| Literature DB >> 29140287 |
Nguyễn Hoàng Ly1, Thanh Danh Nguyen2,3, Kyung-Duk Zoh4, Sang-Woo Joo5,6.
Abstract
A surface-enhanced Raman scattering (SERS) detection method forEntities:
Keywords: cyanide removal; diethyldithiocarbamate; industrial electroplating wastewater; plasmonic gold nanoparticles; surface-enhanced Raman spectroscopy
Year: 2017 PMID: 29140287 PMCID: PMC5713075 DOI: 10.3390/s17112628
Source DB: PubMed Journal: Sensors (Basel) ISSN: 1424-8220 Impact factor: 3.576
Scheme 1Schematic diagram of detection of Cu2+ ions with (a) a complex of DDTC and subsequent adsorption on AuNPs and (b) in electroplating wastewater after alkaline chlorination under the interference from the other ionic species.
Figure 1(a) Photo of DDTC and DDTC-metal complexes for NH4+, K+, Ca2+, Mg2+, Cd2+, Pb2+, Hg2+, Zn2+, Co2+, Cr3+, Ni2+, Fe2+, Fe3+, Cu2+, and Mn2+ ions. (b) UV-Vis absorption spectra of DDTC-metal complexes. The inset shows the absorption bands at ~450 nm and the photo of DDTC-Cu2+ complex corresponding to various concentrations of the Cu2+ ion. (c) UV-Vis absorption spectra of AuNPs and DDTC-metal complexes on AuNPs. The inset shows the TEM image of the AuNPs-DDTC-Cu2+ complex. The scale bar is 100 nm. (d) High-resolution image of AuNPs with a scale bar of 5 nm. Photo of AuNPs and DDTC-metal complexes on AuNPs.
Spectral data and vibrational assignments for DDTC and DDTC-Cu2+ on Au.
| NR of DDTC | a DFT DDTC-Au6 | SERS on Au | a DFT Cu(DDTC)2-Au6 | SERS on Au | b Assignments Based on PED Calculations |
|---|---|---|---|---|---|
| --- | --- | --- | 268 | 268 | β(C–N–C) + β(N–C–S) |
| 350 | 329 | --- | 345 | 367 | ν(Cu–S) + β(S–C–S) |
| 426 | 415 | 435 | 407 | 434 | β(C–C–N) + ν(S–C) + γ(N–S–S–C) |
| 567 | 523 | 552 | 523 | 547 | ν(S–C) + γ(N–S–S–C) + β(C–N–C) |
| 775 | 756 | --- | 756 | --- | ν(N=C)(CH2) |
| 835 | 849 | --- | 841 | --- | δ(H–C–C–N) |
| 910 | 935 | 902 | 942 | 885 | ν(C–C) |
| 1003 | 997 | 1005 | 997 | 998 | ν(N=C)(CH2) + ν(S–C) + ν(C–C) |
| 1074 | 1051 | 1080 | 1043 | 1075 | ν(N=C)(CH2) + ν(C–C) |
| 1131 | 1144 | 1144 | 1152 | 1147 | δ(H–C–C–N) |
| 1261 | 1292 | 1270 | 1276 | 1270 | ν(N=C)(CS2) + δ(H–C–N–C) + β(H–C–C) |
| 1367 | 1354 | 1350 | 1354 | 1366 | δ(H–C–N–C) + β(H–C–H)(CH2) |
| 1412 | 1416 | 1423 | 1447 | 1432 | ν(N=C)(CS2) + β(H–C–H)(CH2) |
| 1449 | 1462 | 1454 | 1470 | 1454 | β(H–C–H)(CH2) + β(H–C–H)(CH3) |
| 1474 | 1493 | 1490 | 1517 | 1504 | ν(N=C)(CS2) + β(H–C–H)(CH2) |
a The scale factor of 0.97 was applied. b Abbreviations: δ: Torsion, ν: stretching, β: in-plane bending, γ: out-of-plane bending.
Figure 2(a) Normal Raman (NR) for the solid state of DDTC and SERS spectra of DDTC, DDTC-Zn2+, and DDTC-Cu2+ on AuNPs. In the case of the DDTC-Cu2+ complex, the vibrational band at ~1490 cm−1 was prominently blueshifted to ~1504 cm−1, as marked in red arrows. (b) The SERS spectra of DDTC-metal complexes on AuNPs for Cu2+, Zn2+, Pb2+, Ni2+, NH4+, Na+, Mn2+, Mg2+, K+, Hg2+, Fe2+, Fe3+, Cr3+, Co2+, Cd2+, and Ca2+.
Figure 3(a) Cu2+ concentration-dependent SERS spectra of DDTC on AuNPs in distilled water. (b) A magnified view of the spectral region from 1380 to 1600 cm−1. (c) Three independent measurements of Raman intensities of vibrational bands at ~1504 cm−1 were performed to provide the standard deviations and a linear fit for the concentration range between 1 and 60 μM.
Atomic percentages of various metal ionic species in electroplating wastewater samples.
| Sample | Cr | Mn | Fe | Ni | Cu | Zn |
|---|---|---|---|---|---|---|
| “S1” (cyanide wastewater) | ND * | ND | 342.95 | 703.85 | 84.69 | 2447.67 |
| “S2” (after alkaline chlorination) | ND | 2.38 | 468.28 | 667.66 | 77.06 | 2175.26 |
* ND: not detected.
Figure 4(a) Initial photo of the industrial wastewater samples: [CN] = 100 ppm, “S1” (cyanide-containing), and “S2” (after alkaline chlorination). Photo of wastewater samples after dilution and treatment with DDTC. (b) UV-Vis absorption spectra of [CN], “S1”, and “S2” after treatment with DDTC. (c) SERS spectra of [CN], “S1”, and “S2” on AuNPs after treatment with DDTC. (d) A magnified view of the C≡N triple bond stretching region at ~2114 cm−1.
Figure 5(a) UV-Vis absorption spectra of the DDTC-Cu2+ complex in wastewater with bands at ~450 nm, depending on the concentrations of the Cu2+ ion. The inset shows a photo of the DDTC-Cu2+ complex with [Cu2+] from 0 to 50 ppm in wastewater. (b) Cu2+ concentration-dependent SERS spectra of DDTC on AuNPs in wastewater samples after alkaline chlorination treatment. (c) A magnified view of the region from 1400 to 1550 cm−1. (d) Three independent measurements of Raman intensities at vibrational bands of ~1504 cm−1 were performed to provide the standard deviations and a linear fit for the concentration range between 1 and 50 ppm. The samples for the calibration curve were obtained by dilution of the initial wastewater (77.06 ppm Cu2+) with the DDTC-Cu2+ complex and the AuNP solution. The samples with the other Cu2+ concentrations could also made by changing the volumes of wastewater and DDTC-Cu2+ complex, accordingly.
Figure 6An alkaline chlorination process of the influent sample “S1” to remove the cyanide species in electroplating industrial wastewater to produce the non-cyanide wastewater in sample “S2”.