Copolymerized PP

Rank	Match %	Compound Name	Formula / SMILES	Library preview	Action
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Rank

Match %

Compound Name

Formula / SMILES

Library preview

Action

Reference candidates load with this Top-15 workbench.

Evidence

Key evidence

Китепкананын алдыңкы дал келүүсү

Copolymerized PP #713 | match 89.0%

Материалдын багыты

Copolymerized PP (polypropylene copolymer) The sample is identified as Copolymerized PP, a polypropylene copolymer. The observed infrared spectrum matches the library reference spectrum of Copolymerized PP (#713) with high similarity (0.875), and the overall band pattern is characteristic of polyolefin materials containing both methyl and methylene groups.

Supporting peaks

424 cm-1 467 cm-1 537 cm-1 719 cm-1 809 cm-1 841 cm-1 876 cm-1 900 cm-1

Supporting groups

aromatic methyl n_h alkyl_c_h silicon_oxygen c_o_single_bond aliphatic_c_h_stretch ch2/ch3_bending

Support

Evidence supporting the conclusion

Only sample-relevant statements that support the present conclusion are shown here.

The sample is identified as Copolymerized PP, a polypropylene copolymer. The observed infrared spectrum matches the library reference spectrum of Copolymerized PP (#713) with high similarity (0.875), and the overall band pattern is characteristic of polyolefin materials containing both methyl and methylene groups.
reference library comparison returned Copolymerized PP (#713) at similarity 0.875, closely followed by other polypropylene entries (PP, 0.875; PP, 0.870; Copolypropylene, 0.871), confirming a polypropylene‐based composition.
The reference interpretation notes that the co‐occurrence of these characteristic bands in models for polyolefin and polypropylene‐based polymer classes reinforces a hydrocarbon backbone interpretation.
The strong C-H stretching absorptions at 2950, 2917, 2868, and 2847 cm⁻¹ are consistent with asymmetric and symmetric CH3 and CH2 stretching vibrations typical of aliphatic hydrocarbon backbones in polyolefins.
The band at 1375 cm⁻¹ is assigned to the symmetric bending of methyl (CH3) groups, a distinctive feature of polypropylene, while the band at 1458 cm⁻¹ corresponds to CH2 and CH3 bending modes.
In the fingerprint region, the cluster of bands at 1166, 1101, 973, 809, and 719 cm⁻¹ matches the spectral pattern observed in polypropylene and copolymerized PP reference spectra, and is analogous to fingerprint variables used in multivariate FTIR models for polyolefin classification (Sciutto et al., 2017).
A peak at approximately 1033 cm⁻¹ can be attributed to C–C skeletal vibrations, which are common in polypropylene backbones.
Major peak assignments include 2917: Related literature: hydrocarbon polymer fingerprint resembling polypropylene / copolypropylene | Direct reference: alkyl c h; c o single bond; 1375: Related literature: hydrocarbon polymer fingerprint resembling polypropylene / copolypropylene | Direct reference: alkyl c h; c o single bond; 2950: Related literature: hydrocarbon polymer fingerprint resembling polypropylene / copolypropylene; 1458: Related literature: hydrocarbon polymer fingerprint resembling polypropylene / copolypropylene | Direct reference: alkyl c h; c o single bond.

Limitations

Evidence that limits the conclusion

Direct‑literature evidence returned a wide range of group assignments (e.g., O–Mg–O, Zn–O, tetrahedral sites, Si–O) from sources that are not chemically compatible with the polyolefin material; these reflect the diversity of the literature corpus rather than meaningful spectral evidence for the present sample.
The small peak at about 1033 cm⁻¹ could partly reflect minor oxidation or the presence of additives, but it does not undermine the primary identification.
The exact comonomer composition (e.g., ethylene content) cannot be inferred from the FTIR spectrum alone without a suitable calibration.

Recommendation

Suggested next verification

Perform differential scanning calorimetry (DSC) to confirm the copolymer type (random or block) and to estimate the ethylene/propylene ratio.
If further confirmation is required, obtain a ¹³C NMR spectrum to quantify the levels of ethylene incorporation.

Index	Characteristic	Wavenumber	Absorbance	Evidence	One-line interpretation	Citation	Confidence
1	★	2917	1.00	Адабият менен колдоого алынган ыйгаруу	2917 cm-1 тилкеси alkyl C-H[33] дайындалган.	[33]	LLM ишеним деңгээли
2	★	1375	0.59	Адабият менен колдоого алынган ыйгаруу	1375 cm-1 тилкеси alkyl C-H[32] дайындалган.	[32]	LLM ишеним деңгээли
3	★	2950	0.55	Адабият менен колдоого алынган ыйгаруу	2950 cm-1 тилкеси alkyl C-H[30] дайындалган.	[30]	LLM ишеним деңгээли
4	★	1458	0.42	Адабият менен колдоого алынган ыйгаруу	1458 cm-1 тилкеси alkyl C-H[29] дайындалган.	[29]	LLM ишеним деңгээли
5	★	2847	0.39	Адабият менен колдоого алынган ыйгаруу	2847 cm-1 тилкеси alkyl C-H[31] дайындалган.	[31]	LLM ишеним деңгээли
6	·	2868	0.33	-	-	-	-
7	·	1000	0.18	-	-	-	-
8	★	1033	0.17	Адабият менен колдоого алынган ыйгаруу	1033 cm-1 тилкеси C-C single bond[34] дайындалган.	[34]	Жалпы ишенимдүүлүк
9	·	467	0.13	-	-	-	-
10	·	1359	0.13	-	-	-	-
11	★	973	0.13	Адабият менен колдоого алынган ыйгаруу	973 cm-1 тилкеси alkyl C-H[25] дайындалган.	[25]	Жалпы ишенимдүүлүк
12	★	1101	0.13	Аналогиялык адабият тапшыруусу	1101 cm-1 тилкеси hydrocarbon polymer fingerprint resembling polypropylene / copolypropylene[26][27][28][S3][S4] дайындалган.	[26], [27], [28], [S3], [S4]	Жалпы ишенимдүүлүк
13	★	719	0.11	Адабият менен колдоого алынган ыйгаруу	719 cm-1 тилкеси alkyl C-H[35] дайындалган.	[35]	LLM ишеним деңгээли
14	★	1166	0.10	Аналогиялык адабият тапшыруусу	1166 cm-1 тилкеси hydrocarbon polymer fingerprint resembling polypropylene / copolypropylene[26][27][28][S3][S4] дайындалган.	[26], [27], [28], [S3], [S4]	Жалпы ишенимдүүлүк
15	·	841	0.09	-	-	-	-
16	·	537	0.09	-	-	-	-
17	·	424	0.07	-	-	-	-
18	·	3695	0.06	-	-	-	-
19	★	809	0.06	Аналогиялык адабият тапшыруусу	809 cm-1 тилкеси hydrocarbon polymer fingerprint resembling polypropylene / copolypropylene[26][27][28][S3][S4] дайындалган.	[26], [27], [28], [S3], [S4]	Жалпы ишенимдүүлүк
20	·	900	0.06	-	-	-	-
21	·	1633	0.05	-	-	-	-
22	·	2722	0.04	-	-	-	-
23	·	3155	0.04	-	-	-	-
24	·	876	0.03	-	-	-	-

Index

Characteristic

Wavenumber

Absorbance

Evidence

One-line interpretation

Citation

Confidence

★

2917

1.00

Адабият менен колдоого алынган ыйгаруу

2917 cm-1 тилкеси alkyl C-H[33] дайындалган.

[33]

LLM ишеним деңгээли

★

1375

0.59

Адабият менен колдоого алынган ыйгаруу

1375 cm-1 тилкеси alkyl C-H[32] дайындалган.

[32]

LLM ишеним деңгээли

★

2950

0.55

Адабият менен колдоого алынган ыйгаруу

2950 cm-1 тилкеси alkyl C-H[30] дайындалган.

[30]

LLM ишеним деңгээли

★

1458

0.42

Адабият менен колдоого алынган ыйгаруу

1458 cm-1 тилкеси alkyl C-H[29] дайындалган.

[29]

LLM ишеним деңгээли

★

2847

0.39

Адабият менен колдоого алынган ыйгаруу

2847 cm-1 тилкеси alkyl C-H[31] дайындалган.

[31]

LLM ишеним деңгээли

2868

0.33

1000

0.18

★

1033

0.17

Адабият менен колдоого алынган ыйгаруу

1033 cm-1 тилкеси C-C single bond[34] дайындалган.

[34]

Жалпы ишенимдүүлүк

467

0.13

1359

0.13

★

973

0.13

Адабият менен колдоого алынган ыйгаруу

973 cm-1 тилкеси alkyl C-H[25] дайындалган.

[25]

Жалпы ишенимдүүлүк

★

1101

0.13

Аналогиялык адабият тапшыруусу

1101 cm-1 тилкеси hydrocarbon polymer fingerprint resembling polypropylene / copolypropylene[26][27][28][S3][S4] дайындалган.

[26], [27], [28], [S3], [S4]

Жалпы ишенимдүүлүк

★

719

0.11

Адабият менен колдоого алынган ыйгаруу

719 cm-1 тилкеси alkyl C-H[35] дайындалган.

[35]

LLM ишеним деңгээли

★

1166

0.10

Аналогиялык адабият тапшыруусу

1166 cm-1 тилкеси hydrocarbon polymer fingerprint resembling polypropylene / copolypropylene[26][27][28][S3][S4] дайындалган.

[26], [27], [28], [S3], [S4]

Жалпы ишенимдүүлүк

841

0.09

537

0.09

424

0.07

3695

0.06

★

809

0.06

Аналогиялык адабият тапшыруусу

809 cm-1 тилкеси hydrocarbon polymer fingerprint resembling polypropylene / copolypropylene[26][27][28][S3][S4] дайындалган.

[26], [27], [28], [S3], [S4]

Жалпы ишенимдүүлүк

900

0.06

1633

0.05

2722

0.04

3155

0.04

876

0.03

No.	Title	DOI	Page
[1]	da Silva 等 - 2020 - From Disposal to Reuse Production of Sustainable	10.3390/su122310159	-
[2]	Vuong Xuan Bui 等 - 2019 - Investigation of Bioactive Glass-Ceramic 60SiO(2)-	10.1155/2019/1528326	-
[3]	Shim 等 - 1998 - Effects of void formation on electrical and optica	10.4028/www.scientific.net/msf.264-268.195	-
[4]	Raghav 等 - 2017 - Nonenzymatic glycosylation of human serum albumin	10.1371/journal	-
[5]	Pro 等 - 2021 - A Spectroscopic Approach to Evaluate the Effects o	10.3390/agriculture11040321	-
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[9]	Arya 和 Sharma - 2018 - Structural, microstructural and electrochemical pr	10.1007/s11581-017-2364-7	-
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[14]	Pulyalina 等 - 2022 - Effect of ionic liquid on formation of copolyimide	10.1038/s41598-022-12377-0	-
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[17]	Graur 等 - 2023 - Novel Copper(II) Complexes with N-4,S-Diallylisoth	10.3390/inorganics11050195	-
[18]	Froehlich 等 - 2013 - Libyan Desert Glass New field and Fourier transfo	10.1111/maps.12223	-
[19]	Dubey 和 Dewangan - 2020 - Rational Design and Characterization of Transderma	10.5530/ijper.54.3s.145	-
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[23]	Aamouche 和 Goormaghtigh - 2008 - FTIR-ATR biosensor based on self-assembled phospho	10.3233/spe-2008-0351	-
[24]	Shahzad 等 - 2012 - Effects of drug-polymer dispersions on solubility	10.1007/s11434-012-5094-2	-
[25]	Veras 等 - 2019 - Compatibility study of rosmarinic acid with excipi	10.1016/j.jsps.2019.09.010	-
[26]	Arya 和 Sharma - 2018 - Structural, microstructural and electrochemical pr	10.1007/s11581-017-2364-7	46
[27]	Sciutto 等 - 2017 - A Multivariate Methodological Workflow for the Ana	10.1155/2017/4938145	9
[28]	Kert 等 - 2021 - Application of Fragrance Microcapsules onto Cotton	10.3390/coatings11101181	13
[29]	Varol 和 Mutlu - 2023 - TGA-FTIR Analysis of Biomass Samples Based on the	10.3390/en16093674	7
[30]	Varrica 等 - 2019 - ATR-FTIR Spectral Analysis and Soluble Components	10.3390/ijerph16142507	8
[31]	Zhao 等 - 2017 - Assessment of HDPE Aged under DC Voltage Combined	-	5
[32]	Premalatha 等 - 2017 - Tamarind seed polysaccharide (TSP)-based Li-ion co	10.1007/s11581-017-1989-x	3
[33]	Viana 等 - 2012 - Adsorption of Sodium Dodecyl Sulfate on Ge Substra	10.3390/ijms13077980	5
[34]	Damastuti 等 - 2023 - High Selectivity Fuel from Efficient CO2 Conversio	10.3390/ma16124314	6
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No.

Title

DOI

Page

[1]

da Silva 等 - 2020 - From Disposal to Reuse Production of Sustainable

10.3390/su122310159

[2]

Vuong Xuan Bui 等 - 2019 - Investigation of Bioactive Glass-Ceramic 60SiO(2)-

10.1155/2019/1528326

[3]

Shim 等 - 1998 - Effects of void formation on electrical and optica