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Crystal lattice free volume in a study of initiation reactivity of nitramines:Impact sensitivity

更新时间:2016-07-05

1.Introduction

Sensitivity of energetic materials(EMs)is inherently connected with chemical reactivity of these materials and/or of their components(see for example Refs[1,2]and quotations herein).For that reason it is on the spot heretospeak about initiation reactivity[1,2].As such the reactivity depends on molecular structure and state of matter of the given EM and also on its possible admixtures.By transmission of these facts into one from the most studied reactivity,i.e.into impact sensitivity,we can say that it is a combination of three fundamental sensitivities[3]:molecular,crystalline and environmental.From the point of view of the physical organic chemistry,the first one of these have been extensively studied for individual organic energetic materials(EMs)by means of the NMR chemical shifts of the key atoms in the reaction centers and by means of the modified Evans-Polaniy-Semenov relation(see papers[1,2,4,5]and citations herein);at the same time the crystalline aspects of impact sensitivity were studied by means of heats of fusion for such compounds[1,4].However,intensive application of quantum chemical methods in the study of EMs in general is head and shoulders above the mentioned chemical approach,also in the study of their initiation reactivity[1,2,6-9].The main problem is here that quantum chemical calculations and simulations start from certain opinions held by their authors,and the results correspond to this fact.Relatively often also only several substances are studied or more EMs but with essentially different structures,even though already Politzer and Murray have shown that the correlations found here[10]are restricted to specific classes(i.e.nitroaromatics,nitroheterocycles and nitramines)which is in a perfect conformity with findings from approaches on the basis of physical organic chemistry(see Refs.[1,2,4]and citations herein).Similar restriction can be newly documented also on the basis of application of the free spaces in crystals(FSIC)in a study notonlyof impact but also other kind of the EMs sensitivity;this paper deals with the first one from them.

At these free spaces an attention was aimed[11-15]on the base of very important finding[16,17]which can be verified on the basis of an X-ray crystallographic study of some polynitroarenes[18-20]and of cis-1,3,4,6-tetranitrooctahydroimidazo-[4,5-d]imidazole(BCHMX)[21]:the decisive factors governing the crystal structure particularly of nitramines,are the dipole-dipole interactions of the oxygen and nitrogen atoms of nitro groups in neighboring nitramine molecules in the crystal[16,21-25];A very important finding from the referenced studies,which still needs further investigation,is that non-binding inter-atomic distances between oxygen atoms inside all of the nitro groups in these poly-nitro compounds are shorter than those corresponding to the intermolecular contact radii for oxygen in carbonyl or nitro groups[19-22];this distance is especially short inside the most reactive nitro groups[19-21].These facts have research on free spaces in crystals of EMs and of their in fluence on the EMs impact sensitivity[11-15]but without taking account important molecular-structural similarity[2];therefore,the mentioned papers need some elaboration.This is realized in this paper using extended number of structurally similar compounds.For this purpose a group of nitramines was elected in this paper as energetic materials which in their molecular structure are relatively simple polynitro compounds,and the mechanism of primary homolysis of their molecules is well understood[1,7,26-29].

2.Data sources

2.1.Studied nitramines

Chemical names,code designations and impact sensitivity,expressed as a drop energy(Edr),of the studied nitramines are summarized in Table 1.For a better illustrative nature also structural formulas of these nitramines are presented in Scheme 1.

2.2.Impact sensitivity

The impact sensitivity data of the nitramines studied,shown in Table 1,have been taken from respectable literature[12,21,30-38]:they were obtained by means of a standard impact tester with an exchangeable anvil(Julius Peters),detection of the 50%probability of initiation being based on acoustic detection(Bruceton method)[30-38].The data considered were the drop energies,Edr,obtained by conversion of drop heights values,h50%;it is due to unification of outputs of measurements with different weights of drop hammers.Accuracy of this approach is verified by relationship between logarithm of the Edrvalues and15N NMR chemical shifts of aza nitrogen atoms in reaction centres of the studied nitramines[1,2,4].

本文提出的识别方法整体流程如图1所示。首先利用脚部IMU采集人员运动时IMU坐标系下的三轴加速度和三轴角速度数据。其次根据三轴加速度信息使用峰值检测的方法对运动过程进行单步的划分,定义每两个峰值之间的数据为一个单步[14],获得每一个单步的起始位置和终止位置。然后取出每一个单步起始位置和终止位置之间的三轴加速度和三轴角速度信息即为单步惯性数据。接着我们从每个单步惯性数据中提取选定的65维统计特征用来表征当前单步的速度,将65维统计特征输入到利用大量单步统计特征-速度数据训练好的识别模型之中即可以获得速度识别结果。

2.3.Results of calculation for crystal lattice free volume of nitramine explosives

All of the compounds were optimized at computational level of B3LYP/6-311+g(d,p)by using software Gaussian 09.The crystal volume[V(0.003)]was calculated by using software Multiwfn 3.3.9.The effective volume per molecule(Veff)is calculated as:Veff=M/d,where M is molecular mass,d is crystal density.The intrinsic gas phase molecular volume(Vint)is calculated by the 0.003 au surface according to Ref.[13],Vint=V(0.003).Therefore,the free space per molecule(ΔV)is

这件《实征税粮簿》表明,至正二十八年闰七月元惠宗妥欢贴睦尔退出元大都之后,在偏远的亦集乃路,税粮征收仍在照常进行。文书上的朱书畏兀体蒙古字可能是当地蒙古或色目吏员所写。

3.Results and discussion

小学生认识事物主要是从感知形象开始。教材中都配有精美的插图,这些插图是针对小学生一般的心理和生理特点而精心设计的,往往能紧扣文本内容,是文本的补充和延伸。因此,教师在教学时可以巧妙地利用插图,引导学生观察,帮助他们积累丰富的表象,训练他们用生动的语句,把所感知的表象准确连贯地表达出来,从而更好地走进课文情境,感悟课文内容。

It is needed to be aware of a possibility that during the impact attack of crystals not only of their compressibility(uniaxial compression)has its share of the given EM decomposition.In dependence on direction of the impact action on main crystal planes also sliding(shear slidewith fixed volume)might have share in initiation:in our recent paper[44]we have intimated relations between impact sensitivity of several nitramine explosives and their bulk(K)and/or shear(G)moduli.But the best ever the relationship for these EMs we found between the mentioned sensitivity and a ratio of these moduli,K.G-1[44]which represents the extent of the plasticity range of the given material(plastic deformations of crystals,together with dislocations,does in the initiation of crystallic energetic materials by the mechanical impulses a decisive role[1,45]).Also here the molecular structural similarity has its in fluence[44].For that matter likewise a semilogarithmic relationship between impact and Friction sensitivities of the nitramines is divided into a number of partial relations which are closelycoherent with the molecular-structural characteristics of these compounds[46].Importance and possible principles of the molecular-structural similarity in a study of the EMs sensitivity are mentioned inpaper[2].All so far mentioned facts signalize a higher importance of the intermolecular interactions in a crystal lattice in comparison with importance of the crystal lattice free volume for impact reactivity of the studied energetic materials.This statement perfectly conforms to the already here cited importance of the dipole-dipole interactions of the oxygen and nitrogen atoms of nitro groups in neighboring nitramine molecules for the crystal structure of these nitro compounds[16,21-25].

Results of these calculations are summarized inTable 2,together with crystal densities of the studied nitramines.

A simple mutual comparing of impact sensitivity(i.e.drop energy,Edr)and the crystal lattice free volume values,ΔV,of the studied nitramines gave a different picture as was shown recently on the 8 nitramines and 17 polynitro compounds of other structures[11-15];according to these papers an increasing of theΔV values should correspond semi-logarithmically to increase,more or less,impact sensitivity.Molecular-structural analysis of the general picture in this paper though does not give like that unambiguous conclusion and leads to Figs.1 and 2 with linear relationships.

Table 1 A survey of the studied nitramines and their impact sensitivities(Edr).

No Chemical name Code design. Drop energy/J Edr Ref 1 1,4-Dinitro-1,4-diazabutane EDNA 8.33 [31]2 2,5-Dinitro-2,5-diazahexane DMEDNA 21.04 [30]3 1,3,3-Trinitroazetidine TNAZ 6.90 [32]4 1,3-Dinitro-1,3-diazetidine TETROGEN 9.97 [35]5 1,3-Dinitroimidazolidine CPX 17.96 [35]6 1,4-Dinitropiperazine DNDC 11.67 [35]7 1,3,5-Trinitro-1,3,5-triazinane RDX 5.58 [31]8 1,3,5-Trinitro-1,3,5-triazepane HOMO 4.55 [35]9 1,3,5,7-Tetranitro-1,3,5,7-tetrazocane β-HMX 6.37 [31]10 cis-1,3,4,6-Tetranitrooctahydro-imidazo-[4,5-d]imidazole BCHMX,bicyclo-HMX 2.98 [21]11 1,4-Dinitrotetrahydroimidazo[4,5-d]imidazol-2,5-(1H,3H)-dione DINGU 24.54 [38]12 trans-1,4,5,8-Tetranitrodecahydro-pyrazino[2,3-b]pyrazine TNAD 8.58 [33]13 1,3,5,7,9-Pentanitro-1,3,5,7,9-pentazocane DECAGEN 4.90 [35]14 4,10-Dinitro-2,6,8,12-tetraoxa-4,10-diaza-isowurtzitane TEX 23.00 [12]15 4,8,10,12-Tetranitro-2,6-dioxa-4,8,10,12-tetraaza-isowurtzitane TNIW-5,Aurora-5 12.54 [35]16.1 2,4,6,8,10,12-Hexanitro-2,4,6,8,10,12-hexaazaisowurtzitane ε-HNIW pure 13.2 [34]16.2 ε-HNIW technical 4.10 [36]16.3 β-HNIW 11.9 [34]16.4 γ-HNIW 12.2 [34]17 bis-N,N-(2,2,2-Trinitroethyl)nitramine HOX 1.20 [31]18 N-Methyl-N,2,4,6-tetranitroaniline TETRYL 7.85 [37]

Scheme 1.Structural formulas of the studied nitramines.

Table 2 A survey of the molecular mass,M,crystal densities,d,intrinsic gas phase volume,Vint,crystal volume,V(0.003)and free space per molecule,ΔV.

Note:TheΔV values listed in brackets are taken from Ref.[13].The crystal density value for Decagen was calculated.

Compound Molecular weight M/×10-24/g Crystal density/(g·cm-3)Veff/Å3 V(0.003)/Å3 ΔV/Å3 No. Code designation 1 EDNA 150.1 249.34 1.65 151.12 119.69 31.43 2 DMEDNA 178.1 295.85 1.45 204.03 153.19 50.84 3 TNAZ 192.1 319.10 1.86 171.56 139.26 32.30(37)4 TETROGEN 148.1 246.01 1.81 135.92 110.67 25.25 5 CPX 162.1 269.27 1.65 163.19 126.03 37.16 6 DNDC 176.1 292.52 1.63 179.46 142.23 37.23 7 RDX 222.1 368.94 1.81 203.83 161.97 41.86(46)8 HOMO 236.1 392.19 1.77 221.58 178.06 43.52 9 HMX 296.2 492.03 1.91 257.61 214.79 42.82(49)10 BCHMX 294.2 488.70 1.92 254.53 206.06 48.47 11 DINGU 232.1 385.55 1.99 193.74 162.34 31.40 12 TNAD 322.2 535.22 1.84 290.88 237.96 52.92 13 DECAGEN 370.2 614.95 1.89(cal.) 325.37 269.20 56.17 14 TEX 262.2 435.55 1.99 218.87 179.33 39.54 15 AURORA 5 350.2 581.73 2.01 289.42 235.16 54.26 16 ε-HNIW 438.2 727.91 2.04 356.82 290.84 65.98 17 HOX 388.1 644.68 1.96 328.92 262.11 66.81 18 TETRYL 287.1 476.91 1.73 275.67 210.47 65.20

Fig.1.Molecular-structural analysis of the mutual relationship of impact sensitivity,expressed as a drop energy,Edr,and free space per molecule,ΔV-a relationship with the negative slope.

Lines with positive slopes in Fig.2 strongly demonstrate molecular structural similarity.Namely line I,by a sign of its slope and also by composition of the corresponding group,is almost identical with those which create exception from semilogarithmic relationship between impact sensitivity and volume heat of explosion[2];in other words this exception is valid also in the case of Fig.2 and it would be needed more detailed quantum chemical analysis.Nevertheless,in the case of lines G and I their trend relates with crossing from planar to the globular molecular systems.Line H unites data of the EDNA derivatives,here crossing from primary to secondary cyclic nitramine DNDC and then to flexible molecule of dimethylated EDNA(i.e.DMEDNA-methyl groups are a good flegmatizing groups).

Lines with negative slopes in Fig.1 represent groups of nitramines in each from which a similarity of molecular structure plays certainrole.Some exception is line F,grouping structurally different nitramines which,however,might have similar con figuration in their reaction centers,i.e.of nitramino groupings(in HNIW it is inposition 2 which is not planar[34,39]):2,2,2-trinitroethyl groups in the HOX molecule are not mutually equivalent in light of the intermolecular interactions in its crystals[40],a big mutual difference is between steric and inductive effects of the picryl and methyl groups in Tetryl(nitramino group here is not planar,N-methylnitramo group is rotated by 65°out of the benzene ring plane and weak hydrogen bond exists between oxygen atom of nitramino group and hydrogen atom in the position 5 of the benzene ring[41]).Position of data of the technical ε-HNIW in Fig.1 re flects in fluence of its imperfect crystal structure(eventually also of its impurities)on impact sensitivity[2,4]which manifests also in thermal reactivity of different qualitative kinds of this nitramine(big differences in Arrhenius parameters of their thermolysis[42,43]).It all should be due to difference in intermolecularinteractions in imperfect crystal lattice of this kind of HNIW in comparison with its perfect crystal(see in Ref.[34]and partially in[40])-distribution of the actions of force in its crystal lattice as though to remind of those in Aurora 5 and TEX,to which also position of its data at line C corresponds.Crystal structure of this“very sensitive”sort of HNIW needs more detailed study in comparison with its RS(reduced sensitivity[2,36])or chemically pure polymorphs[34].Difference between lines B and C clearly shows in fluence of transition from relatively planar nitramine molecules to their globular analogues.In structures of the nitramines molecules,associated with line D,is possible to find the DMEDNA molecular skeleton.Positions of the HNIW data for all its polymorphic modifications and also of its “normal”quality in Figs.1 and 2 have connection with approach to theΔV values calculation,i.e.by means of eqn.(1),in which optimal con figuration of isolated molecules are take in account.From the same reason a molecular-structural similarity as if has substituted of a real action of the intermolecular forces here.

4.Conclusions

More detailed analysis of a mutual relationship of impact sensitivity(detected by sound)and crystal lattice free volume,ΔV,for the 18 nitramines shows that increase of theΔV values corresponds to enhance of this sensitivity but also fairly big number of nitramines are here inwhich the relationship works in the opposite direction;this opposite character is mainly connected with transition from approximately plane molecular structures to the globular ones.Especially,a direction of the mentioned relationship for data of1,3,5-trinitro-1,3,5-triazinane,1,3,5,7-tetranitro-1,3,5,7-tetrazocane,and β- and ε-polymorphs of 2,4,6,8,10,12-hexanitro-2,4,6,8,10,12-hexaazaisowurtzitane is similar like those which create exception from semilogarithmic relationship between impact sensitivity and volume heat of explosion[2].Initiation reactivity of technical ε-polymorphs of 2,4,6,8,10,12-hexanitro-2,4,6,8,10,12-hexaazaisowurtzitane(i.e.position of its data in Figs.1 and 2 and in other similar reference frame[2])gives the impression by disorderliness in distribution of the actions of force in its crystal lattice in comparison with its RS-ε-HNIW or chemically pure analogue.Also limitations of partial shapes of the mentioned relationship by molecular-structural similarity signalizes higher importance of the intermolecular interactions in a crystal lattice in comparison with the crystal lattice free volume for initiation of the crystallineEMsbymechanicalimpulses(seeforexample[1,4,30,46]and references herein).These problems,however,need further investigation.

Fig.2.Molecular-structural analysis of the mutual relationship of impact sensitivity,expressed as a drop energy,Edr,and free space per molecule,ΔV-a relationship with the positive slope.

Acknowledgement

The work described in this paper partially received financial support from the Students Grant Projects No.SGSFCHT_2016002 of the Faculty of Chemical Technology at the University of Pardubice,partially it was created in the framework of the six month traineeship of Dr.LIU Ning in Institute of Energetic Materials at University of Pardubice in 2016 under financial support The State Administration of Foreign Experts Affairs,Peoples Republic of China.

2.沉淀法。用石灰、纯碱处理,使硬水中的Ca2+、Mg2+生成沉淀析出,过滤后即可得到软水,其中的锰、铁等离子也可除去。

Appendix A.Supplementary data

Supplementary data related to this article can be found at https://doi.org/10.1016/j.dt.2017.11.008.

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Svatopluk Zeman,Ning Liu,Marcela Jungová,Ahmed K. Hussein,Qi-Long Yan
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