How can you identify GO from FTIR?
This page summarizes the recurring FTIR evidence reported for GO, including the most frequent peaks, supporting functional groups, and literature-backed interpretation patterns. It is a structured evidence page, not a claim of automatic single-spectrum certainty.
Backed by 39 cited sources
Hurtigt svar
GO is usually reported with a recurring pattern of peaks and functional-group evidence. The most useful approach is to cross-check at least two characteristic peaks before treating it as a match, then verify whether the full spectrum still fits the same material family.
Topfortolkning
Mulige materialer / grupper
| Funktionel gruppe | Bevis |
|---|---|
| Methacrylate | 58 |
| Acetate | 58 |
| Hydroxyl (O-H) | 54 |
| C-O single bond | 53 |
| Methoxy (OCH3) | 47 |
| Alkyl C-H | 40 |
| Amide | 32 |
| Carboxyl (COOH) | 29 |
Spektrumlogik
The logic here is evidence aggregation: repeated literature mentions of GO, repeated peak positions, and repeated functional-group associations. A strong material hypothesis should still be supported by multiple peaks that agree with each other, not by one headline band alone.
Anvendelse i virkeligheden
Denne side er designet til polymeridentifikation, kvalitetskontrol af indgående materialer, analyse af ukendt plast, gennemgang af genanvendt indhold og litteraturunderstøttet fortolkning af reference-spektre.
Almindelige fejl
- At kalde et materialematch for tidligt, fordi en berømt top er til stede.
- Ignorer prøveforberedelse, fyldstoffer, oxidation, vand eller additiver, der kan ændre det tilsyneladende mønster.
- Brug af litteraturbevis uden at kontrollere, om din egen prøvetagningsmetode og spektrumkvalitet er sammenlignelige.
Verifikationsrådgivning
Brug DSC, GC-MS eller TGA til at validere materialehypotesen, når topmønstret er tvetydigt eller blandet.
Litteratur bag denne side
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tillid 0,9
GO
A thermal method for obtention of 2 to 3 reduced graphene oxide layers from graphene oxide DOI: 10.1007/s42452-020-03241-9 -
tillid 0,9
GO
Wang 等 - 2015 - Bilayer graphite-oxide anode for organic light-emi DOI: 10.7567/JJAP.54.042101 -
tillid 0,9
GO
Preparation and capacitance performance of Ag–graphene based nanocomposite DOI: 10.1016/j.jpowsour.2011.11.026 -
tillid 0,9
GO
Reduced graphene oxide-intercalated graphene oxide nano-hybrid for enhanced photoelectrochemical water reduction DOI: 10.1007/s40097-019-00324-x -
tillid 0,9
GO
Green syntheses of silver nanoparticle decorated reduced graphene oxide using l-methionine as a reducing and stabilizing agent for enhanced catalytic hydrogenation of 4-nitrophenol and antibacterial activity DOI: 10.1039/c9ra08536j -
tillid 0,9
GO
New Insights into the Interaction between Graphene Oxide and Beta-Blockers DOI: 10.3390/nano9101429 -
tillid 0,9
GO
Sustainable Remedy Waste to Generate SiO2 Functionalized on Graphene Oxide for Removal of U(VI) Ions DOI: 10.3390/su14052699 -
tillid 0,9
GO
Novel plant flavonoid electrochemical sensor based on in-situ and controllable double-layered membranes modified electrode DOI: 10.1371/journal. -
tillid 0,9
GO
Non-Covalent Supported of l-Proline on Graphene Oxide/Fe3O4 Nanocomposite: A Novel, Highly Efficient and Superparamagnetically Separable Catalyst for the Synthesis of Bis-Pyrazole Derivatives DOI: 10.3390/molecules23020330 -
tillid 0,9
GO
Niu 等 - 2014 - Fabrication, structure and mechanism of reduced gr DOI: 10.1039/c0xx00000x
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