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This set of information contains books and CD-ROMs, a total of 2 sets of content, a total of 270 yuan, including freight details, please consult customer service personnel tel: 010-51654247 010-57923471
First Material: The Reaction and Process of Energetic Compound Synthesis, the latest book published by Publishing House
The second set of information: Compilation of Energetic Compounds, CD-ROM, contains the corresponding contents of the following catalogues, almost all of which are summarized together;
The catalogue of books is as follows:
1 Introduction 1
1.1 Concept of energetic compounds 1
Structural Characteristics and Classification of 1 2 Energetic Compounds
Structural Characteristics of 1 2 1 Energetic Compounds 1
Classification of 1 2 2 energetic compounds 2
SYNTHESIS OF 1 3 ENERGY-CONTAINING COMPOUNDS 9
1 3 1 aldolamine condensation reaction 9
1 3 2 Mannich condensation reaction 10
1 3 3 3 Direct Nitrification (Nitrification) Reaction 10
1 3 4 Indirect Nitrification Reaction 12
1 3 5 azide reaction 13
SYNTHESIS PROCESS OF 1 4 ENERGY-CONTAINING COMPOUNDS 13
Characteristics of the synthetic process of energetic compounds 1 4 1
Progress in synthesis of energetic compounds 1 4 2
Prospect of synthesis reaction and process of energetic compounds 1 5 20
1.5.1 Computer Aided Design (CAD) will be an important method for the synthesis and process study of energetic compounds 20
1 5 2-ldquo; Clean synthesis method-rdquo; Target 20 for the development of synthesis reaction and process of energetic compounds
Reference 21
2. Computer Aided Design of Energetic Compound Synthesis 22
Molecular Design of 2 1 Energetic Compounds 22
Performance Estimation of 2.2 Energetic Compounds 25
2 2 1 Density Estimation 25
Estimation of enthalpy of formation for 2 2 2 2 26
CALCULATION AND ESTIMATION OF 2 2 3 DETONATION PERFORMANCE
Estimation of 2 2 4 impact sensitivity 33
Computer Aided Synthesis Route Design of 2 3 Energetic Compounds 36
2.3.1 Origin and Development of Computer Aided Synthetic Route Design 37
Significance of 2 3 2 Computer Aided Synthesis Route Design in the Field of Energetic Materials 37
2 3 3 3 Chemical Reaction Knowledge in Computer 37
Classification of 2 3 4 Computer Aided Route Design System 38
2 3 5 Inverse Synthesis and Its Application in Computer Aided Synthesis of Energetic Compounds
Cutting of 2 3 6 Synthetic trees and evaluation of synthetic routes 48
Reference 49
SYNTHESIS OF 3-NITROGEN HETEROCYCLIC COMPOUNDS 53
Synthesis of 3_1 aza quaternary ring 53
3 1 11,3,3 trinitroaza heterocyclic butane 53
3.1.2 Other aza quaternary rings 59
SYNTHESIS OF 3_2 AZA FIVE-MEMBER RINGS 60
3 2 1 monofurazan ring compound 60
3 2 25 nitrotetrazole and its salts 63
3 2 3 quinary nitrogen heterocyclic compounds 64
3 2 44 amino 3,5 dinitropyrazole (LLM 116)67
3 2 52,3,4 trinitropyrrole and 2,3,4,5 tetranitropyrrole 68
SYNTHESIS OF 3_3 AZA 6-membered RING 69
Synthesis of 3 3 1 RDX parent ring 69
SYNTHESIS OF 3 3 3 21,3,5,5 tetranitro 1,3 diazo (DNNC) 75
Synthesis of 3 3 3 31,1 diamino 2,2 dinitroethylene (FOX 7) 79
SYNTHESIS AND MECHANISM OF 3_4 AZA EIGHT-MEMBER RING 80
Synthesis of 3 4 1 DPT 81
Synthesis of 3 4 2 TAT 83
3 4 3 small molecule synthesis method 86
3 4 4 4 other small molecule synthesis 87
SYNTHESIS OF 3_5 NITROGEN CAGE COMPOUNDS 89
Progress in synthesis of 3 5 1 aza cage energetic materials 89
SYNTHESIS OF 3 5 2CL 20 90
Synthesis of 3 5 3 TEX 93
A New Idea for the Synthesis of 3 6 Nitrogen Heterocycles 94
3 6 1 & ldquo; Click Chemistry & rdquo; Application in Nitrogen Heterocyclic Synthesis 94
Application of 3 6 2 Supramolecular Strategy in Nitroheterocyclic Synthesis 96
Reference 102
Nitration of 4-azacyclic compounds 108
Structure and nitrification characteristics of 4 1 nitrogen heterocyclic compounds 108
Characteristics and Selection of 4.2 Nitrate Dissolution Agent 109
Mechanism and Kinetics of 4 3 Nitration Reaction 111
Structure and Concentration Characteristics of 4 3 1 Nitroyl Cation 111
Nitrolysis Reaction and Mechanism of 4 3 2RDX Synthesis
Nitrolysis of 4 3 HMX and its mechanism 136
Nitrolysis of 4 3 4 caged azacyclic compounds 160
Reference 162
SYNTHESIS OF 5 ENERGY AROMATIC COMPOUNDS 169
Summary of Nitrification of 5 1 Aromatic Compounds 169
Properties of 5 1 1 aromatic compounds 169
A Brief Description of Nitrification Reaction Mechanism of 5 1 2 Aromatic Compounds
Development Trends of Nitrification of 5 1 3 Aromatic Compounds 170
Synthesis of Nitroaromatic Compounds in 5 2 Ionic Liquids
Synthesis of Nitroaromatic Compounds in 5 2 1 Imidazole Ionic Liquids
Synthesis of Nitroaromatic Compounds in 5 2 caprolactam Ionic Liquids 178
Synthesis of Nitroaromatic Compounds in 5 2 3 Pyridine Ionic Liquids
Synthesis of Nitroaromatic Compounds in 5 2 4 Straight Chain Quaternary Ammonium Salt Ionic Liquids
Nitrification of Aromatic Compounds Catalyzed by 5 3 Inorganic Solid Acid 181
Regioselective nitration of aromatic compounds catalyzed by 5 3 1 zeolite 181
REGIONALLY SELECTIVE NITRIFICATION OF AROMATIC COMPOUNDS WITH 5 3 2 SUPPORTED SOLID ACID CATALYST 193
Regioselective nitration of aromatic compounds catalyzed by 5 3 3 heteropoly acid 199
Regioselective nitration of aromatic compounds 204 catalyzed by 5 3 4 Solid Superacid
Synthesis of Nitroaromatic Compounds under the Action of 5 4 Transition Metals and Lanthanide Metal Salts 206
Catalytic nitration of aromatic compounds by 5 4 1 trifluoromethanesulfonic transition metals and lanthanide metal salts 207
Catalytic Nitrification of Aromatic Compounds by 5 4 2 Long Chain Transition Metals of Total Sulfonic Acid and Lanthanide Salts
Response 210
Catalytic nitration of aromatic compounds by 5 4 3 aromatic sulfonic acid transition metal salts 215
Catalytic nitration of aromatic compounds by 5 4 4 4 perfluorosulfonyl imide transition metal salts
5.4.5 Catalytic nitration of aromatic compounds by other transition metal salts 218
Application of 5 5 Phase Transfer Catalyst in Nitrification of Aromatic Compounds
Application of 5 6 Microreactor in Nitrification of Aromatic Compounds 223
5.7 Application of New Systems and Methods for Other Reactions in Nitrification of Aromatic Compounds 226
Reference 227
SYNTHESIS OF 6-ION ENERGY-CONTAINING COMPOUNDS
6.1 Overview 236
Synthesis of 6 2 Nitroform Salt 236
Synthesis of 6 2 1 nitroform 236
Separation and Purification of 6 2 nitroform 240
Conversion of 6 2 3 nitroform 240
SYNTHESIS OF 6 3 DINITRAMIDE SALT 241
SYNTHESIS OF 6 3 1ADN 242
SYNTHESIS OF 6 3 2 OTHER DINITRAMIDE SALTS 247
SYNTHESIS OF 6 4 ION-TYPE ENERGY-RICH NITROGEN COMPOUNDS 247
SYNTHESIS OF 6 4 1 ION-TYPE ENERGY-RICH NITROGEN COMPOUNDS 248
Synthesis of 6 4 2 tetrazole ionic nitrogen-rich energetic compounds 249
6 4 3 tetrazines ionic nitrogen-rich energetic compound 249
6 5 Ionic Total Nitrogen Compound 250
SYNTHESIS OF 6 5 1 N+5 ION SALT 250
6.5.2 Assumption for the synthesis of other total nitrogen ions 251
Reference 252
7 strong exothermic kettle reaction process 254
7.1 Overview 254
Structure of 7 2 Energetic Compound Reactor 254
7.3 Mixing Component 255
Type of 7 3 1 agitator 255
Selection of 7 3 2 agitator 258
7 3 3 3 Mixing Appendix 260
Flow Characteristics of 7 4 Reactor 261
7.4.1 Fluid Circulation Volume and Pressure Head 261
7.4.2 Reynolds number of impeller 262
Calculation of 7 4 3 Mixing Power 263
Heat Transfer Characteristics of 7 5 Energetic Compound Reactor 266
Heat Transfer Mode of 7 5 1 Reactor 266
Heat Transfer Calculation of 7 5 2 Reactor 268
Mathematical model for kettle reaction of 7 6 energetic compounds 275
Operating mode of 7 6 1 stirred reactor 275
Material Balance of 7.6.2 Tank Reactor 275
Energy balance of 7 6 3 kettle reactor 277
7.6.4 Reaction process optimization based on mathematical model 279
Flying Temperature Simulation of 7 7 Energetic Compound Reaction Process and Emergency Measures 285
Flight temperature simulation of 7 7 1 energetic compound reaction process 285
Technical Prevention and Emergency Measures for the Reaction Process of 7 7 2 Energetic Compounds 288
Scale-up of 7 8 Energetic Compounds Reactor 290
Amplification of 7 8 1 Homogeneous System 292
Amplification of 7 8 2 Heterogeneous System 296
Reference 299
8-Strong Exothermic Tube Reaction Process 301
8.1 Overview 301
An Example 301 of Strong Exothermic Reaction Model in 8 2 Tube Reactor
Brief Introduction of Reaction in 8 2 1 Tube Reactor 301
Balance of mass and energy in 8 2 2 2 tubular reactor 302
Safety of 8 3 tubular reactor 306
Heat exchange capacity of 8 3 1 tubular reactor 306
Examples of Essential Safety of 8 3 2 Tube Reactor 306
Progress in Heat Transfer Phenomena of 8.3.3 Microtubes 308
Application of 8 4 Microreactor in Strong Exothermic Reaction 310
Development of 8 4 1 microreactor 310
Characteristics of 8.4.2 Microreactor 310
Application of 8 4 3 Microreactor in the Synthesis of Energetic Compounds
Detection Technology of 8 5 Small Tube Reactor 314
8 5 1 Optical Detection Method 315
8.5.2 Capacitance Detection Method 317
8 5 3 Conductivity Detection Method 320
Reference 334
The contents of the CD-ROM are as follows:
A Computer Aided Design System for Energetic Compounds
2. Method of Generating Molecular Combination Library of Energetic Compounds Based on Smile Chemical Expressions
3 Oligopeptide Compounds Containing D-2-Alkyl Tryptophan and Promoting Growth Hormone Release
4 Polypeptide Compounds Containing D-2-Alkyl Tryptophan Promoting Growth Hormone Release
SYNTHESIS AND CHARACTERIZATION OF 5-TETRAZINE HIGH NITROGEN ENERGY COMPOUNDS
Progress in synthesis and application of 6-polynitropyridine derivatives
Crystal structure of energetic compound 4-amino-1,2,4-picrate
Study on 8 New Energetic Materials
Progress in synthesis of 9 dicyclic nitroamine energetic compounds
Application of 10 KPCA and GRNN in energetic compound QSAR
Research Progress of 11 Imidazole Energetic Compounds
Study on the Interaction Mechanism of 12 Laser with Energetic Compounds
Effect of cis-trans isomerization on the sensitivity of azo energetic compounds
Prediction of Structural Properties of Energetic Compounds Based on PCA and SVM
Study on the Periodic Density Functional Theory of 15 Trinitropyrogallol and Its Alkali Metal Salt Crystals
Research Progress of 16 Triaminoguanidine Series Energetic Compounds
In 1760, Chicheng Pays Honest Reporting for National Defense in the New Century
Synthesis and Crystal Structure of 18 3-Azide-4-Aminofurazan
New Progress in Application of 19 High Nitrogen Energetic Compounds
Synthesis, Crystal Structure and Thermal Analysis of 207-Amino-6-furoxan Dioxide
Study on Thermal Decomposition of 21 High Nitrogen Energetic Compound Azotetrazole Triaminoguanidine Salt
Progress in 22 Pyrazole and Pyrazine Energetic Compounds
Calculating and Predicting Thermal Hazard of 23 New Energetic Compounds
SYNTHESIS AND PROPERTIES OF 24 S-TETRAZINE HIGH NITROGEN ENERGY COMPOUNDS
25 A Novel High Energy Insensitive 3,4-Di(Aminofurazan)Furzan Oxide
Crystal structure of 263-amino-4-amidooxime furazan
Synthesis and Reactivity of 27 High Nitrogen Energetic Compounds
Advances in 28-N Heterocyclic Energetic Compounds
Synthesis and Crystal Structure of 293,6-Bis(3-rsquo;-Aminofurazan-4-yl) -1,4-dioxane-2,5-diazocyclohexane-2,5-diene
30 chemistry—&mdashNew advances in organic chemical energetic compounds with high ammonia content
SYNTHETIC AMPLIFICATION AND PROPERTIES OF 313,6-DIAMINO-1,2,4,5-TETRAZINE-1,4-DIOXIDE
Preparation of 324,5-dinitroimidazole
SYNTHESIS OF 33-HEXAZAIWOODZANE DERIVATIVES
Recent Progress in 34 High Nitrogen Energetic Compounds
Study on 35 Copper-based Infrared Jamming Smoke Agent Containing High Nitrogen Compounds
Determination of specific heat capacity of energetic compounds by differential scanning calorimetry
Synthesis and Crystal Structure of 373-Amino-4-Aminooxime Furzan
38 furazan energetic compounds and their applications in Propellants
Study on the Amplified Synthesis and Characterization of 39 Triaminoguanidine Nitrate
SYNTHESIS AND CHARACTERIZATION OF ISOMERS OF 403,4-DIAMINOFUZAZANYL OXIDAZANE
SYNTHESIS AND CHARACTERIZATION OF 41 S-TETRAZINE ENERGY-CONTAINING COMPOUNDS WITH HIGH NITROGEN
Synthesis of 423-Amino-4-Aminooxime Furzan at 500g Level
Progress in synthesis of 43 furoxan oxide derivatives
Study on Preparation and crystal structure of 443,4-diaminofurazan-based furoxan oxide
SYNTHESIS AND CRYSTAL STRUCTURES OF 453,4-DIAMINOfurazan-based furoxan oxide
SYNTHESIS AND CHARACTERIZATION OF 46 AZOTRAZOLE HIGH AZO ENERGY COMPOUNDS
47 3,3-rsquo; - diamino-4,4-rsquo; - synthesis of azofluxan and azofluxan oxide
48 六硝基六氮杂三环十四烷对二呋咱(HHTTD)的合成
49 新型含能化合物N-次甲基-二-3,3-二硝基氮(杂)环丁烷的理论研究
50 高氮化合物在含能材料中的应用研究进展
51 六硝基六氮杂异伍兹烷制备工艺研究开发新进展
52 聚三的合成研究
53 1,4,5,8—四氮杂氢化萘(2,3,—6,7)并双呋咱衍生物的合成
54 3,4—二氨墓呋咱的乙酰化反应
55 3,4—二氢基呋咱500克级合成
56 《含能化合物标准光谱图集》简介
57 笼形含能化合物HNIW的结构与性能研究
58 二叠氮季戊二醇二硝酸酯的结构分析
