1) cation-resin column
阳离子树脂交换柱<冶>
2) anion-exchange column,anion-resin column
阴离子树脂交换柱<冶>
3) pellets cation exchange resin
柱状阳离子交换树脂
4) cation exchange resin
阳离子交换树脂
1.
Determination of six trace elements in zirconium alloy by cation exchange resin chromatography and inductively coupled plasma atomic emission spectrometry;
阳离子交换树脂色层分离-电感耦合等离子体原子发射光谱法测定锆合金中6种微量元素
2.
Effect of amounts of resin particles on performance of cation exchange resin/PES hybrid membranes;
树脂颗粒填充量对阳离子交换树脂/聚醚砜杂化膜性能的影响
3.
Determinations of trace Copper,Lead and Cadmium in seawater by graphite furnace atomic absorption spectrometry with cation exchange resin;
阳离子交换树脂吸附石墨炉原子吸收法测定海水中痕量铜、铅、镉
5) ion exchange resin
阳离子交换树脂
1.
Synthesis of allantoin from glyoxylic acid and urea using ion exchange resins as catalyst was investigated.
对三种阳离子交换树脂在乙醛酸与尿素缩合反应中的催化活性进行了研究。
2.
Experiments were carried out on the hydration of terpene for one step, synthesizing terpineol by using certain super acid cation exchange resin as major catalyst.
用强酸性阳离子交换树脂作为主催化剂 ,加入相转移催化剂 ,在一定的温度条件下 ,由松节油和水一步合成松油醇 (不辅加有机溶剂 ) ,对其工艺条件及参数进行了研究 。
3.
Methyl 1 - maphthylacetate as a kind of plant growth regulator was synthesized by esterication of 1 - naphthyacetic acid with methanol in present of strongly acidic styrene type caution exchange resins.
以大孔径苯乙烯系强酸性阳离子交换树脂为催化剂,对μ-萘乙酸和甲酯的酯化反应进行催化,合成出作为植物生长调节剂的α-萘乙酸甲酯。
6) Cationic exchange resin
阳离子交换树脂
1.
Study on the preparation of methylacrylic dodecyl alcohol esters in the catalysis of cationic exchange resin;
阳离子交换树脂催化甲基丙烯酸十二醇酯的合成研究
2.
p -CumylphenolwassynthesizedbyFriedel-Craftsalkylationofphenol with α -methylstyrene in the presence of D 72 strong acid type cationic exchange resin catalyst.
用D72 强酸型阳离子交换树脂催化苯酚与α -甲基苯乙烯的Friedel-Crafts烷基化反应 ,合成对枯基苯酚。
3.
The main factors affecting the preparation of magnetic cationic exchange resin by chemical transformation were experimentally studied in detail.
对化学转化法制备磁性阳离子交换树脂的主要影响因素进行了较详细的实验探讨。
补充资料:阳离子-阳离子干扰
分子式:
CAS号:
性质:火焰原子吸收光谱分析中,伴生阳离子对待测阳离子测定中信号的增强或抑制。它属于化学干扰;信号增强属于增感效应,信号被抑制属于干扰效应。如测定镁时铝存在可抑制镁的信号;测定铝时钛存在,可增强铝的信号。前者由于生成难解离的MgO·Al2O3,减少了镁的基态原子;后者是钛的亲氧能力比铝强,钛夺取了氧化铝中的氧,生成氧化钛,铝从氧化铝中释放出来。
CAS号:
性质:火焰原子吸收光谱分析中,伴生阳离子对待测阳离子测定中信号的增强或抑制。它属于化学干扰;信号增强属于增感效应,信号被抑制属于干扰效应。如测定镁时铝存在可抑制镁的信号;测定铝时钛存在,可增强铝的信号。前者由于生成难解离的MgO·Al2O3,减少了镁的基态原子;后者是钛的亲氧能力比铝强,钛夺取了氧化铝中的氧,生成氧化钛,铝从氧化铝中释放出来。
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参考词条