Versailles project on advanced materials and standards | |
Abbreviation | VAMAS |
---|---|
Formation | 1982 |
Founded at | Versailles, France |
Type | Nonprofit |
Methods | International Interlaboratory Comparison (ILC) |
Fields | Materials Science |
Membership | 16 |
Official language | English |
Chair | Nicholas Barbosa (US)[1] |
Secretary | Steve Freiman (US) |
Affiliations | NMI-Australia, NPL-UK, BMTA-UK, NPL-India, NIST-US, NIMS-Japan, AIST-Japan, BAM-Germany, BIPM-France, INMETRO-Brazil, NRC-Canada, ITRI-Chinese Taipei, KRISS-Korea, and CINVESTAV-Mexico, CENAM-Mexico, NMISA-South Africa, UNIBS-Italy, ENEA-Italy, INRIM-Italy, NIM-China, APMP, BIPM, ISO, IEC |
Website | www |
Formerly called | Materials Research and Development Project |
VAMAS stands for Versailles Project on Advanced Materials and Standards. It is a collaborative project that was initiated at the 1982 G7 Economic Summit in Versailles to develop and promote standards for the characterisation of advanced materials, including surfaces, interfaces, thin films, and nanostructures. Using interlaboratory studies, the VAMAS project has developed a number of standard test methods and reference materials for a wide range of materials. These standards have been widely adopted by industry and academic researchers, and have contributed to the development of new materials and technologies.
History
G7 summits proposals
The Versailles project on advanced materials and standards (VAMAS) was first proposed, among 18 other projects, at the 1982 G7 Economic Summit held at the Palace of Versailles.[2]
However the proposal materialised during the 1983 G7 summit in the US where there was a focus on issues related to science and technology. During that meeting, the attendees acknowledged the importance of collaborating in the field of science and technology. The proposals for cooperation came from the French President François Mitterrand, which were presented in a lengthy speech highlighting the necessity of creating a new international division of labour for technology.[3]
The proposal was met with scepticism from the US, but George A. Keyworth, director of the White House's Office of Science and Technology Policy (OSTP), was enthusiastic about the idea of international cooperation in science and technology. He argued that the massive cost of experimental facilities in areas such as high-energy physics and fusion research made international collaboration desirable. Both Europe and the United States were spending approximately half a billion dollars a year on controlled fusion, with Japan spending another quarter of a million dollars. Keyworth believed that this highly redundant research could be avoided with greater collaboration.[3]
"The single most important outcome [of the initiative] is that science and technology have been discussed at two successive summits by the heads of state," says Robin Nicholson, chief scientific adviser to British Prime Minister Margaret Thatcher. "That has never happened before, and it must be significant for science and technology that it is happening now."[3]
The French, under the guidance of President Mitterrand's personal adviser, Jacques Attali, who chaired the Versailles working group, provided a more pragmatic approach to the working groups to bridge the political gap between Mitterrand's interventionist position, broadly supported by Japan and Italy, and the United States' free-trade position, adopted by West Germany and the United Kingdom. The working group included a reference to the need to restrict the transfer of militarily technology to Soviet bloc.[3]
During the summits, the Working Group on Science and Technology proposed 18 specific cooperation projects, with one or more of the seven nations and the European Economic Community taking organising responsibility for each project. The projects included high-energy physics, solar system exploration, remote sensing from space, advanced robotics, biological sciences, photosynthesis, the impact of new technologies on mature industries, high-speed ground transportation, public acceptance of new technologies, and aquiculture.[3]
The United States declined to participate in projects in which it claimed government actions could impinge on the interests of the private sector, including the biotechnology project, which was led by France and generated the most controversy. Initially, France and Japan argued strongly for the internationalisation of biotechnology research.[3] The UK requested to co-lead the biotechnology subject with France, but France's interest in the subject was criticised as "idiosyncratic" by the UK Chief Scientist.[4]
The UK also nominated a Working Group to report on the theme of collaborative projects relating to "Technology, Growth and Employment,” which developed the “Materials research and development” project that was jointly led by the UK and the US. This last project became the “Versailles Project on Advanced Materials and Standards”, or VAMAS.[4]
Inception
The VAMAS project was proposed by Robin Nicholson. Nicholson presented the proposal at IUVSTA meeting in Brighton, UK, in 1982, where it was well-received and subsequently led to the establishment of the VAMAS project. Nicholson and his colleagues recognised the need for international standards for the characterisation of surfaces and interfaces using X-ray photoelectron spectroscopy (XPS) and Auger electron spectroscopy (AES), and proposed the idea for a collaborative project to develop and promote such standards. The proposal was a result of a collaboration between the National Physical Laboratory and the UK Department of Trade and Industry, and it received significant support from the international scientific community.
Then, the proposal was put forward by Nicholson (Government Chief Scientist) to Prime Minister Thatcher to consider on 8 October 1982. In his letter, Nicholson outlined UK capabilities in excelling in Materials science research and development but “failed to reap the commercial rewards”[4] VAMAS was meant to address the “entire materials cycle [which] is a fundamental component of economic production and technological innovation” (said President Regan), including the lack of agreed standards, test procedures, etc., which prevents the European Community from being taken as a single market for a new product involving the use of new materials.[4]
On 15 October 1982, Thatcher agreed to the proposed approach,[4] and during the early stages of the project, the Margaret Thatcher government provided significant financial and political support. Thatcher herself was reported to have taken a keen interest in its progress.
The United States expressed its intention to play an active role. The United Kingdom and the United States became the leading countries.[4] Out of the original 18 projects, VAMAS is the only project that continues to this date.[5]
Formation
The first VAMAS meeting was held at the National Physical Laboratory (NPL) in Teddington, London, in 1983. There, Ernest Hondros was selected as the Chair for the Steering Committee.[6]
VAMAS founding countries are (1982-1983): Canada, France, Germany, Italy, Japan, UK, USA, and European Economic Community. Brazil, Mexico, Chinese Taipei, South Africa, Australia, South Korea, and India joined later between 2007 and 2008, and China joined in 2013. VAMAS is supported by leadership in National measurement institutes (NMI) including NPL, National Institute for Materials Science (NIMS),[7] National Bureau of Standards (today's National Institute of Standards and Technology, NIST),[8] The British measurement and testing association (BMTA),[9] International Bureau of Weights and Measures (BIPM),[10] and Federal Institute for Materials Research and Testing (BAM).[11][12]
VAMAS signed a memorandum with International Organization for Standardization (ISO) in 1993,[5] International Electrotechnical Commission (IEC) in 1995,[13] International Bureau of Weights and Measures (BIPM) and Asia Pacific Metrology Programme (APMP) in 2020.
First VAMAS technical groups included “Wear Test Methods”[14] lead by Horst Czichos (Germany),[15] “Surface Chemical Analysis” led by Cedric J Powell (US),[16] “Polymer Blends” led by Lechoslaw Utracki (Canada), and "Ceramics" led by Phillipe Boch (France).[17][18]
The first round-robin test was held for Wear test methods[19] and the results were reported in 1987.[20]
Objectives
Using new materials is crucial in advancing technology in fields such as electronics, energy, aerospace, and biotechnology. However, these materials have different qualities compared to traditional materials, which poses a challenge in standardisation and testing methods. In order to promote their use and distribution, it is important to consider the international division of labour and future product distribution. Developing international standards for new materials effectively removes technical barriers to trade and promotes global information circulation and data sharing. Unlike conventional materials, new materials must be standardised before the production of the object is standardised, or the use of the method has been socially accumulated. Thus, standardisation for new materials is considered pre-emptive rather than follow-up.[21][22]
VAMAS initiative emerges from these needs as a collaborative endeavour involving national metrology institutes, universities, research institutions, and industry, with the primary goal of promoting international cooperation and accelerating technological advancement by facilitating the exchange of information and standardising measurement methods related to advanced materials.[23] VAMAS support pre-standards research by providing the technical basis for measurements, testing, specifications, and standards.[24] Using interlaboratory studies, this will lead to new improved test procedures, reference materials and data, or algorithms and software with the researchers being drawn from VAMAS and non-VAMAS countries.[25] Results of these activities are submitted to ISO, Regional or National Standards bodies.[26][27]
The project has generated a wealth of technical reports that offer detailed guidance on various aspects of materials characterisation,[28][29] including sample preparation, measurement conditions, data analysis, and reporting.[11][30] These reports are publicly accessible and widely utilised as a reference by researchers, instrument manufacturers, and testing laboratories.[28] In addition to its efforts to establish materials characterisation standards, the VAMAS project has also contributed to the development of international standards for other areas of materials science, such as mechanical testing,[14] thermal analysis,[31] powder diffraction,[32] X-ray photoelectron spectroscopy (XPS),[33] Auger electron spectroscopy (AES),[34] and secondary ion mass spectrometry (SIMS).[35] Its endeavours have led to the emergence of new materials and technologies and fostered international collaboration in research and development.[28][36]
More than 85 national, regional or international standards, 50 VAMAS reports, 5 ISO technology trends assessments (TTA), and 600 publications were resulted from VAMAS work.[37][38]
Structure
Steering Committee
VAMAS has a Steering Committee and a Technical Working Groups, with the latter responsible for conducting research cooperation activities in each technical field and managing research projects. The majority of joint research themes adopted by the Steering Committee focus on standardising testing and evaluation techniques. The Steering Committee, which includes representatives from Member States and the European Commission, has approves the launch of several sector working parties to promote the use of advanced materials in high-technology products and encourage international trade. This can be achieved through either national experts agreeing on compatible standards or through multilateral research to establish scientific and metrological bases for standardisation.[39]
The Steering Committee has a Chair and secretariat both from the same host institute, and they are elected every 5 years. The secretariat publishes announcements of the Technical Working Group's activities. The Steering Committee meets annually.
Technical work areas
VAMAS technical work areas (TWA) are list for active[40] and completed.[41]
1 Wear Test Methods | 2 Surface Chemical Analysis[42] | 3 Ceramics for Structural Applications[43] |
4 Multiphase Polymers | 5 Polymer Composites[44] | 6 Superconducting and Cryogenic Structural Materials |
7 Biomaterials | 8 Hot Salt Corrosion Resistance | 9 Weld Characteristics |
10 Computerised Materials Data | 11 Creep Crack Growth | 12 Efficient Test Procedures for Polymers |
13 Low Cycle Fatigue | 14 Unified Classification System for Advanced Ceramics | 15 Metal Matrix Composites |
16 Superconducting Materials[45] | 17 Cryogenic Structural Materials | 18 Statistical Techniques for Interlaboratory Studies |
19 High-Temperature Fracture of Brittle Materials | 20 Residual Stress[46] | 21 Mechanical Measurements for Hardmetals |
22 Mechanical Properties of Thin Films and Coatings | 23 Thermal Properties of Thin Films | 24 Performance Related Properties of Electroceramics[47] |
25 Creep, Fatigue Crack Growth in Components | 26 Full Field Optical Stress and Strain Measurement | 27 Characterisation Methods for Ceramic Powders and Green Bodies |
28 Quantitative Mass Spectrometry of Synthetic Polymers | 29 Nanomechanics applied to Scanning Probe Microscopy | 30 Tissue Engineering |
31 Creep, Crack and Fatigue Growth in Weldments[48][49] | 32 Modulus Measurements | 33 Polymer Nanocomposites[50] |
34 Nanoparticle Populations[51][52] | 35 Materials Databases Interoperability | 36 Printed, flexible and stretchable electronics[53] |
37 Quantitative Microstructural Analysis[54] | 38 Thermoelectric Materials | 39 Solid Sorbents[55] |
40 Synthetic Biomaterials[56] | 41 Graphene and Related 2D Materials[57] | 42 Raman Spectroscopy and Microscopy[58] |
43 Thermal Properties[31] | 44 Self-Healing Ceramics | 45 Micro and Nano Plastics in the Environment[59] |
International Interlaboratory Comparison
International Interlaboratory Comparison is a method of ensuring the accuracy and reliability of testing results by comparing the measurements made by different laboratories worldwide.[60] In this method, a sample is sent to multiple laboratories in round-robin tests,[61] and each laboratory measures the same sample using their respective methods and equipment.[62] The results are then compared to identify any differences or discrepancies, and to evaluate the consistency and reliability of the methods used by each laboratory.[30] This process helps to ensure that the testing and measurement methods used by laboratories are accurate, and that the results obtained can be trusted and used confidently.[63][64][65]
References
- ↑ "Steering Committee Representatives". www.vamas.org. Retrieved 2023-12-14.
- ↑ Dickson, David (1983-06-17). "Scientific Cooperation Endorsed at Summit". Science. 220 (4603): 1252–1253. Bibcode:1983Sci...220.1252D. doi:10.1126/science.220.4603.1252. ISSN 0036-8075. PMID 17769355.
- 1 2 3 4 5 6 Dickson, David (1983-06-17). "Scientific Cooperation Endorsed at Summit". Science. 220 (4603): 1252–1253. Bibcode:1983Sci...220.1252D. doi:10.1126/science.220.4603.1252. ISSN 0036-8075. PMID 17769355.
- 1 2 3 4 5 6 "Dr. Nicholson letter to 10 Downing stress 2.0631".
- 1 2 "VAMAS - Versailles Project on Advanced Materials and Standards". ISO. Retrieved 2023-03-30.
- ↑ Seah, Martin P.; Lea, Colin (June 2018). "Anastasios Demetrios Hondros CMG FRS. 18 February 1930—13 September 2016". Biographical Memoirs of Fellows of the Royal Society. 64: 231–248. doi:10.1098/rsbm.2017.0032. ISSN 0080-4606. S2CID 58542665.
- ↑ "National Institute for Materials Science - About VAMAS". www.nims.go.jp. Archived from the original on 2022-10-10. Retrieved 2022-10-10.
- ↑ "Versailles Project on Advanced Materials and Standards". NIST. 2022-05-10. Archived from the original on 2022-10-10. Retrieved 2022-10-10.
- ↑ "Versailles Project on Advanced Materials and Standards (VAMAS) - British Measurement and Testing Association". www.bmta.co.uk. Archived from the original on 2022-10-10. Retrieved 2022-10-10.
- ↑ "VAMAS - BIPM". www.bipm.org. Archived from the original on 2022-10-10. Retrieved 2022-10-10.
- 1 2 "News - VAMAS interlaboratory comparison on "Surface analysis of oxide nanoparticles" - Call for participation". www.bam.de. Archived from the original on 2022-10-10. Retrieved 2022-10-10.
- ↑ "VAMAS Structure". www.vamas.org. Archived from the original on 2022-10-10. Retrieved 2022-10-10.
- ↑ "Global partnerships | IEC". www.iec.ch. Retrieved 2023-04-13.
- 1 2 Czichos, Horst; Becker, Susanne; Lexow, Jürgen (1987-01-15). "Multilaboratory tribotesting: Results from the Versailles Advanced Materials and Standards programme on wear test methods". Wear. 114 (1): 109–130. doi:10.1016/0043-1648(87)90020-2. ISSN 0043-1648. Archived from the original on 2023-03-25. Retrieved 2023-03-25.
- ↑ Becker, S; Lexow, J (April 1986). "INTRODUCTION TO THE VERSAILLES PROJECT ON ADVANCED MATERIALS AND STANDARDS(VAMAS) TECHNICAL WORKING AREA: WEAR TEST METHODS". NBS/BAM 1986 Symposium on Advanced Ceramics Berlin: 111–123.
- ↑ Powell, C. J. (January 1988). "The development of standards for surface analysis". Surface and Interface Analysis. 11 (1–2): 103–109. doi:10.1002/sia.740110113. ISSN 0142-2421.
- ↑ L Schwartz, BW Steiner (1986). "Versailles Project on Advanced Materials and Standards". Journal STAND. NEWS Stand. News. 14 (10): 40.
- ↑ Early, James G.; Rook, Harry L. (January 1996). "Versailles project on advanced materials and standards (VAMAS)". Advanced Materials. 8 (1): 9–12. Bibcode:1996AdM.....8....9E. doi:10.1002/adma.19960080102. ISSN 0935-9648.
- ↑ Bassani, Roberto; Meozzi, Mario (1986). "VAMAS:(Versailles Project Advanced Materials and Standards): Sottoprogetto WTM (Wear Test Methods): Results of the International Round Robin, First Phase". Università degli studi di Pisa.
- ↑ Czichos, Horst; Becker, Susanne; Lexow, Jürgen (1987-01-15). "Multilaboratory tribotesting: Results from the Versailles Advanced Materials and Standards programme on wear test methods". Wear. 114 (1): 109–130. doi:10.1016/0043-1648(87)90020-2. ISSN 0043-1648.
- ↑ 正雄, 金尾; 和嘉, 新居; 紀雄, 新谷 (1988). "新材料の試験・評価に関する国際協力". 鉄と鋼. 74 (2): 207–214. doi:10.2355/tetsutohagane1955.74.2_207.
- ↑ Freiman, Stephen; Early, James (2012-04-03), Matsui, Minoru; Jahanmir, Said; Mostaghaci, Hamid; Naito, Makio (eds.), "VAMAS: Accomplishments and Future Directions", Ceramic Transactions Series, 735 Ceramic Place, Westerville, Ohio 43081: The American Ceramic Society, pp. 251–258, doi:10.1002/9781118371480.ch34, ISBN 978-1-118-37148-0, retrieved 2023-03-30
{{citation}}
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- ↑ orsen (2014-07-24). "VAMAS Versailles Project on Advanced Materials and Standards". SlideServe. Archived from the original on 2022-10-10. Retrieved 2022-10-10.
- ↑ Freiman, Stephen (2017-01-20), Mansfield, Elisabeth; Kaiser, Debra L.; Fujita, Daisuke; Van de Voorde, Marcel (eds.), "Versailles Project on Advanced Materials and Standards (VAMAS) and its Role in Nanotechnology Standardization", Metrology and Standardization of Nanotechnology, Weinheim, Germany: Wiley-VCH Verlag GmbH & Co. KGaA, pp. 323–326, doi:10.1002/9783527800308.ch20, ISBN 978-3-527-80030-8, archived from the original on 2022-10-10, retrieved 2022-10-10
- ↑ Early, James G.; Rook, Harry L. (January 1996). "Versailles project on advanced materials and standards (VAMAS)". Advanced Materials. 8 (1): 9–12. Bibcode:1996AdM.....8....9E. doi:10.1002/adma.19960080102. ISSN 0935-9648. Archived from the original on 2022-10-10. Retrieved 2022-10-10.
- ↑ Belsey, Natalie A.; Cant, David J. H.; Minelli, Caterina; Araujo, Joyce R.; Bock, Bernd; Brüner, Philipp; Castner, David G.; Ceccone, Giacomo; Counsell, Jonathan D. P.; Dietrich, Paul M.; Engelhard, Mark H.; Fearn, Sarah; Galhardo, Carlos E.; Kalbe, Henryk; Kim, Jeong Won (2016-10-27). "Versailles Project on Advanced Materials and Standards Interlaboratory Study on Measuring the Thickness and Chemistry of Nanoparticle Coatings Using XPS and LEIS". The Journal of Physical Chemistry C. 120 (42): 24070–24079. doi:10.1021/acs.jpcc.6b06713. ISSN 1932-7447. PMC 5093768. PMID 27818719.
- 1 2 3 Hossain, Kamal (1992-02-01). "Standardization for advanced materials: experience and strategies for the future". Bulletin of Materials Science. 15 (1): 77–89. doi:10.1007/BF02745219. ISSN 0973-7669. S2CID 137483839.
- ↑ Gries, W. H. (1989-05-01). "The Versailles Project on Advanced Materials and Standards (VAMAS) project on ion‐implanted reference materials for surface analysis: September 1988". Journal of Vacuum Science & Technology A. 7 (3): 1639–1640. Bibcode:1989JVSTA...7.1639G. doi:10.1116/1.576063. ISSN 0734-2101. Archived from the original on 2022-10-16. Retrieved 2022-10-10.
- 1 2 Turner, Piers; Paton, Keith R; Legge, Elizabeth J; de Luna Bugallo, Andres; Rocha-Robledo, A K S; Zahab, Ahmed-Azmi; Centeno, Alba; Sacco, Alessio; Pesquera, Amaia; Zurutuza, Amaia; Rossi, Andrea Mario; Tran, Diana N H; L Silva, Diego; Losic, Dusan; Farivar, Farzaneh (2022-07-01). "International interlaboratory comparison of Raman spectroscopic analysis of CVD-grown graphene". 2D Materials. 9 (3): 035010. Bibcode:2022TDM.....9c5010T. doi:10.1088/2053-1583/ac6cf3. ISSN 2053-1583. S2CID 248654909.
- 1 2 "Thermal Poperties". www.vamas.org. Archived from the original on 2022-10-11. Retrieved 2022-10-11.
- ↑ ISO/TTA 3:2001 Polycrystalline materials — Determination of residual stresses by neutron diffraction. International Organization for Standardization. 2001.
- ↑ Reed, Benjamen P.; Cant, David J. H.; Spencer, Steve J.; Carmona-Carmona, Abraham Jorge; Bushell, Adam; Herrera-Gómez, Alberto; Kurokawa, Akira; Thissen, Andreas; Thomas, Andrew G.; Britton, Andrew J.; Bernasik, Andrzej; Fuchs, Anne; Baddorf, Arthur P.; Bock, Bernd; Theilacker, Bill (2020-12-01). "Versailles Project on Advanced Materials and Standards interlaboratory study on intensity calibration for x-ray photoelectron spectroscopy instruments using low-density polyethylene". Journal of Vacuum Science & Technology A. 38 (6): 063208. Bibcode:2020JVSTA..38f3208R. doi:10.1116/6.0000577. ISSN 0734-2101. PMC 7688089. PMID 33281279.
- ↑ Kim, K. J.; Moon, D. W.; Park, C. J.; Simons, D.; Gillen, G.; Jin, H.; Kang, H. J. (August 2007). "Quantitative surface analysis of FeNi alloy films by XPS, AES and SIMS". Surface and Interface Analysis. 39 (8): 665–673. doi:10.1002/sia.2575. S2CID 97604429.
- ↑ Aoyagi, Satoka; Fujiwara, Yukio; Takano, Akio; Vorng, Jean-Luc; Gilmore, Ian S.; Wang, Yung-Chen; Tallarek, Elke; Hagenhoff, Birgit; Iida, Shin-ichi; Luch, Andreas; Jungnickel, Harald; Lang, Yusheng; Shon, Hyun Kyong; Lee, Tae Geol; Li, Zhanping (2021-03-09). "Evaluation of Time-of-Flight Secondary Ion Mass Spectrometry Spectra of Peptides by Random Forest with Amino Acid Labels: Results from a Versailles Project on Advanced Materials and Standards Interlaboratory Study". Analytical Chemistry. 93 (9): 4191–4197. doi:10.1021/acs.analchem.0c04577. ISSN 0003-2700. PMID 33635050. S2CID 232057011. Archived from the original on 2022-10-10. Retrieved 2022-10-10.
- ↑ Seah MP, Kingdom U, Powell CJ (1985). "The Coordinated Development of Standards for Surface Chemical Analysis" (PDF). Archived (PDF) from the original on 2022-10-10. Retrieved 2022-10-10.
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(help)CS1 maint: multiple names: authors list (link) - ↑ "VAMAS - Versailles Project on Advanced Materials and Standards". ISO. Archived from the original on 2023-03-25. Retrieved 2022-10-10.
- ↑ C. J. Powell and R. Shimizu (1988). "Importance of VAMAS and ISO in Developing Reference Standards and Documentary Standards for Practical Surface Analysis". NIST: 1–6. Archived from the original on 2022-10-10. Retrieved 2022-10-10.
- ↑ "Versailles Project on Advanced Materials and Standards (VAMAS)". www.vamas.org. Archived from the original on 2022-10-10. Retrieved 2022-10-10.
- ↑ "VAMAS - Active Technical Working Areas". www.vamas.org. Archived from the original on 2023-03-25. Retrieved 2022-10-10.
- ↑ "VAMAS - Completed Technical Working Areas". www.vamas.org. Archived from the original on 2022-10-10. Retrieved 2022-10-10.
- ↑ "Surface Chemical Analysis". www.vamas.org. Archived from the original on 2022-10-11. Retrieved 2022-10-11.
- ↑ Quinn, George D. (2002-01-01). "The Fracture Toughness Round Robins in VAMAS: What We Have Learned". NIST. Archived from the original on 2022-11-24. Retrieved 2023-03-25.
- ↑ "Polymer Composites". www.vamas.org. Archived from the original on 2017-12-25. Retrieved 2022-10-11.
- ↑ "Superconducting Materials". www.vamas.org. Archived from the original on 2022-10-11. Retrieved 2022-10-11.
- ↑ Agency, International Atomic Energy (2005). Measurement of Residual Stress in Materials Using Neutrons: Proceedings of a Technical Meeting Held in Vienna, 13-17 October, 2003. International Atomic Energy Agency. ISBN 978-92-0-106305-2.
- ↑ "Performance Related Properties for Electroceramics". www.vamas.org. Archived from the original on 2022-10-11. Retrieved 2022-10-11.
- ↑ "Crack growth in Weldments under Creep/Fatigue Loading". www.vamas.org. Archived from the original on 2022-10-11. Retrieved 2022-10-11.
- ↑ Gibbons, T.B. (1992-05-01). "The VAMAS initiative on advanced materials and standards: A unified approach to creep crack growth measurement". Materials at High Temperatures. 10 (2): 66–68. Bibcode:1992MaHT...10...66G. doi:10.1080/09603409.1992.11689402. ISSN 0960-3409.
- ↑ "Polymer Nanocomposites". www.vamas.org. Retrieved 2023-03-25.
- ↑ "Nanoparticle Populations". www.vamas.org. Archived from the original on 2022-10-11. Retrieved 2022-10-11.
- ↑ Minelli, Caterina; Wywijas, Magdalena; Bartczak, Dorota; Cuello-Nuñez, Susana; Infante, Heidi Goenaga; Deumer, Jerome; Gollwitzer, Christian; Krumrey, Michael; Murphy, Karen E.; Johnson, Monique E.; Bustos, Antonio R. Montoro; Strenge, Ingo H.; Faure, Bertrand; Høghøj, Peter; Tong, Vivian (2022-03-24). "Versailles project on advanced materials and standards (VAMAS) interlaboratory study on measuring the number concentration of colloidal gold nanoparticles". Nanoscale. 14 (12): 4690–4704. doi:10.1039/D1NR07775A. hdl:10044/1/95893. ISSN 2040-3372. PMID 35262538. S2CID 247316593. Archived from the original on 2022-10-10. Retrieved 2022-10-10.
- ↑ "Printed, flexible and stretchable electronics". www.vamas.org. Archived from the original on 2022-10-11. Retrieved 2022-10-11.
- ↑ "Quantitative Microstructural Analysis". www.vamas.org. Archived from the original on 2022-10-11. Retrieved 2022-10-11.
- ↑ "Solid Sorbents". www.vamas.org. Archived from the original on 2022-10-11. Retrieved 2022-10-11.
- ↑ "Synthetic Biomaterials". www.vamas.org. Archived from the original on 2022-10-11. Retrieved 2022-10-11.
- ↑ "Graphene and Related 2D Materials". www.vamas.org. Archived from the original on 2022-10-11. Retrieved 2022-10-11.
- ↑ "Raman Spectroscopy and Microscopy". www.vamas.org. Archived from the original on 2021-10-17. Retrieved 2022-10-11.
- ↑ "Micro and Nano Plastics in the Environment". www.vamas.org. Retrieved 2023-03-25.
- ↑ Tachikawa, K.; Koyama, S.; Takahashi, S.; Itoh, K. (June 1995). "The VAMAS intercomparison on the upper critical field measurement in Nb-Ti wire". IEEE Transactions on Applied Superconductivity. 5 (2): 536–539. Bibcode:1995ITAS....5..536T. doi:10.1109/77.402606. ISSN 1558-2515. S2CID 38776704. Archived from the original on 2022-10-10. Retrieved 2022-10-10.
- ↑ "Round Robin Test and Interlaboratory Comparison Program - SPEKTRA". www.spektra-dresden.com. Retrieved 2023-03-30.
- ↑ Turner, Piers; Paton, Keith R; Legge, Elizabeth J; de Luna Bugallo, Andres; Rocha-Robledo, A K S; Zahab, Ahmed-Azmi; Centeno, Alba; Sacco, Alessio; Pesquera, Amaia; Zurutuza, Amaia; Rossi, Andrea Mario; Tran, Diana N H; L Silva, Diego; Losic, Dusan; Farivar, Farzaneh (2022-05-20). "International interlaboratory comparison of Raman spectroscopic analysis of CVD-grown graphene". 2D Materials. 9 (3): 035010. Bibcode:2022TDM.....9c5010T. doi:10.1088/2053-1583/ac6cf3. ISSN 2053-1583. S2CID 248654909.
- ↑ Guthrie, William F. (2007-12-10). "Interlaboratory Comparisons". NIST.
- ↑ RUDOLPH, NATALIE; RIEDL, MILENA (2021-02-14). "Why We Participate in Round Robin Tests and Why You Should Too". NETZSCH.
- ↑ Sjövall, P.; Rading, D.; Ray, S.; Yang, L.; Shard, A. G. (2010-01-21). "Sample Cooling or Rotation Improves C 60 Organic Depth Profiles of Multilayered Reference Samples: Results from a VAMAS Interlaboratory Study". The Journal of Physical Chemistry B. 114 (2): 769–774. doi:10.1021/jp9095216. ISSN 1520-6106. PMID 20020719. Archived from the original on 2022-10-10. Retrieved 2022-10-10.