化工进展
化工進展
화공진전
CHEMICAL INDUSTRY AND ENGINEERING PROGRESS
2014年
3期
710-713,719
,共5页
张帅国%米杰%尚素利%上官炬%武蒙蒙
張帥國%米傑%尚素利%上官炬%武矇矇
장수국%미걸%상소리%상관거%무몽몽
合成%动力学%纳米粒子%晶粒生长%微波
閤成%動力學%納米粒子%晶粒生長%微波
합성%동역학%납미입자%정립생장%미파
synthesis%kinetics%nanoparticles%grain growth%microwave
以乙酸锌和草酸为原料,采用低热固相化学反应法制备纳米氧化锌的前体,通过微波和马弗炉两种焙烧方式焙烧制备得到纳米氧化锌,考察了焙烧温度和时间对纳米氧化锌粒径的影响。使用透射电镜、热重-差热、傅里叶变换红外光谱仪和X射线衍射仪对前体和纳米ZnO进行表征;采用晶粒生长动力学唯象理论计算得出纳米氧化锌在这两种焙烧方式下的晶粒生长动力学规律。结果表明,前体为ZnC2O4·2H2O,随着焙烧温度的提高,纳米氧化锌晶粒迅速长大,在相同焙烧温度和时间下,微波焙烧氧化锌的晶粒尺寸要明显大于常规焙烧方式。微波焙烧和常规焙烧下氧化锌的晶粒生长平均动力学指数分别是6.114和6.858,晶粒生长的平均活化能分别为70.67 kJ/mol和52.13 kJ/mol。
以乙痠鋅和草痠為原料,採用低熱固相化學反應法製備納米氧化鋅的前體,通過微波和馬弗爐兩種焙燒方式焙燒製備得到納米氧化鋅,攷察瞭焙燒溫度和時間對納米氧化鋅粒徑的影響。使用透射電鏡、熱重-差熱、傅裏葉變換紅外光譜儀和X射線衍射儀對前體和納米ZnO進行錶徵;採用晶粒生長動力學唯象理論計算得齣納米氧化鋅在這兩種焙燒方式下的晶粒生長動力學規律。結果錶明,前體為ZnC2O4·2H2O,隨著焙燒溫度的提高,納米氧化鋅晶粒迅速長大,在相同焙燒溫度和時間下,微波焙燒氧化鋅的晶粒呎吋要明顯大于常規焙燒方式。微波焙燒和常規焙燒下氧化鋅的晶粒生長平均動力學指數分彆是6.114和6.858,晶粒生長的平均活化能分彆為70.67 kJ/mol和52.13 kJ/mol。
이을산자화초산위원료,채용저열고상화학반응법제비납미양화자적전체,통과미파화마불로량충배소방식배소제비득도납미양화자,고찰료배소온도화시간대납미양화자립경적영향。사용투사전경、열중-차열、부리협변환홍외광보의화X사선연사의대전체화납미ZnO진행표정;채용정립생장동역학유상이론계산득출납미양화자재저량충배소방식하적정립생장동역학규률。결과표명,전체위ZnC2O4·2H2O,수착배소온도적제고,납미양화자정립신속장대,재상동배소온도화시간하,미파배소양화자적정립척촌요명현대우상규배소방식。미파배소화상규배소하양화자적정립생장평균동역학지수분별시6.114화6.858,정립생장적평균활화능분별위70.67 kJ/mol화52.13 kJ/mol。
ZnO nanoparticles were obtained by calcination of precursor,which was synthesized by solid-state reaction using Zn(CH3COO)2·2H2O and H2C2O4·2H2O as raw materials,with muffle furnace and microwave furnace. Thermogravimetry/differential thermal(TG/DTA) , Transmission electron microscope(TEM),Fourier transform-infrared spectra (FT-IR) and X-ray diffraction (XRD) were used to characterize the structure of precursor and the ZnO nanoparticles. The influences of calcination temperature and time on the grain size of ZnO nanoparticles were investigated. The results indicate that the precursor is ZnC2O4·2H2O,the grain size of ZnO nanoparticles calcined by microwave furnace is larger than that treated with muffle furnace under the same conditions. The average grain growth exponents of ZnO prepared by microwave heating and conventional calcination are 6.114 and 6.858, respectively. Their average grain growth activation energies are 70.67 kJ/mol and 52.13 kJ/mol,respectively.
