91973
Amberlite™ HPR1100 Ion Exchange Resin
beads, suitable for LPLC, Na ion exchange resin, strongly acidic, 20-50 mesh
别名:
Amberlite™ HPR1100 Na, Amberlite™ HPR1100 sodium
产品名称
AMBERLITE ™ HPR1100 钠形式, Na ion exchange resin, strongly acidic, 20-50 mesh
description
formerly Dowex Marathon™ C Na
form
beads
manufacturer/tradename
Du Pont Amberlite™
parameter
5-150 °C operating temperature
technique(s)
LPLC: suitable
loss
~45% loss on drying, 110°C
matrix
styrene-divinylbenzene (gel)
matrix active group
sulfonic acid
particle size
20-50 mesh, 535-635 μm
operating pH range
0-14
capacity
≥2.0 eq/L total exchange capacity(Na+ form), 42.0-48.0 % water retention capacity(Na+ form)
separation technique
strong cation exchange, strong cation exchange
Quality Level
General description
AMBERLITE™ HPR1100 Na离子交换树脂是一种强酸性阳离子交换树脂,用于去矿化和工业软化应用。
Application
AMBERLITE™ HPR1100是阳离子交换树脂 可用于:
- 接枝聚乙二醇,催化环氧化物进行区域选择性叠氮分解。
- 固定 β-环糊精,作为相转移催化剂,将环氧化物还原成醇。
- 作为吸附剂,去除水溶液中的砷 和铜。
Legal Information
Amberlite is a trademark of DuPont de Nemours, Inc.
Marathon is a trademark of The Dow Chemical Company or an affiliated company of Dow
signalword
Warning
hcodes
Hazard Classifications
Eye Irrit. 2
存储类别
11 - Combustible Solids
wgk
WGK 3
ppe
dust mask type N95 (US), Eyeshields, Gloves
Arsenite and arsenate sorption by hydrous ferric oxide/polymeric material.
Habuda-Stanic M, et al.
Desalination, 229(1-3), 1-9 (2008)
Removal of copper from aqueous solution by ion exchange resins.
Veli S and Pekey B
Fresenius Environmental Bulletin, 13(3), 244-250 (2004)
Poly (ethylene glycol) grafted onto dowex resin: an efficient, recyclable, and mild polymer-supported phase transfer catalyst for the regioselective azidolysis of epoxides in water.
Kiasat AR, et al.
The Journal of Organic Chemistry, 73(21), 8382-8385 (2008)
Wei Zhang et al.
Chemosphere, 227, 247-255 (2019-04-17)
Previous studies have demonstrated that anaerobic digestion (AD) enhances sludge dewaterability. However, the mechanism of AD influence on digested sludge dewaterability is still not well understood. In this study, moisture distribution and bond energy were used to evaluate the influence
Han-Quan Wen et al.
Environment international, 139, 105683-105683 (2020-04-04)
Photo-fermentative hydrogen production, the new energy production alternative, was greatly enhanced by formed biofilm. To understand the mechanism of enhancement, the intracellular proteome and extracellular polymeric substance (EPS)i during biofilm formation were investigated in this work. Experimental results indicated that
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