利用自反应淬熄法制备了Zn-Ti钡铁氧体空心陶瓷微珠吸波材料,这种材料具有核/壳结构,比一般的铁氧体密度小,是一种新型的吸波材料;通过SEM、EDS和XRD分析表明,该材料具有中空结构,成球规则,粒径分布均匀,经过热处理之后,由非晶相物质转...利用自反应淬熄法制备了Zn-Ti钡铁氧体空心陶瓷微珠吸波材料,这种材料具有核/壳结构,比一般的铁氧体密度小,是一种新型的吸波材料;通过SEM、EDS和XRD分析表明,该材料具有中空结构,成球规则,粒径分布均匀,经过热处理之后,由非晶相物质转变为了晶相物质,主要物相为Ba Zn Ti Fe10O19和Ba Fe12O19;通过吸波性能测试,该材料具有一定的吸波性能,经过热处理之后吸波性能提高了,其吸波最低反射率为–21.98 d B,反射率小于–10 d B的带宽大于2 GH Z。展开更多
研究了热浸镀Zn-Ti合金镀层的耐蚀性能。结果表明,Zn-Ti合金镀层耐蚀性较纯锌镀层有不同程度的提高,尤其是锌浴中钛含量为0.04%、0.06%和0.07%的合金镀层,其腐蚀速率降低为纯锌镀层的3/5~1/2,自腐蚀电位向正方向移动了20~40 m V,腐蚀电...研究了热浸镀Zn-Ti合金镀层的耐蚀性能。结果表明,Zn-Ti合金镀层耐蚀性较纯锌镀层有不同程度的提高,尤其是锌浴中钛含量为0.04%、0.06%和0.07%的合金镀层,其腐蚀速率降低为纯锌镀层的3/5~1/2,自腐蚀电位向正方向移动了20~40 m V,腐蚀电流密度降低。并通过SEM、EDS和XPS等测试手段,研究了钛含量对合金镀层内部组织的影响规律,探讨了钛对提高Zn-Ti合金镀层耐蚀性能的作用机理。展开更多
采用高温固相法制备了系列Zn改性的层状K-Fe-Zn-Ti催化剂,用于CO2加氢经费托合成直接制烯烃反应。采用SEM、TEM、XRD、H2-TPR、CO2-TPD、XPS、N2吸附-脱附和TG等手段对反应前后的催化剂进行了表征,对K-Fe-Zn-Ti催化剂的组成-结构-性能...采用高温固相法制备了系列Zn改性的层状K-Fe-Zn-Ti催化剂,用于CO2加氢经费托合成直接制烯烃反应。采用SEM、TEM、XRD、H2-TPR、CO2-TPD、XPS、N2吸附-脱附和TG等手段对反应前后的催化剂进行了表征,对K-Fe-Zn-Ti催化剂的组成-结构-性能关系进行了关联研究。结果表明,所制备的催化剂均出现K2.3Fe2.3Ti5.7O16物相,为典型的层状金属氧化物(Layered Metal Oxides,LMO)结构;Zn改性后生成了ZnFe2O4物相,降低了催化剂样品结晶度,增强了表面碱性,促进了CO2表面吸附。在CO2加氢反应中,K-Fe-Zn-Ti系列催化剂均具有较高的烯烃选择性(O/P>6.5),Zn改性促进了C5+的生成,显著提高了C4+线性α-烯烃(linearα-olefins,LAOs)的选择性,C4+烃中LAOs含量由Zn改性前的54.6%提高至75.2%。在所考察的范围内,随Zn/Fe比的增加,烯/烷比(C2-4=/C2-40,O/P)先增加后降低,但对重烃含量以及LAOs选择性影响不明显。K-FeZn-Ti催化剂具有较好的稳定性,经100 h在线反应后,仍保持LM O结构。展开更多
Hot-dip Zn-Ti galvanizing can restrain the excess growth of the coating which has better corrosion resist- ances than hot-dip pure Zn. The change rules of Г2 intermetallic compound in hot-dip Zn-Ti galvanizing is inv...Hot-dip Zn-Ti galvanizing can restrain the excess growth of the coating which has better corrosion resist- ances than hot-dip pure Zn. The change rules of Г2 intermetallic compound in hot-dip Zn-Ti galvanizing is investiga ted by immersion time, titanium content and the slag test using scanning electron microscopy (SEM), energy dis- persive spectroscopy (EDS) and X-ray diffraction (XRD). And the mechanism of nucleation and growth of Г2 inter- metallic compound is analysed. The results show that, when adding 0. 05mass% titanium to the zinc bath, the Г2 particles form in the η layer, which nucleate by obtaining Ti atoms from the phase and Fe atoms from the dissol- ving ζ phase layer. Moreover, the more titanium is added into the bath, the more and bigger Гz particles appear. The Fz particles in the coatings grow up noticeably with prolonging the immersion time.展开更多
文摘利用自反应淬熄法制备了Zn-Ti钡铁氧体空心陶瓷微珠吸波材料,这种材料具有核/壳结构,比一般的铁氧体密度小,是一种新型的吸波材料;通过SEM、EDS和XRD分析表明,该材料具有中空结构,成球规则,粒径分布均匀,经过热处理之后,由非晶相物质转变为了晶相物质,主要物相为Ba Zn Ti Fe10O19和Ba Fe12O19;通过吸波性能测试,该材料具有一定的吸波性能,经过热处理之后吸波性能提高了,其吸波最低反射率为–21.98 d B,反射率小于–10 d B的带宽大于2 GH Z。
文摘研究了热浸镀Zn-Ti合金镀层的耐蚀性能。结果表明,Zn-Ti合金镀层耐蚀性较纯锌镀层有不同程度的提高,尤其是锌浴中钛含量为0.04%、0.06%和0.07%的合金镀层,其腐蚀速率降低为纯锌镀层的3/5~1/2,自腐蚀电位向正方向移动了20~40 m V,腐蚀电流密度降低。并通过SEM、EDS和XPS等测试手段,研究了钛含量对合金镀层内部组织的影响规律,探讨了钛对提高Zn-Ti合金镀层耐蚀性能的作用机理。
文摘采用高温固相法制备了系列Zn改性的层状K-Fe-Zn-Ti催化剂,用于CO2加氢经费托合成直接制烯烃反应。采用SEM、TEM、XRD、H2-TPR、CO2-TPD、XPS、N2吸附-脱附和TG等手段对反应前后的催化剂进行了表征,对K-Fe-Zn-Ti催化剂的组成-结构-性能关系进行了关联研究。结果表明,所制备的催化剂均出现K2.3Fe2.3Ti5.7O16物相,为典型的层状金属氧化物(Layered Metal Oxides,LMO)结构;Zn改性后生成了ZnFe2O4物相,降低了催化剂样品结晶度,增强了表面碱性,促进了CO2表面吸附。在CO2加氢反应中,K-Fe-Zn-Ti系列催化剂均具有较高的烯烃选择性(O/P>6.5),Zn改性促进了C5+的生成,显著提高了C4+线性α-烯烃(linearα-olefins,LAOs)的选择性,C4+烃中LAOs含量由Zn改性前的54.6%提高至75.2%。在所考察的范围内,随Zn/Fe比的增加,烯/烷比(C2-4=/C2-40,O/P)先增加后降低,但对重烃含量以及LAOs选择性影响不明显。K-FeZn-Ti催化剂具有较好的稳定性,经100 h在线反应后,仍保持LM O结构。
基金Sponsored by Science and Technology Planning Project of Guangdong Province of China(2011B010300017)
文摘Hot-dip Zn-Ti galvanizing can restrain the excess growth of the coating which has better corrosion resist- ances than hot-dip pure Zn. The change rules of Г2 intermetallic compound in hot-dip Zn-Ti galvanizing is investiga ted by immersion time, titanium content and the slag test using scanning electron microscopy (SEM), energy dis- persive spectroscopy (EDS) and X-ray diffraction (XRD). And the mechanism of nucleation and growth of Г2 inter- metallic compound is analysed. The results show that, when adding 0. 05mass% titanium to the zinc bath, the Г2 particles form in the η layer, which nucleate by obtaining Ti atoms from the phase and Fe atoms from the dissol- ving ζ phase layer. Moreover, the more titanium is added into the bath, the more and bigger Гz particles appear. The Fz particles in the coatings grow up noticeably with prolonging the immersion time.
