DD ISO/TS 12805:2011
Current
The latest, up-to-date edition.
Nanotechnologies. Materials specifications. Guidance on specifying nano-objects
Hardcopy , PDF
English
11-30-2011
Important note : All end users must be registered with an Account prior to user licenses being assigned.
Foreword
Introduction
1 Scope
2 Normative references
3 Terms and definitions
4 Specifying manufactured nano-objects
5 Additional material characteristics that
might influence end-product performance
and/or downstream processability
6 Proposed measurement methods for
determining the characteristics of manufactured
nano-objects identified as important for
specification purposes
7 Possible impacts of contamination on the
properties and performance of manufactured
nano-objects and their mitigation
Annex A (informative) - Figure A.1 - Decision
tree to assist with the use of ISO/TS 12805
Annex B (informative) - Measurement methods
Bibliography
Gives guidance on the preparation of specifications for the characteristics of manufactured nano-objects and their measurement methods.
| Committee |
NTI/1
|
| DocumentType |
Standard
|
| Pages |
32
|
| PublisherName |
British Standards Institution
|
| Status |
Current
|
This Technical Specification provides guidance on the preparation of specifications for the characteristics of manufactured nano-objects and their measurement methods. This is intended to help ensure the delivery of products with consistent properties for subsequent processing and/or final product performance. This Technical Specification includes guidance on specifying the physical and chemical characteristics of manufactured nano-objects, which might affect performance or subsequent processing. A list of applicable measurement methods is given in AnnexB. NOTE1 The nano-objects can be supplied in a dry form or as dispersions in a liquid medium. Guidance on specifying the environmental, health and safety (EHS) characteristics of manufactured nano-objects is outside the scope of this Technical Specification. NOTE2 Nanotechnology is a rapidly growing and evolving field. It is therefore good practice for users of this Technical Specification to maintain an awareness of the legislative environment and latest developments in EHS regarding nanotechnology (see References [1][2][3][4][15][16][38][39][40][41][42][43]). If the customer or supplier wishes to assess the environmental, safety or health risks of the material, they can refer to ISO/TR13121 and ISO/TR12885 for further guidance. This Technical Specification also does not include guidance on specifying materials containing nanosized phases formed in situ by a transformation in the material, e.g. Guinier-Preston zones in precipitation hardening metals. Furthermore, it does not specify quantitative requirements for the object to be considered a nano-object, but lists appropriate examples of characteristics and properties and their measurement methods useful for specifying nano-objects. Characteristics and measurement methods for nano devices are not included. Although this Technical Specification refers to parameters, which could be considered aspects of material quality, it is not intended to provide guidance on the establishment of quality management systems. For guidance on quality management systems, reference can be made to ISO9000.
| Standards | Relationship |
| ISO/TS 12805:2011 | Identical |
| ISO 23145-1:2007 | Fine ceramics (advanced ceramics, advanced technical ceramics) — Determination of bulk density of ceramic powders — Part 1: Tap density |
| ISO 16700:2016 | Microbeam analysis — Scanning electron microscopy — Guidelines for calibrating image magnification |
| ISO 22412:2017 | Particle size analysis — Dynamic light scattering (DLS) |
| ISO/TR 13121:2011 | Nanotechnologies — Nanomaterial risk evaluation |
| ISO 3923-2:1981 | Metallic powders — Determination of apparent density — Part 2: Scott volumeter method |
| ISO 18754:2013 | Fine ceramics (advanced ceramics, advanced technical ceramics) Determination of density and apparent porosity |
| ISO 18114:2003 | Surface chemical analysis Secondary-ion mass spectrometry Determination of relative sensitivity factors from ion-implanted reference materials |
| 2001/95/EC : 2001 AMD 2 2009 | DIRECTIVE 2001/95/EC OF THE EUROPEAN PARLIAMENT AND OF THE COUNCIL OF 3 DECEMBER 2001 ON GENERAL PRODUCT SAFETY (TEXT WITH EEA RELEVANCE) |
| ISO/TS 27687:2008 | Nanotechnologies Terminology and definitions for nano-objects Nanoparticle, nanofibre and nanoplate |
| ISO 18753:2017 | Fine ceramics (advanced ceramics, advanced technical ceramics) — Determination of absolute density of ceramic powders by pycnometer |
| ISO/TR 18394:2016 | Surface chemical analysis Auger electron spectroscopy Derivation of chemical information |
| ISO 14887:2000 | Sample preparation Dispersing procedures for powders in liquids |
| ISO 22048:2004 | Surface chemical analysis Information format for static secondary-ion mass spectrometry |
| ISO 3953:2011 | Metallic powders — Determination of tap density |
| ISO 14707:2015 | Surface chemical analysis Glow discharge optical emission spectrometry (GD-OES) Introduction to use |
| ISO 21501-2:2007 | Determination of particle size distribution Single particle light interaction methods Part 2: Light scattering liquid-borne particle counter |
| ISO 13321:1996 | Particle size analysis Photon correlation spectroscopy |
| EN 13925-1:2003 | Non-destructive testing - X-ray diffraction from polycrystalline and amorphous material - Part 1: General principles |
| ISO/IEC Guide 51:2014 | Safety aspects — Guidelines for their inclusion in standards |
| ISO/IEC Guide 50:2014 | Safety aspects — Guidelines for child safety in standards and other specifications |
| ISO 13322-1:2014 | Particle size analysis — Image analysis methods — Part 1: Static image analysis methods |
| ISO/IEC Guide 73:2002 | Risk management Vocabulary Guidelines for use in standards |
| CSA Q850 : 1997 | RISK MANAGEMENT: GUIDELINE FOR DECISION-MAKERS |
| ISO 18757:2003 | Fine ceramics (advanced ceramics, advanced technical ceramics) — Determination of specific surface area of ceramic powders by gas adsorption using the BET method |
| ISO/TS 80004-1:2015 | Nanotechnologies — Vocabulary — Part 1: Core terms |
| ISO 9001:2015 | Quality management systems — Requirements |
| ISO/TS 10867:2010 | Nanotechnologies Characterization of single-wall carbon nanotubes using near infrared photoluminescence spectroscopy |
| ISO/TR 12885:2008 | Nanotechnologies Health and safety practices in occupational settings relevant to nanotechnologies |
| ISO/IEC Guide 71:2014 | Guide for addressing accessibility in standards |
| ISO 20998-1:2006 | Measurement and characterization of particles by acoustic methods Part 1: Concepts and procedures in ultrasonic attenuation spectroscopy |
| ISO 9000:2015 | Quality management systems — Fundamentals and vocabulary |
| ISO 4490:2014 | Metallic powders Determination of flow rate by means of a calibrated funnel (Hall flowmeter) |
| ISO 3923-1:2008 | Metallic powders Determination of apparent density Part 1: Funnel method |
| ISO 6721-10:2015 | Plastics Determination of dynamic mechanical properties Part 10: Complex shear viscosity using a parallel-plate oscillatory rheometer |
| EN 13925-2:2003 | Non-destructive testing - X-ray diffraction from polycrystalline and amorphous materials - Part 2: Procedures |
| EN 13925-3:2005 | Non destructive testing - X ray diffraction from polycrystalline and amorphous materials - Part 3: Instruments |
| ISO 9277:2010 | Determination of the specific surface area of solids by gas adsorption — BET method |
| ISO 13320-1:1999 | Particle size analysis Laser diffraction methods Part 1: General principles |
| ISO 14488:2007 | Particulate materials — Sampling and sample splitting for the determination of particulate properties |
| ISO 20903:2011 | Surface chemical analysis Auger electron spectroscopy and X-ray photoelectron spectroscopy Methods used to determine peak intensities and information required when reporting results |
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