铝氧化

太湖、巢湖、白洋淀、泸沽湖的优势磷形态分别为铁锰螯合态磷、铁铝氧化态磷、钙镁结合态磷、活性有机磷。

Advantage phosphorus forms in Tai Lake , Chao Lake , Lugu Lake is respectively for Ferromanganese of Chelated phosphorus , iron and aluminum oxidation state phosphorus , calcium and magnesium bound phosphorus , active organic phosphorus .

其中铁铝氧化态磷对生物可利用磷的贡献最大。

The iron and aluminum oxidation state a maximum contribution to bioavailable phosphorus . 2 .

pH值对溶胶-凝胶法制备的掺铝氧化锌薄膜光电性能的影响

Effect of pH Value on the Optical and Electrical Properties of Al-doped ZnO Thin Films by Sol-gel Process

在SEM下观察了高铝氧化层的微观结构。

Then we have observed the microstructure of the high aluminum oxidized layer through SEM .

离子辅助沉积掺铝氧化锌透明导电膜的研究透光导电ITO膜的制备及其光电特性的研究

Optical and electrical properties of transparent conductive ITO films prepared by sol-gel process

掺铝氧化锌（AZO）薄膜制备及结合机理探索

Al-doped zinc oxide thin film preparation and integration mechanism

用表面渗铝氧化方法形成微米厚度的Al2O3／FeAl涂层，是广泛研究的防渗屏障层生成工艺。

An Al2O3 / FeAl coating with thickness of micrometers is formed by packed-bed aluminizing and oxidizing technology .

熔铝氧化渗透合成SiCp/Al2O3-Al复合材料的微观结构分析

Investigation on the microstructure of SiC_p / Al_2O_3-Al composites synthesized by oxidative infiltration of Al melt

SiC颗粒粒度对熔铝氧化渗透合成SiCp/Al2O3-Al复合材料微观断裂机制的影响

Effect of SiC Particle Size on Micro-fracture Mechanism of SiC_p / Al_2O_3-Al Composites Synthesized by Oxidative Infiltration of Al Melt

掺铝氧化锌（ZAO）鉴于其导电性在太阳能电池、气体传感器和超声传感器领域有着广泛的应用。

Aluminum doped zinc oxide has been widely used in the fields of solar cells , gas sensors and ultrasonic sensors due to its electrical properties .

ZAO（掺铝氧化锌）薄膜由于其宽禁带特性、导电特性而有重要应用，对其红外波段特性的研究更是人们研究的一个热点。

ZAO ( Al-doped ZnO ) thin films have a lot of important applications because of its wide band gap and conductivity . Researchers have paid attention in its infrared optical properties .

综述透明导电薄膜的性能、种类、制备工艺、研究及应用状况，重点讨论掺铝氧化锌（AZO）薄膜的结构、导电机理、光电性能和当前的研究焦点。

The properties , varieties , preparation technologies , recent research advances on transparent and conducting films and their applications in various fields are described . Structure , electric mechanism , photoelectric properties and investigation focus of AZO film are emphasized .

我国铝氧化着色现状和前景

Anodizing and Colouring of Aluminium in China & Current Status and Prospects

大功率铝氧化脉冲电源设计

Design of High Power Pulsation Supply on Anodizing of Aluminum

8407模具钢表面渗铝氧化的研究

Study on Surface Aluminization and Oxidation of 8407 Die Steel

掺铝氧化锌薄膜的红外性能及机制

Infrared properties and mechanism of Al-doped ZnO Thin Films

原色系铝氧化膜层的研究

A Study on Aluminium Anodizing Films with Original Colours

免疫过氧化物酶染色自动线组合技术应用于铝氧化染色工艺

Application of Automation Line of Combined Technology to Anodic Oxidation and Painting of Aluminium

反渗透技术在铝氧化废水处理和回用中的应用

Application of reverse osmosis technique to treatment of aluminium oxide wastewater and its reuse

水热法制备高定向掺铝氧化锌纳米棒阵列

Preparation of High-directional Al-doped Zinc Oxide ( ZAO ) Nanorods Array by Hydrothermal Method

铝氧化剂的研制与开发

Development and Study on Aluminium Oxidizer

掺铝氧化锌粉末的制备及其性能研究

Preparation and properties of doped-ZAO powders

掺铝氧化锌薄膜表面织构机制的研究

Study on the surface texture mechanism of Al-doped zinc oxide films etched by NH_4Cl aqueous solution

掺铝氧化锌厚膜制备及其对三甲胺和海产品鲜度的敏感性

Preparation of aluminum doped zinc oxide thick films and their sensitivity to TMA and freshness of sea food

叙述了铝氧化着色和封孔的基本原理，阐明了影响质量的一些关键问题。

Basic principles of aluminium oxidation , coloration and sealing are described . A few key problems affecting the quality are elucidated .

介绍了铝氧化反应结合技术与干湿法纺丝工艺相结合制备氧化铝中空纤维膜的方法。

The preparation method of alumina hollow fiber membrane by reaction bonding of aluminum oxide ( RBAO ) technique combined with dry wet spinning process was introduced in this paper .

应用X射线衍射仪分析铝基氧化铜吸附剂的硫化性能

XRD Analysis of the Sulfurization Property of Aluminum Supported Copper Oxide Sorbents

铝型材氧化处理PLC控制系统分析

Analysis on PLC Control System for Oxidizing Aluminium Shapes

铝型材氧化着色基于DH+的PLC网络控制

PLC Network Control System for Aluminium Alloy Shape Anodizing and Coloring Based on DH + Network

铝阳极氧化法制备Al2O3纳米线

Preparation of alumina nanowires by aluminum anodization