共找到 357 条与 物理学、化学 相关的标准,共 24 页
BS EN IEC 62565-3-1. Nanomanufacturing. Material specifications - Part 3-1. Graphene. Blank detail specification
Fine bubble technology -- Storage and transportation of ultrafine bubble dispersion in water
Fine bubble technology -- General principles for usage and measurement of fine bubbles -- Part 2: Categorization of the attributes of fine bubbles
Fine bubble technology -- Sampling and sample preparation for measurement -- Part 1: Ultrafine bubble dispersion in water
Guidance on safe management of nanotechnology-based products
Fine bubble technology - Agricultural applications - Part 3: Guidelines for the minimum viable number concentration of ultrafine bubbles for promoting the germination of barley seeds
Fine bubble technology. Elimination method for sample characterization. Fine bubble elimination techniques
This document specifies the elimination techniques for removing fine bubbles from fine bubble dispersion in water and how to optimize the elimination procedures to obtain better efficiency. This document is applicable to fine uncoated bubbles (without shells). It does not apply to fine coated bubbles (with shells). NOTE Fine bubbles dispersed in liquid are classified into “fine bubble with shells” and “fine bubble without shells”. Fine bubble with shells means the fine bubble whose surface/interface is covered almost completely by an object or a collection of objects.
Fine bubble technology - Elimination method for sample characterization - Part 2: Fine bubble elimination techniques
Fine bubble technology. Cleaning applications. Test method for cleaning hard flooring surfaces
IEC TS 62607-4-5:2017(E) provides a standardized method for the determination of electrochemical properties of cathode nanomaterials such as lithium iron phosphate (LFP) for electrical energy storage devices. This method will enable the industry to: decide whether or not a cathode nanomaterial is usable, and select a cathode nanomaterial suitable for their application. This document includes: recommendations for sample preparation, outlines of the experimental procedures used to measure cathode nanomaterial properties, methods of interpretation of results and discussion of data analysis, and case studies. NOTE The very purpose of this method is to arrive at a detailed characterization of the electrodes so that individual contribution of the anode and cathode for performance and degradation could be predicted. The method can be applied for characterization of the electrode working as cathode or/and as anode.
Nanomanufacturing - Key control characteristics - Part 4-5: Cathode nanomaterials for nano-enabled electrical energy storage - Electrochemical characterization, 3-electrode cell method
IEC TS 62607-4-7:2018 provides a method for the determination of magnetic impurities in anode nanomaterials for energy storage devices using an Inductively Coupled Plasma Optical Emission Spectrometer (ICP-OES), including test overview, reagents, apparatus, test procedures, test results and test report. IEC TS 62607-4-7:2018 applies to the determination of the total content of magnetic impurities (iron, cobalt, chromium, and nickel) ≥ 0,02 mg/kg which can be attracted by magnet.
Nanomanufacturing - Key control characteristics - Part 4-7: Nano-enabled electrical energy storage - Determination of magnetic impurities in anode nanomaterials, ICP-OES method
IEC/IEEE 62659:2015(E) provides a framework for introducing nanoelectronics into large scale, high volume production in semiconductor manufacturing facilities through the incorporation of nanomaterials (e.g. carbon nanotubes, graphene, quantum dots, etc.). Since semiconductor manufacturing facilities need to incorporate practices that maintain high yields, there are very strict requirements for how manufacturing is performed. Nanomaterials represent a potential contaminant in semiconductor manufacturing facilities and need to be introduced in a structured and methodical way.
Nanomanufacturing - Large scale manufacturing for nanoelectronics
This document specifies a test method for the cleaning of hard flooring surfaces. It can be used to demonstrate the comparative cleaning performance of a fine bubble solution to an alternate cleaning solution to remove contaminant from a soiled surface. This alternate cleaning solution can be another fine bubble solution, municipal tap water or a commercially available cleaning solution blended to the manufacturer’s specifications. This method is not suitable for differentiating between cleaning solutions when the contaminant is excessively applied on the surface as the mechanism of cleaning changes.
Fine bubble technology - Cleaning applications - Part 3: Test method for cleaning hard flooring surfaces
Nanomaterials. Quantification of nano-object release from powders by generation of aerosols
Fine bubble technology. Guideline for indicating benefits. Assignment of Sustainable Development Goals (SDGs) to applications of fine bubble technologies
Fine bubble technology – Guideline for indicating benefits — Part 2: Assignment of Sustainable Development Goals (SDGs) to applications of fine bubble technologies
Nanotechnologies — Electron spin resonance(ESR) as a method for measuring reactive oxygen species(ROS) generated by metal oxide nanomaterials
Nanotechnologies — Electron spin resonance(ESR) as a method for measuring reactive oxygen species(ROS) generated by metal oxide nanomaterials
Nanomanufacturing - Key control characteristics - Part 8-2: Nano-enabled metal-oxide interfacial devices - Test method for the polarization properties by thermally stimulated depolarization current
State system for ensuring the uniformity of measurements. Standard reference data. Carbon monoxide, liquid and gaseous. Density, enthalpy, entropy, isochoric and isobaric heat capacities at temperatures from 70 K up to 500 K and pressures up to 100 MPa
Copyright ©2007-2022 ANTPEDIA, All Rights Reserved
京ICP备07018254号 京公网安备1101085018 电信与信息服务业务经营许可证:京ICP证110310号