物理化学学报
物理化學學報
물이화학학보
ACTA PHYSICO-CHIMICA SINICA
2010年
3期
547-551
,共5页
任晓宁%刘子如%王晓红%赵凤起%谢明召%衡淑云
任曉寧%劉子如%王曉紅%趙鳳起%謝明召%衡淑雲
임효저%류자여%왕효홍%조봉기%사명소%형숙운
快速热分解%T-Jump/FTIR%DNTF%压强
快速熱分解%T-Jump/FTIR%DNTF%壓彊
쾌속열분해%T-Jump/FTIR%DNTF%압강
Flash pyrolysis%T-jump/FTIR%DNTF%Pressure
采用温度快速跃迁原位池与快速扫描傅里叶变换红外联用(T-Jump/FTIR)技术在0.1-0.4 MPa压强范围内研究了3,4-二硝基呋咱基氧化呋咱(DNTF)的快速热裂解.试验是以1000℃·s~(-1)的升温速率在800和1000℃的温度下进行,用快速扫描傅里叶变换红外光谱实时跟踪分析DNTF裂解的气相产物.结果表明,DNTF快速热裂解的主要产物CO、C0_2、NO和NO_2的相对摩尔浓度c~*与温度和压强有关,通过分析相时摩尔浓度比(c_(NO)~*/C_(NO_2)~*)随温度和压强的变化,揭示了DNTF中碳硝基C-N0_2存在均裂生成NO_2和异构化生成NO两条竞争分解的可能途径,同时压强可能抑制呋咱环和氧化呋咱环生成NO的可能性.压强升高使c_(co)~*和c_(co_2)~*升高,而使c_(co)~*/c_(co_2)~*下降,证明DNTF的分解中存在非均相的气相/凝聚相反应和均相的气相产物间反应的二次或三次过程.
採用溫度快速躍遷原位池與快速掃描傅裏葉變換紅外聯用(T-Jump/FTIR)技術在0.1-0.4 MPa壓彊範圍內研究瞭3,4-二硝基呋偺基氧化呋偺(DNTF)的快速熱裂解.試驗是以1000℃·s~(-1)的升溫速率在800和1000℃的溫度下進行,用快速掃描傅裏葉變換紅外光譜實時跟蹤分析DNTF裂解的氣相產物.結果錶明,DNTF快速熱裂解的主要產物CO、C0_2、NO和NO_2的相對摩爾濃度c~*與溫度和壓彊有關,通過分析相時摩爾濃度比(c_(NO)~*/C_(NO_2)~*)隨溫度和壓彊的變化,揭示瞭DNTF中碳硝基C-N0_2存在均裂生成NO_2和異構化生成NO兩條競爭分解的可能途徑,同時壓彊可能抑製呋偺環和氧化呋偺環生成NO的可能性.壓彊升高使c_(co)~*和c_(co_2)~*升高,而使c_(co)~*/c_(co_2)~*下降,證明DNTF的分解中存在非均相的氣相/凝聚相反應和均相的氣相產物間反應的二次或三次過程.
채용온도쾌속약천원위지여쾌속소묘부리협변환홍외련용(T-Jump/FTIR)기술재0.1-0.4 MPa압강범위내연구료3,4-이초기부찰기양화부찰(DNTF)적쾌속열렬해.시험시이1000℃·s~(-1)적승온속솔재800화1000℃적온도하진행,용쾌속소묘부리협변환홍외광보실시근종분석DNTF렬해적기상산물.결과표명,DNTF쾌속열렬해적주요산물CO、C0_2、NO화NO_2적상대마이농도c~*여온도화압강유관,통과분석상시마이농도비(c_(NO)~*/C_(NO_2)~*)수온도화압강적변화,게시료DNTF중탄초기C-N0_2존재균렬생성NO_2화이구화생성NO량조경쟁분해적가능도경,동시압강가능억제부찰배화양화부찰배생성NO적가능성.압강승고사c_(co)~*화c_(co_2)~*승고,이사c_(co)~*/c_(co_2)~*하강,증명DNTF적분해중존재비균상적기상/응취상반응화균상적기상산물간반응적이차혹삼차과정.
The fast thermolysis of 3,4-dinitrofurazanfuroxan (DNTF) at 0.1-0.4 MPa was investigated by temperature-jump Fourier transform infrared (T-jump/FTIR) spectroscopy. All tests were carried out using a heating rate of 1000℃· s~(-1) at 800 and 1000℃. Structures and concentrations of the gaseous products were obtained in situ and in real time by fast scanning FTIR. Results showed that the relative molar concentrations c~* of the main gaseous products (CO, CO_2, NO and NO_2) that were released by the thermolysis of DNTF were related to pressure and temperature. The relative molar concentration ratios of c_(NO)~*/C_(NO_2)~* changes as the temperature and pressure change. These results reveal that the two competitive reactions of C-NO_2 homolysis (to form NO_2) and isomerization (to form NO) may occur during the fast thermolysis of DNTF. NO formation from the cracking of furazan or furoxan rings may be limited by pressure. Heterogeneous gas/condensed phase and homogeneous gas phase reactions may occur in the secondary and tertiary class reactions of the fast thermolysis of DNTF because the relative molar concentrations of c_(co)~* and c_(co_2)~* increase and the relative molar concentration ratios of c_(co)~*/c_(co_2)~* decrease with increasing pressure.