Silica-based material with possible zinc sulfate and/or zinc oxide co…

Rank	Match %	Compound Name	Formula / SMILES	Library preview	Action
Reference candidates load with this Top-15 workbench.

Rank

Match %

Compound Name

Formula / SMILES

Library preview

Action

Reference candidates load with this Top-15 workbench.

Evidence

Key evidence

لائبریری معروف مماثلت

Zinc sulfate #135252 | match 73.0%

مواد کی سمت

Silica-based material with possible zinc sulfate and/or zinc oxide components The spectrum is dominated by strong silica/siloxane absorptions (Si-O bending at 465 cm⁻¹, Si-O-Si stretching at 1073 and 1099 cm⁻¹, and intertetrahedral Si-O-Si bending at 797 cm⁻¹), indicating a major silicate or silicon dioxide component. The presence of a broad O-H stretch at 3485 cm⁻¹ and a water bending mode at 1645 cm⁻¹ suggests adsorbed moisture or silanol groups. Additionally, weak to moderate bands at 410–493 cm⁻¹ and around 564–600 cm⁻¹ are attributable to metal-oxygen vibrations, compatible with zinc oxide. Bands at 600, 1099, 1117, 1134, 1159, and 1192 cm⁻¹ can be assigned to sulfate S-O stretching and bending modes, consistent with the library-retrieved top candidate zinc sulfate. A peak at 967 cm⁻¹ may arise from SiO₄ tetrahedra or silanol Si-OH vibrations. The overall chemical evidence suggests a silica-dominant material that incorporates zinc and sulfate species; however, the library match confidence is low, and the exact proportions and phases remain uncertain.

Supporting peaks

410 cm-1 425 cm-1 437 cm-1 452 cm-1 465 cm-1 480 cm-1 493 cm-1 511 cm-1

Supporting groups

methyl aromatic amide phosphate metal_oxygen silicon_oxygen c_s s_s

Support

Evidence supporting the conclusion

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

The spectrum is dominated by strong silica/siloxane absorptions (Si-O bending at 465 cm⁻¹, Si-O-Si stretching at 1073 and 1099 cm⁻¹, and intertetrahedral Si-O-Si bending at 797 cm⁻¹), indicating a major silicate or silicon dioxide component. The presence of a broad O-H stretch at 3485 cm⁻¹ and a water bending mode at 1645 cm⁻¹ suggests adsorbed moisture or silanol groups. Additionally, weak to moderate bands at 410–493 cm⁻¹ and around 564–600 cm⁻¹ are attributable to metal-oxygen vibrations, compatible with zinc oxide. Bands at 600, 1099, 1117, 1134, 1159, and 1192 cm⁻¹ can be assigned to sulfate S-O stretching and bending modes, consistent with the library-retrieved top candidate zinc sulfate. A peak at 967 cm⁻¹ may arise from SiO₄ tetrahedra or silanol Si-OH vibrations. The overall chemical evidence suggests a silica-dominant material that incorporates zinc and sulfate species; however, the library match confidence is low, and the exact proportions and phases remain uncertain.
Direct literature evidence cites Zn-O bonds at 437, 452, and 465 cm⁻¹ in zinc oxide materials [1,4,6].
Sulfate bands are supported by literature attributions to sulfate S-O/S=O vibrations in various compounds [2, PC474].
The reference library comparison's Top-15 list shows a consensus toward silicon/oxygen materials, including silica gel, dioxosilane, and diatomite support.
The intense bands at 1073 and 1099 cm⁻¹ are characteristic of asymmetric Si-O-Si stretching modes in silica networks [PC123, PC7].
The band at 465 cm⁻¹ is attributed to Si-O bending vibrations [PC82], though a contribution from Zn-O stretching cannot be excluded.
The absorption at 797 cm⁻¹ is consistent with intertetrahedral Si-O-Si bending [PC262].
The broad O-H stretch at 3485 cm⁻¹ and the bending band at 1645 cm⁻¹ are typical of adsorbed water or silanol groups [PC257, PC79].
Low-frequency bands centered at 437, 452, and 480 cm⁻¹ are assigned to metal-oxygen vibrations, specifically Zn-O stretching as supported by direct literature [1,4,5].
The series of peaks in the 1099–1192 cm⁻¹ region alongside the band at 600 cm⁻¹ are indicative of sulfate S-O/S=O vibrations [PC474, PC477, PC478].
A peak at 967 cm⁻¹ appears in the region of SiO₄ tetrahedral stretching [PC450]; it may also reflect silanol groups or minor sulfate contributions.
Major peak assignments include 465: Related literature: siloxane / silica-like peak pattern | Direct reference: ring; ring 6m; 1099: Related literature: siloxane / silica-like peak pattern.

Limitations

Evidence that limits the conclusion

The library search returned Zinc sulfate with low confidence (0.609 similarity), and the Top-15 contains many silica-dominated entries, indicating that the spectrum is not a pure zinc sulfate reference but likely a mixed-phase or composite material.
The precise chemical form of zinc and sulfate (e.g., separate zinc oxide and sulfate salt vs. zinc sulfate compound) cannot be confirmed from these data alone.
The assignment of the 1073 cm⁻¹ band to Si-O-Si stretching relies on analogy with silica literature; direct confirmation would require reference spectra of expected compositions.
Minor organic contributions (e.g., residual C-H or ester groups) are possible but cannot be reliably ruled out in the absence of strong aliphatic C-H stretching bands.

Recommendation

Suggested next verification

Acquire reference spectra of pure zinc sulfate and zinc oxide in mixtures with silica for direct library comparison.
Perform complementary techniques such as XRF or XRD to clarify elemental composition and phase identity.
If possible, conduct thermal gravimetric analysis to assess volatile content (water/organics).

Index	Characteristic	Wavenumber	Absorbance	Evidence	One-line interpretation	Citation	Confidence
1	★	465	0.91	ادب سے تعاون یافتہ تفویض	بینڈ 465 cm-1 کو bending vibration of Si-O[36] تفویض کیا گیا ہے۔	[36]	LLM اعتماد
2	★	425	0.90	ادب سے تعاون یافتہ تفویض	بینڈ 425 cm-1 کو metal oxygen[21] تفویض کیا گیا ہے۔	[21]	LLM اعتماد
3	★	452	0.66	ادب سے تعاون یافتہ تفویض	بینڈ 452 cm-1 کو metal oxygen[39] تفویض کیا گیا ہے۔	[39]	LLM اعتماد
4	★	1099	0.56	ادب سے تعاون یافتہ تفویض	بینڈ 1099 cm-1 کو [sio4] tetrahedron[24] تفویض کیا گیا ہے۔	[24]	LLM اعتماد
5	★	1073	0.42	ادب سے تعاون یافتہ تفویض	بینڈ 1073 cm-1 کو C-O[37] تفویض کیا گیا ہے۔	[37]	LLM اعتماد
6	★	1117	0.39	ادب سے تعاون یافتہ تفویض	بینڈ 1117 cm-1 کو sulfate[26] تفویض کیا گیا ہے۔	[26]	مجموعی اعتماد
7	★	1159	0.36	ادب سے تعاون یافتہ تفویض	بینڈ 1159 cm-1 کو S-O[28] تفویض کیا گیا ہے۔	[28]	مجموعی اعتماد
8	★	1134	0.33	ادب سے تعاون یافتہ تفویض	بینڈ 1134 cm-1 کو S-O[27] تفویض کیا گیا ہے۔	[27]	مجموعی اعتماد
9	★	1192	0.30	ادب سے تعاون یافتہ تفویض	بینڈ 1192 cm-1 کو S-O[33] تفویض کیا گیا ہے۔	[33]	مجموعی اعتماد
10	★	493	0.29	ادب سے تعاون یافتہ تفویض	بینڈ 493 cm-1 کو metal oxygen[8] تفویض کیا گیا ہے۔	[8]	مجموعی اعتماد
11	★	410	0.24	ادب سے تعاون یافتہ تفویض	بینڈ 410 cm-1 کو metal oxygen[1] تفویض کیا گیا ہے۔	[1]	LLM اعتماد
12	★	3485	0.23	ادب سے تعاون یافتہ تفویض	بینڈ 3485 cm-1 کو hydroxyl / moisture O-H stretch[S4] تفویض کیا گیا ہے۔	[S4]	LLM اعتماد
13	★	967	0.13	ادب سے تعاون یافتہ تفویض	بینڈ 967 cm-1 کو sio tetrahedra[25] تفویض کیا گیا ہے۔	[25]	مجموعی اعتماد
14	★	480	0.13	ادب سے تعاون یافتہ تفویض	بینڈ 480 cm-1 کو metal oxygen[22] تفویض کیا گیا ہے۔	[22]	مجموعی اعتماد
15	★	511	0.12	ادب سے تعاون یافتہ تفویض	بینڈ 511 cm-1 کو metal oxygen[23] تفویض کیا گیا ہے۔	[23]	مجموعی اعتماد
16	★	1645	0.11	ادب سے تعاون یافتہ تفویض	بینڈ 1645 cm-1 کو bending mode of liquid h2o[29] تفویض کیا گیا ہے۔	[29]	LLM اعتماد
17	★	437	0.10	ادب سے تعاون یافتہ تفویض	بینڈ 437 cm-1 کو metal oxygen[35] تفویض کیا گیا ہے۔	[35]	LLM اعتماد
18	★	797	0.09	ادب سے تعاون یافتہ تفویض	بینڈ 797 cm-1 کو inter tetrahedral Si-O si bending[24] تفویض کیا گیا ہے۔	[24]	LLM اعتماد
19	★	564	0.05	ادب سے تعاون یافتہ تفویض	بینڈ 564 cm-1 کو metal oxygen[38] تفویض کیا گیا ہے۔	[38]	مجموعی اعتماد
20	★	600	0.05	ادب سے تعاون یافتہ تفویض	بینڈ 600 cm-1 کو sulfate[34] تفویض کیا گیا ہے۔	[34]	LLM اعتماد

Index

Characteristic

Wavenumber

Absorbance

Evidence

One-line interpretation

Citation

Confidence

★

465

0.91

ادب سے تعاون یافتہ تفویض

بینڈ 465 cm-1 کو bending vibration of Si-O[36] تفویض کیا گیا ہے۔

[36]

LLM اعتماد

★

425

0.90

ادب سے تعاون یافتہ تفویض

بینڈ 425 cm-1 کو metal oxygen[21] تفویض کیا گیا ہے۔

[21]

LLM اعتماد

★

452

0.66

ادب سے تعاون یافتہ تفویض

بینڈ 452 cm-1 کو metal oxygen[39] تفویض کیا گیا ہے۔

[39]

LLM اعتماد

★

1099

0.56

ادب سے تعاون یافتہ تفویض

بینڈ 1099 cm-1 کو [sio4] tetrahedron[24] تفویض کیا گیا ہے۔

[24]

LLM اعتماد

★

1073

0.42

ادب سے تعاون یافتہ تفویض

بینڈ 1073 cm-1 کو C-O[37] تفویض کیا گیا ہے۔

[37]

LLM اعتماد

★

1117

0.39

ادب سے تعاون یافتہ تفویض

بینڈ 1117 cm-1 کو sulfate[26] تفویض کیا گیا ہے۔

[26]

مجموعی اعتماد

★

1159

0.36

ادب سے تعاون یافتہ تفویض

بینڈ 1159 cm-1 کو S-O[28] تفویض کیا گیا ہے۔

[28]

مجموعی اعتماد

★

1134

0.33

ادب سے تعاون یافتہ تفویض

بینڈ 1134 cm-1 کو S-O[27] تفویض کیا گیا ہے۔

[27]

مجموعی اعتماد

★

1192

0.30

ادب سے تعاون یافتہ تفویض

بینڈ 1192 cm-1 کو S-O[33] تفویض کیا گیا ہے۔

[33]

مجموعی اعتماد

★

493

0.29

ادب سے تعاون یافتہ تفویض

بینڈ 493 cm-1 کو metal oxygen[8] تفویض کیا گیا ہے۔

[8]

مجموعی اعتماد

★

410

0.24

ادب سے تعاون یافتہ تفویض

بینڈ 410 cm-1 کو metal oxygen[1] تفویض کیا گیا ہے۔

[1]

LLM اعتماد

★

3485

0.23

ادب سے تعاون یافتہ تفویض

بینڈ 3485 cm-1 کو hydroxyl / moisture O-H stretch[S4] تفویض کیا گیا ہے۔

[S4]

LLM اعتماد

★

967

0.13

ادب سے تعاون یافتہ تفویض

بینڈ 967 cm-1 کو sio tetrahedra[25] تفویض کیا گیا ہے۔

[25]

مجموعی اعتماد

★

480

0.13

ادب سے تعاون یافتہ تفویض

بینڈ 480 cm-1 کو metal oxygen[22] تفویض کیا گیا ہے۔

[22]

مجموعی اعتماد

★

511

0.12

ادب سے تعاون یافتہ تفویض

بینڈ 511 cm-1 کو metal oxygen[23] تفویض کیا گیا ہے۔

[23]

مجموعی اعتماد

★

1645

0.11

ادب سے تعاون یافتہ تفویض

بینڈ 1645 cm-1 کو bending mode of liquid h2o[29] تفویض کیا گیا ہے۔

[29]

LLM اعتماد

★

437

0.10

ادب سے تعاون یافتہ تفویض

بینڈ 437 cm-1 کو metal oxygen[35] تفویض کیا گیا ہے۔

[35]

LLM اعتماد

★

797

0.09

ادب سے تعاون یافتہ تفویض

بینڈ 797 cm-1 کو inter tetrahedral Si-O si bending[24] تفویض کیا گیا ہے۔

[24]

LLM اعتماد

★

564

0.05

ادب سے تعاون یافتہ تفویض

بینڈ 564 cm-1 کو metal oxygen[38] تفویض کیا گیا ہے۔

[38]

مجموعی اعتماد

★

600

0.05

ادب سے تعاون یافتہ تفویض

بینڈ 600 cm-1 کو sulfate[34] تفویض کیا گیا ہے۔

[34]

LLM اعتماد

No.	Title	DOI	Page
[1]	Sultan 等 - 2022 - Green Synthesis and Investigation of Surface Effec	10.3390/ma15165768	-
[2]	Stamataki 等 - 2021 - Is it hot enough A multi-proxy approach shows var	10.1016/j.jas.2021.105509	-
[3]	Song 等 - 2022 - Properties of poly(lactic acid)walnut shellhydro	10.1038/s41598-022-15622-8	-
[4]	Omar 等 - 2023 - Investigation of morphological, structural and ele	10.1007/s11082-023-04663-6	-
[5]	Faraz 等 - 2019 - Enhancement of Al-N co-dopant solubility in ZnO by	10.1016/j.ceramint.2018.10.005	-
[6]	Dhayalan 等 - 2021 - Eco friendly synthesis and characterization of zin	10.1515/nanofab-2020-0104	-
[7]	Delgado-Rosero 等 - 2023 - Composite Polymer Electrolytes Based on (PEO)(4)CF	10.3390/polym15010049	-
[8]	Arunkumar 和 Alagiri - 2017 - Synthesis and Characterization of Spindle-Like TiO	10.1007/s10876-017-1245-6	-
[9]	Ariza Ortega 等 - 2012 - Analysis of trans fatty acids production and squal	10.2478/s11532-012-0104-4	-
[10]	Roy 等 - 2020 - Exploring the Inclusion Complex of a Drug (Umbelli	10.1021/acsomega.0c04716	-
[11]	Piorecka 等 - 2020 - Hydrophilic Polyhedral Oligomeric Silsesquioxane,	10.3390/ma13235512	-
[12]	Fernández 等 - 2017 -	10.17230/ingciencia.13.25.6	-
[13]	Chatchawal 等 - 2021 - Detection of Human Cholangiocarcinoma Markers in S	10.3390/cancers13205109	-
[14]	Chaparro 等 - 2023 - Biowaxes from Palm Oil as Promising Candidates for	10.3390/ma16124402	-
[15]	Chaber 等 - 2021 - A Preliminary Study of FTIR Spectroscopy as a Pote	10.3390/molecules	-
[16]	Armenta 等 - 2005 - Vibrational spectrometry strategies for quality co	10.1080/00387010500315843	-
[17]	Raghav 等 - 2017 - Nonenzymatic glycosylation of human serum albumin	10.1371/journal	-
[18]	Jradi 等 - 2015 - Contribution of TEMPO-Oxidized Cellulose Gel in th	10.3390/app5041164	-
[19]	Elashmawi 等 - 2007 - Spectroscopic and thermal investigations of poly(v	10.1002/crat.200610789	-
[20]	Ducic 等 - 2012 - Phosphorus Compartmentalization on the Cellular Le	10.1155/2012/374039	-
[21]	Singh 等 - 2013 - Structural and Optical Properties of Pr Doped BiFe	10.1063/1.4791111	-
[22]	Ayanwale 等 - 2020 - Bactericidal Activity Study of ZrO2-Ag2O Nanoparti	10.1177/1559325820941374	-
[23]	Rathore 等 - 2021 - Synthesis and characterization of chitosan-polyani	10.1016/j.molstruc.2021.130750	-
[24]	Melucci 等 - 2019 - ATR-FTIR Spectroscopy, a New Non-Destructive Appro	10.3390/molecules24213927	-
[25]	He 等 - 2011 - Morphology and Structure of Aluminum Substituted C	10.4028/www.scientific.net/amr.287-290.1193	-
[26]	Verma 和 Deb - 2007 - Direct and rapid determination of sulphate in envi	10.1016/j.talanta.2006.07.056	-
[27]	0816 ftir cm_1 peak wos/myneni 等 - 1998 - vibrational spectroscopy of functional group chemi.pdf	-	-
[28]	Chen 等 - 2021 - A Research on Durability Degradation of Mineral Ad	10.3390/ma14071752	-
[29]	Zou 和 Ma - 2014 - A New Criterion to Evaluate Water Vapor Interferen	10.3390/ijms150610018	-
[30]	Kert 等 - 2021 - Application of Fragrance Microcapsules onto Cotton	10.3390/coatings11101181	13
[31]	Arivazhagan 和 Rexalin - 2013 - Vibrational spectra, UV-vis spectral analysis and	10.1016/j.saa.2013.01.029	6
[32]	Sciutto 等 - 2017 - A Multivariate Methodological Workflow for the Ana	10.1155/2017/4938145	9
[33]	Tambara Junior 等 - 2021 - Effect of Alkaline Salts on Calcium Sulfoaluminate	10.3390/molecules26071938	8
[34]	Serefidou 等 - 2016 - Microchemical and microscopic characterization of	-	24
[35]	Kanbar 和 Kaouk - 2019 - Mineral and chemical changes of sediments after Cu	10.1016/j.chemosphere.2019.124393	40
[36]	Kastiukas 等 - 2017 - Preparation Conditions for the Synthesis of Alkali	-	17
[37]	Hernandez-Fernandez 等 - 2023 - Identifying, Quantifying, and Recovering a Sorbito	10.3390/molecules28134948	10
[38]	Lin 等 - 2020 - Enhanced Anti-Mold Property and Mechanism Descript	10.3390/nano10040682	9
[39]	Malik 等 - 2023 - Facile Synthesis of Magnetic Nigella Sativa Seeds	10.3390/pharmaceutics15020642	6

No.

Title

DOI

Page

[1]

Sultan 等 - 2022 - Green Synthesis and Investigation of Surface Effec

10.3390/ma15165768

[2]

Stamataki 等 - 2021 - Is it hot enough A multi-proxy approach shows var

10.1016/j.jas.2021.105509

[3]

Song 等 - 2022 - Properties of poly(lactic acid)walnut shellhydro

10.1038/s41598-022-15622-8

[4]

Omar 等 - 2023 - Investigation of morphological, structural and ele

10.1007/s11082-023-04663-6

[5]

Faraz 等 - 2019 - Enhancement of Al-N co-dopant solubility in ZnO by

10.1016/j.ceramint.2018.10.005

[6]

Dhayalan 等 - 2021 - Eco friendly synthesis and characterization of zin

10.1515/nanofab-2020-0104

[7]

Delgado-Rosero 等 - 2023 - Composite Polymer Electrolytes Based on (PEO)(4)CF

10.3390/polym15010049

[8]

Arunkumar 和 Alagiri - 2017 - Synthesis and Characterization of Spindle-Like TiO

10.1007/s10876-017-1245-6

[9]

Ariza Ortega 等 - 2012 - Analysis of trans fatty acids production and squal

10.2478/s11532-012-0104-4

[10]

Roy 等 - 2020 - Exploring the Inclusion Complex of a Drug (Umbelli

10.1021/acsomega.0c04716

[11]

Piorecka 等 - 2020 - Hydrophilic Polyhedral Oligomeric Silsesquioxane,

10.3390/ma13235512

[12]

Fernández 等 - 2017 -

10.17230/ingciencia.13.25.6

[13]

Chatchawal 等 - 2021 - Detection of Human Cholangiocarcinoma Markers in S

10.3390/cancers13205109

[14]

Chaparro 等 - 2023 - Biowaxes from Palm Oil as Promising Candidates for

10.3390/ma16124402

[15]

Chaber 等 - 2021 - A Preliminary Study of FTIR Spectroscopy as a Pote

10.3390/molecules

[16]

Armenta 等 - 2005 - Vibrational spectrometry strategies for quality co

10.1080/00387010500315843

[17]

Raghav 等 - 2017 - Nonenzymatic glycosylation of human serum albumin

10.1371/journal

[18]

Jradi 等 - 2015 - Contribution of TEMPO-Oxidized Cellulose Gel in th

10.3390/app5041164

[19]

Elashmawi 等 - 2007 - Spectroscopic and thermal investigations of poly(v

10.1002/crat.200610789

[20]

Ducic 等 - 2012 - Phosphorus Compartmentalization on the Cellular Le

10.1155/2012/374039

[21]

Singh 等 - 2013 - Structural and Optical Properties of Pr Doped BiFe

10.1063/1.4791111

[22]

Ayanwale 等 - 2020 - Bactericidal Activity Study of ZrO2-Ag2O Nanoparti

10.1177/1559325820941374

[23]

Rathore 等 - 2021 - Synthesis and characterization of chitosan-polyani

10.1016/j.molstruc.2021.130750

[24]

Melucci 等 - 2019 - ATR-FTIR Spectroscopy, a New Non-Destructive Appro

10.3390/molecules24213927

[25]

He 等 - 2011 - Morphology and Structure of Aluminum Substituted C

10.4028/www.scientific.net/amr.287-290.1193

[26]

Verma 和 Deb - 2007 - Direct and rapid determination of sulphate in envi

10.1016/j.talanta.2006.07.056

[27]

0816 ftir cm_1 peak wos/myneni 等 - 1998 - vibrational spectroscopy of functional group chemi.pdf

[28]

Chen 等 - 2021 - A Research on Durability Degradation of Mineral Ad

10.3390/ma14071752

[29]

Zou 和 Ma - 2014 - A New Criterion to Evaluate Water Vapor Interferen

10.3390/ijms150610018

[30]

Kert 等 - 2021 - Application of Fragrance Microcapsules onto Cotton

10.3390/coatings11101181

[31]

Arivazhagan 和 Rexalin - 2013 - Vibrational spectra, UV-vis spectral analysis and

10.1016/j.saa.2013.01.029

[32]

Sciutto 等 - 2017 - A Multivariate Methodological Workflow for the Ana

10.1155/2017/4938145

[33]

Tambara Junior 等 - 2021 - Effect of Alkaline Salts on Calcium Sulfoaluminate

10.3390/molecules26071938

[34]

Serefidou 等 - 2016 - Microchemical and microscopic characterization of

[35]

Kanbar 和 Kaouk - 2019 - Mineral and chemical changes of sediments after Cu

10.1016/j.chemosphere.2019.124393

[36]

Kastiukas 等 - 2017 - Preparation Conditions for the Synthesis of Alkali

[37]

Hernandez-Fernandez 等 - 2023 - Identifying, Quantifying, and Recovering a Sorbito

10.3390/molecules28134948

[38]

Lin 等 - 2020 - Enhanced Anti-Mold Property and Mechanism Descript

10.3390/nano10040682

[39]

Malik 等 - 2023 - Facile Synthesis of Magnetic Nigella Sativa Seeds

10.3390/pharmaceutics15020642

Silica-based material with possible zinc sulfate and/or zinc oxide components

FTIR Spectrum Analysis Report

Similarity-ranked Top-15 library comparison

Reference library candidates