C32—H32B108.3C25—C26—N2121.5 (4)
H32A—C32—H32B107.4C25—C26—C21118.8 (4)
C11—C12—C13—C140.3 (5)C31—C32—C22—C21108.3 (4)
C11—C12—C13—C33178.1 (3)C31—C32—C22—C2375.3 (4)
C11—C12—C31—C32108.7 (4)C32—C22—C23—C342.6 (5)
C12—C11—C16—N1178.4 (3)C32—C22—C23—C24174.8 (4)
C12—C11—C16—C151.8 (5)C33—C13—C14—C15178.4 (3)
C12—C13—C14—C150.0 (5)C33—C34—C23—C2268.8 (5)
C12—C13—C33—C3476.1 (5)C33—C34—C23—C24113.8 (4)
C12—C31—C32—C22109.5 (4)C34—C23—C24—C25177.7 (4)
C13—C12—C31—C3271.9 (4)C21—C22—C23—C34179.0 (3)
C13—C14—C15—C161.3 (5)C21—C22—C23—C241.6 (5)
C13—C33—C34—C23107.9 (4)C22—C21—C26—N2179.7 (3)
C14—C13—C33—C34105.6 (4)C22—C21—C26—C250.7 (6)
C14—C15—C16—N1178.8 (3)C22—C23—C24—C250.2 (6)
C14—C15—C16—C112.1 (5)C23—C24—C25—C261.0 (6)
C16—C11—C12—C130.6 (5)C24—C25—C26—N2178.3 (4)
C16—C11—C12—C31178.8 (3)C24—C25—C26—C210.7 (6)
C31—C12—C13—C14179.7 (3)C26—C21—C22—C32174.7 (3)
C31—C12—C13—C331.3 (5)C26—C21—C22—C231.9 (5)
Hydrogen-bond geometry (Å, º) top
Cg1 and Cg2 are the centroids of rings C11–C16 and C21–C26, respectively.
D—H···AD—HH···AD···AD—H···A
N1—H1B···N2i0.86 (4)2.46 (4)3.295 (5)165 (4)
N2—H2A···N1ii0.882.463.295 (5)159
N2—H2B···Cg2iii0.882.963.742 (4)149
C14—H14···Cg1iv0.952.843.572 (4)135
C32—H32A···Cg1ii0.992.783.640 (4)145
Symmetry codes: (i) x+3/2, y1/2, z+1/2; (ii) x+1, y+1, z1/2; (iii) x1/2, y+3/2, z+1/2; (iv) x+2, y+1, z+1/2.
 

Acknowledgements

This research was supported by the Laboratory Directed Research and Development program at Sandia National Laboratories, a multimission laboratory managed and operated by National Technology and Engineering Solutions of Sandia LLC, a wholly owned subsidiary of Honeywell Inter­national Inc. for the US Department of Energy's National Nuclear Security Administration under Contract DE-NA0003525. This paper describes objective technical results and analysis. Any subjective views or opinions that might be expressed in the paper do not necessarily represent the views of the US Department of Energy or the United States Government.

References

First citationBiron, M. (2013). Editor. Thermosets and Composites, 2nd ed., ch. 6 Composites, pp 299–243. Oxford: William Andrew Publishing. https://doi.org/10.1016/B978-1-4557-3124-4.00006-7  Google Scholar
 First citationBrostow, W., Goodman, S. & Wahrmund, J. (2014). Handbook of Thermoset Plastics, 3rd ed., edited by H. Dodiuk & S. Goodman, ch. 8 Epoxies, pp 191–252. Boston: William Andrew Publishing. https://doi.org/10.1016/B978-1-4557-3107-7.00008-7  Google Scholar
 First citationBruker (2019). APEX2 and SAINT. Bruker AXS Inc., Madison, Wisconsin, USA.  Google Scholar
 First citationCremer, D. & Pople, J. A. (1975). J. Am. Chem. Soc. 97, 1354–1358.  CrossRef CAS Web of Science Google Scholar
 First citationDickie, R., Labana, S. & Bauer, R. (1988). Editors. Cross-Linked Polymers: Chemistry, Properties, and Applications, vol 367. Washington, D. C.: American Chemical Society. https://doi.org/10.1021/bk-1988-0367.fw001  Google Scholar
 First citationDolomanov, O. V., Bourhis, L. J., Gildea, R. J., Howard, J. A. K. & Puschmann, H. (2009). J. Appl. Cryst. 42, 339–341.  Web of Science CrossRef CAS IUCr Journals Google Scholar
 First citationDomiano, P., Cozzini, P., Claramunt, R. M., Lavandera, J. L., Sanz, D. & Elguero, J. (1992). J. Chem. Soc. Perkin Trans. 2, pp. 1609–1620.  CSD CrossRef Google Scholar
 First citationFoster, J., Staiger, C., Dugger, J. & Redline, E. (2021). ACS Macro Lett. 10, 940–944.  CrossRef CAS PubMed Google Scholar
 First citationFranck, G., Brill, M. & Helmchen, G. (2012). Org. Syn. 89, 55–65.  CAS Google Scholar
 First citationFu, W., Alam, T., Li, J., Bustamante, J., Lien, T., Adams, R. W., Teat, S. J., Stokes, B., Yang, W., Liu, Y. & Lu, J. (2020). J. Am. Chem. Soc. 142, 16651–16660.  CSD CrossRef CAS PubMed Google Scholar
 First citationGroom, C. R., Bruno, I. J., Lightfoot, M. P. & Ward, S. C. (2016). Acta Cryst. B72, 171–179.  Web of Science CrossRef IUCr Journals Google Scholar
 First citationGuo, Q. (2018). Editor.Thermosets, 2nd ed., ch. 8–13. Amsterdam: Elsevier. ISBN: 978-0081010211  Google Scholar
 First citationKrause, L., Herbst-Irmer, R., Sheldrick, G. M. & Stalke, D. (2015). J. Appl. Cryst. 48, 3–10.  Web of Science CSD CrossRef ICSD CAS IUCr Journals Google Scholar
 First citationMiyoshi, H., Sugiura, R., Kishi, R., Spisak, S. N., Wei, Z., Muranaka, A., Uchiyama, M., Kobayashi, N., Chatterjee, S., Ie, Y., Hisaki, I., Petrukhina, M. A., Nishinaga, T., Nakano, M. & Tobe, Y. (2022). Angew. Chem. Int. Ed. 61, e202115316.  CSD CrossRef Google Scholar
 First citationOkura, J., Shetty, S., Ramakrishnan, B., Dasgupta, A., Caers, J. F. J. M. & Reinikainen, T. (2000). Microelectron. Reliab. 40, 1173–1180.  CrossRef Google Scholar
 First citationPascault, J., Sautereau, H., Verdu, J. & Williams, R. (2002). Thermosetting Polymers. New York: CRC Press. ISBN: 978-0429208072  Google Scholar
 First citationSheldrick, G. M. (2015a). Acta Cryst. A71, 3–8.  Web of Science CrossRef IUCr Journals Google Scholar
 First citationSheldrick, G. M. (2015b). Acta Cryst. C71, 3–8.  Web of Science CrossRef IUCr Journals Google Scholar
 First citationShen, X., Viney, C., Johnson, E., Wang, C. & Lu, J. (2013). Nat. Chem. 5, 1035–1041.  CrossRef CAS PubMed Google Scholar
 First citationVreugd, J. de, Jansen, K., Ernst, L. & Bohm, C. (2010). Microelectron. Reliab. 50, 910–916.  Google Scholar
 First citationWang, Z., Huang, Y., Guo, J., Li, Z., Xu, J., Lu, J. & Wang, C. (2018). Macromolecules, 51, 1377–1385.  CrossRef CAS Google Scholar

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Volume 80| Part 6| June 2024| Pages 645-648
https://doi.org/10.1107/S2056989024004468
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