International interlaboratory comparison of Raman spectroscopic analysis of CVD-grown graphene

Turner, Philip J.; Paton, Keith R.; Legge, Elizabeth J.; Bugallo, Andrés De Luna; Rocha-Robledo, Ana Karen Susana; Zahab, Ahmed-Azmi; Centeno, Alba; Sacco, Alessio; Pesquera, Amaia; Zurutuza, Amaia; Rossi, Andrea Mario; Tran, Diana; Silva, Diego L.; Lošić, Dušan; Farivar, Farzaneh; Kerdoncuff, Hugo; Kwon, Hyuk‐Sang; Pirart, Jerome; Campos, João Luiz; Subhedar, Kiran M.; Tay, Li‐Lin; Ren, Lingling; Cançado, Luiz Gustavo; Paillet, Matthieu; Finnie, Paul; Yap, Pei Lay; Arenal, Raúl; Dhakate, Sanjay R.; Wood, Sebastian; Jiménez‐Sandoval, S.; Batten, Tim; Nagyte, Vaiva; Yao, Yaxuan; Walker, Angela Hight; Ferreira, Erlon H. Martins; Casiraghi, Cinzia; Pollard, Andrew J.

doi:10.1088/2053-1583/ac6cf3

Cited by 14 publications

(12 citation statements)

References 83 publications

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“…These parameters are as follows: (1) the number of mass loss steps, (2) thermal stability, (3) temperature of maximum mass change rate ( T p ) for each decomposition step, (4) the mass contents (%) of moisture, oxygen groups, carbon, combustible organic impurities, and (5) the mass content (%) of noncombustible residues. These parameters have been selected to combine the measurement of physical and qualitative and quantitative chemical properties of GR2Ms based on their practical relevance, complementarity with other ISO characterization methods and the developed procedures from both the authors and the literature. − , …”

Section: Introductionmentioning

confidence: 99%

International Interlaboratory Comparison of Thermogravimetric Analysis of Graphene-Related Two-Dimensional Materials

et al. 2023

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Research on graphene-related two-dimensional (2D) materials (GR2Ms) in recent years is strongly moving from academia to industrial sectors with many new developed products and devices on the market. Characterization and quality control of the GR2Ms and their properties are critical for growing industrial translation, which requires the development of appropriate and reliable analytical methods. These challenges are recognized by International Organization for Standardization (ISO 229) and International Electrotechnical Commission (IEC 113) committees to facilitate the development of these methods and standards which are currently in progress. Toward these efforts, the aim of this study was to perform an international interlaboratory comparison (ILC), conducted under Versailles Project on Advanced Materials and Standards (VAMAS) Technical Working Area (TWA) 41 “Graphene and Related 2D Materials” to evaluate the performance (reproducibility and confidence) of the thermogravimetric analysis (TGA) method as a potential new method for chemical characterization of GR2Ms. Three different types of representative and industrially manufactured GR2Ms samples, namely, pristine few-layer graphene (FLG), graphene oxide (GO), and reduced graphene oxide (rGO), were used and supplied to ILC participants to complete the study. The TGA method performance was evaluated by a series of measurements of selected parameters of the chemical and physical properties of these GR2Ms including the number of mass loss steps, thermal stability, temperature of maximum mass change rate (T p) for each decomposition step, and the mass contents (%) of moisture, oxygen groups, carbon, and impurities (organic and non-combustible residue). TGA measurements determining these parameters were performed using the provided optimized TGA protocol on the same GR2Ms by 12 participants across academia, industry stakeholders, and national metrology institutes. This paper presents these results with corresponding statistical analysis showing low standard deviation and statistical conformity across all participants that confirm that the TGA method can be satisfactorily used for characterization of these parameters and the chemical characterization and quality control of GR2Ms. The common measurement uncertainty for each parameter, key contribution factors were identified with explanations and recommendations for their elimination and improvements toward their implementation for the development of the ISO/IEC standard for chemical characterization of GR2Ms.

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Section: Introductionmentioning

confidence: 99%

International Interlaboratory Comparison of Thermogravimetric Analysis of Graphene-Related Two-Dimensional Materials

et al. 2023

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“…A recent interlaboratory study has concluded that the standard deviation of peak widths of graphene spectra, especially for the 2D band, are substantially reduced if Voigt fitting is used instead of Lorentzian. 68 A Voigt function is a convolution of a Gaussian and a Lorentzian function and it captures better the broadening of the 2D mode resulting from doping, strain variations or increasing defect density since the gaussian component of the Voigt can accommodate the change in the peak tails. Therefore, we have developed an alternative code where Lorentzian fitting functions are replaced by a pseudo-Voigt functions as defined in OriginPro 2020 (‘ PsdVoigt1 ’):where y 0 is a constant background, A is the peak area, w is the FWHM, x 0 is the peak center and m u the profile shape-parameter (or gaussian weight/fraction).…”

Section: Methodsmentioning

confidence: 99%

Automated statistical analysis of raman spectra of nanomaterials

Martín Sabanés,

Eaton,

Moreno-Da Silva

et al. 2024

Nanoscale

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“…Instruments 2023, 7, 30 2 of 16 These advantages made Raman spectroscopy a tool used in numerous fields, both in research and technology [5]. Speaking of areas such as the pharmaceutical industry [2], medicine [6,7], analytical chemistry [8][9][10][11], mineralogy [12,13], materials science [14], historical research [9,15], and even forensic science [16], it has revealed many applications. It is easy to see the importance of this technique, but is it suitable for its wide use in highly regulated environments?…”

Section: Introductionmentioning

confidence: 99%

Moving from Raman Spectroscopy Lab towards Analytical Applications: A Review of Interlaboratory Studies

Rusu,

Baia

2023

Instruments

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Is Raman spectroscopy applicable for analytical purposes? Although Raman spectroscopy is a commonly used technique for analyzing sample characteristics and has numerous benefits, it still has several significant limitations that hinder the current tendency to produce the same results regardless of location, equipment, or operator. Overcoming these drawbacks may help to further the development of personalized medicine, diagnosis and treatment, the development of work protocols, and the pursuit of consistent and repeatable performance across all fields. Interlaboratory studies are currently the best way to do this. In this study, we reviewed the interlaboratory studies on Raman spectroscopy conducted to highlight the importance of moving to quantitative analysis in controlled environments. The advantages of Raman spectroscopy, including its high molecular specificity, short spectrum acquisition time, and excellent component identification capabilities, were clearly stated in all experiments. The Raman spectroscopy lab is taking small steps toward analytical applications by figuring out how to accurately predict concentrations in the relevant range of concentrations, developing and verifying the technology, and producing homogenous samples for those investigations.

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International interlaboratory comparison of Raman spectroscopic analysis of CVD-grown graphene

Cited by 14 publications

References 83 publications

International Interlaboratory Comparison of Thermogravimetric Analysis of Graphene-Related Two-Dimensional Materials

International Interlaboratory Comparison of Thermogravimetric Analysis of Graphene-Related Two-Dimensional Materials

Automated statistical analysis of raman spectra of nanomaterials

Moving from Raman Spectroscopy Lab towards Analytical Applications: A Review of Interlaboratory Studies

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