GB/T 37664.1-2019 English PDF

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GB/T 37664.1-2019: Nanomanufacturing -- Key control characteristics -- Luminescent nanomaterials -- Part 1: Quantum efficiency
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Basic data

Standard ID: GB/T 37664.1-2019 (GB/T37664.1-2019)
Description (Translated English): Nanomanufacturing -- Key control characteristics -- Luminescent nanomaterials -- Part 1: Quantum efficiency
Sector / Industry: National Standard (Recommended)
Classification of Chinese Standard: G04
Classification of International Standard: 71.040.50
Word Count Estimation: 26,239
Date of Issue: 2019-06-04
Date of Implementation: 2019-06-04
Issuing agency(ies): State Administration for Market Regulation, China National Standardization Administration

GB/T 37664.1-2019: Nanomanufacturing -- Key control characteristics -- Luminescent nanomaterials -- Part 1: Quantum efficiency

---This is a DRAFT version for illustration, not a final translation. Full copy of true-PDF in English version (including equations, symbols, images, flow-chart, tables, and figures etc.) will be manually/carefully translated upon your order.
Nanomanufacturing - Key control characteristics - Luminescent nanomaterials - Part 1.Quantum efficiency ICS 71.040.50 G04 National Standards of People's Republic of China Nano-manufacturing key control characteristics Part 1.Quantum efficiency (IEC 62607-3-1.2014, Nanomanufacturing-Keycontrolcharacteristics- 2019-06-04 released 2019-06-04 implementation State Administration for Market Regulation Issued by China National Standardization Administration

Table of contents

Preface Ⅲ Introduction Ⅳ 1 Scope 1 2 Normative references 1 3 Terms and definitions 1 4 Test notes 3 4.1 Overview 3 4.2 Environmental conditions 3 4.3 Brightening and photobleaching 3 4.4 Luminescence of pollutants when the excitation wavelength is less than 380nm 4 4.5 Industrial Hygiene 4 5 Measurement of relative quantum efficiency 4 5.1 Overview 4 5.2 Equipment 4 5.2.1 Equipment to be equipped 4 5.2.2 Instrument and equipment installation 4 5.3 Calibration 5 5.3.1 General 5 5.3.2 Preparation of calibration standard solution 6 5.3.3 Measurement of standard solutions for calibration 6 5.4 Experimental Step 7 5.4.1 Measurement of calibration standards 7 5.4.2 Measurement of luminescent nanoparticle samples 7 6 Measurement of absolute quantum efficiency 9 6.1 Overview 9 6.2 Test equipment 10 6.3 Calibration 11 6.4 Sample preparation 12 6.4.1 General 12 6.4.2 Liquid samples 12 6.4.3 Solid samples 12 6.5 Test Step 12 6.5.1 Collimated incident light method 12 6.5.2 Diffuse incident light method 15 7 Explanation of uncertainty 16 8 Test report 16 Appendix A (informative appendix) Avoid temperature quenching to achieve the best measurement conditions 18 A.1 Overview 18 A.2 Solution for temperature quenching 18 Reference 20 Figure 1 Example of calculation of absorption spectrum of cresol purple 6 Figure 2 Schematic diagram of the configuration of test equipment for collimated incident light method and diffuse reflected incident light method 10 Figure 3 Spectra of samples measured by collimated incident light method 14 Figure 4 Spectra of the sample measured by diffuse reflection incident light method 16 Figure A.1 Example of transient behavior of luminescent material (YAG.Ce) under pulse excitation 18 Figure A.2 Normalized quantum efficiency change with average excitation power and preferred input power range (shown by vertical lines) 19 Table 1 Examples of relative fluorescence measurement methods 5 Table 2 Several reference materials for relative quantum efficiency measurement 5 Table 3 Comparison of quantum efficiency data using Table 8 Table 4 Quantum efficiency data comparison table 9 Table 5 Comparison of methods for measuring absolute quantum efficiency of luminescent nanoparticles 9

Foreword

The plan of GB/T 37664 "Nanomanufacturing Key Control Characteristics Luminescent Nanomaterials" is divided into the following parts. ---Part 1.Quantum efficiency; ---Part 2.The quality of quantum dot dispersion. This part is Part 1 of GB/T 37664. This section was drafted in accordance with the rules given in GB/T 1.1-2009. The translation method used in this part is equivalent to IEC 62607-3-1.2014 "Nanomanufacturing Key Control Characteristics Part 3-1.Luminous Nano Quantum efficiency of rice materials. This section has made the following editorial changes. ---Change the standard name to "Nano-manufacturing key control characteristics of luminescent nanomaterials Part 1.Quantum efficiency". This part was proposed by the Chinese Academy of Sciences. This part is under the jurisdiction of the National Nanotechnology Standardization Technical Committee (SAC/TC279). Drafting organizations of this section. National Nanoscience Center, Beijing Zhongjiao Jinyuan Technology Co., Ltd., Beijing Institute of Technology, Tianmei (China) Science Instrument Co., Ltd., Beijing Beida Jubang Technology Co., Ltd., Nano Crystal Technology Co., Ltd., Xiamen Rare Earth Materials Research Institute, Suzhou Xingshuo Na Mi Technology Co., Ltd. The main drafters of this section. Zhang Donghui, Ge Guanglu, Cai Chunshui, Wang Xinwei, Zhong Haizheng, Chen Bingkun, Zhang Hairong, Guo Haiqing, Zhao Zhiqiang, Kang Yongyin, Marx and Wang Yunjun.

Introduction

One of the main driving forces in the development of solid state lighting (SSL) field comes from the improvement of the electro-optical conversion efficiency of lighting devices. high. The efficiency of incandescent lighting devices and fluorescent lighting devices is only about 5% to 30%, and the efficiency of incandescent lighting devices is the lowest. According to Ming is the main source of electrical energy consumption, so improving the conversion efficiency of lighting devices will greatly affect the world's energy consumption pattern. SSL device The measurement of luminous efficiency is the key to its overall efficiency measurement. At present, standard methods for these measurements have been established. These methods are very important for manufacturers and consumers. It is important for consumers to obtain reliable product information. The measurement of luminous efficiency is also important for the luminescent materials that light-emitting diode (LED) manufacturers rely on. It is very important, but there is no standard for measuring the luminous efficiency of such materials. This section provides a comparison for SSL manufacturers from different Supplier's general method of luminous efficiency of luminescent nanomaterials, this method can also be used for general LED luminescent materials. A conventional SSL device contains a blue LED chip and a luminescent material, and the blue LED excites the luminescent material to emit monochromatic light of appropriate color Or multi-color light to produce the desired white spectrum. This device is called a fluorescence conversion type light-emitting diode (or pc-LED), which first produces blue Light converts part of the blue light into broadband visible light radiation, and indirectly converts electrical energy into white light. Quantum dots (QDs) or nano phosphors are photoinduced A new type of luminescent material, this type of material can convert blue LED waves into broad-spectrum visible light. Compared with the traditional size larger than 5μm Compared with typical phosphor particles, quantum dots and nano phosphors have greater color tunability, narrowband emission spectrum, broadband absorption, and nearly unlimited flocculation. The characteristics of setting time, not easy to bleach and weak scattering, so the application of QDs and nano phosphors in this field has attracted widespread attention. QD-based pc-LED is superior to other pc-LEDs on the market in comprehensive performance such as color rendering index, color temperature and lumen efficiency. In the lighting industry, quantum efficiency is a key parameter of luminescent materials. In this section, the meaning of fluorescence quantum efficiency is the emission of luminescent nanoparticles. The ratio of the number of emitted photons to the number of absorbed photons is also called fluorescence quantum yield. Because the measurement of relative quantum efficiency is easier, and this Application of measurement in biomedical imaging (QDs are widely used in the field of biomedical imaging R Suppliers of luminescent nanomaterials usually only measure the relative quantum efficiency (or quantum yield) in solution. In order to reduce the agglomeration and weight of nanoparticles The influence of absorption is usually measured at low concentrations. However, the actual concentration of luminescent nanomaterials in the final application May vary. For example, in order to meet the requirements for luminous flux and color temperature in SSL devices, a high concentration of luminescent nanoparticles may be required (Solid or liquid) formula products. This section standardizes this method for the first time, whether it is a solution or a solid, as long as a solid state (e.g., Luminous nanoparticles embedded in a polymer matrix, coated on optical glass, directly applied to light-emitting diodes, and other forms) and solutions A test method for the absolute quantum efficiency of samples (e.g., colloidal suspensions of luminescent nanoparticles), suppliers and users can compare different materials Between performance. Nano-manufacturing key control characteristics Part 1.Quantum efficiency

1 Scope

This part of GB/T 37664 specifies the steps and precautions to be followed in the repeatable measurement of quantum efficiency of luminescent nanomaterials. The luminescent nanomaterials applicable to this part include quantum dots, nano phosphors, nanoparticles, nanofibers, nanocrystals, nanosheets and containing The structure of these materials. Luminescent nanomaterials can be dispersed in the liquid phase (for example, colloidal quantum dots) or in the solid phase (for example, containing Nanofibers of luminescent nanoparticles). This part not only specifies the relative measurement method of quantum efficiency of liquid luminescent nanomaterials, but also specifies Absolute measurement method for quantum efficiency of state and liquid nanomaterials.

2 Normative references

The following documents are indispensable for the application of this document. For dated reference documents, only the dated version applies to this article Pieces. For undated references, the latest version (including all amendments) applies to this document. ISO /T S80004-2.2015 Nanotechnology terminology Part 2.Nano objects (Nanotechnologies-Vocabulary- Part 2.Nano-objects) CIE017/E.2011 International Lighting-Vocabulary

3 Terms and definitions

CIE017/E.2011, ISO /T S80004-2.2015 and the following terms and definitions apply to this document. 3.1 Absorbance At a specific wavelength, the negative logarithm of the ratio of the light intensity (I) transmitted through the sample to the incident light intensity (I0) based on the base 10. Note. Mathematical expression. absorbance = -lg (I/I0). In order to ensure the correctness of this equation, other losses (for example, reflection and scattering) must be appropriately corrected. 3.2 Absorptance In a given spectral range, the ratio of the radiation or luminous flux absorbed by the medium to the incident optical radiation or luminous flux. Note. The sum of reflectance, transmittance and absorption is 1. 3.3 Absorption The process by which matter absorbs incident light photons and converts them into another form of energy (for example, heat). Note. The incident photon flux includes absorption, reflection and transmission. 3.4 Collimated incident light method A method of measuring absolute quantum efficiency by introducing collimated light into the integrating sphere containing the sample to be tested and using the collimated beam (for example, laser). 3.5 Diffuse incident light method The diffuse reflection light is introduced into the integrating sphere containing the sample to be tested, and the absolute quantum efficiency is measured by the diffuse reflection beam. The diffuse reflection beam comes from ......

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