| Literature DB >> 30127316 |
Qin Zhang1, Muhan Chen2, Lijiang Zhong3, Qun Ye4, Shaoshong Jiang5, Zhangjie Huang6.
Abstract
In this study, quaternary-ammonium-functionEntities:
Keywords: metal cyanide complexes; metal-organic framework; palladium cyanide recovery; removal
Mesh:
Substances:
Year: 2018 PMID: 30127316 PMCID: PMC6222324 DOI: 10.3390/molecules23082086
Source DB: PubMed Journal: Molecules ISSN: 1420-3049 Impact factor: 4.411
Figure 1FT-IR spectra of (a) Cu(BDC-NH2)(DMF), (b) Et-N-Cu(BDC-NH2) (DMF) and (c) Et-N-Cu(BDC-NH2)(DMF)-Pd(CN)42−.
Figure 2XRD patterns of (a) Cu(BDC)(DMF), (b) Cu(BDC-NH2)(DMF) and (c) Et-N-Cu(BDC-NH2)(DMF).
Figure 3The SEM images of Cu(BDC-NH2)(DMF) (a,a) and Et-N-Cu(BDC-NH2) (DMF) (b,b).
Figure 4TG-DTG curves of Et-N-Cu(BDC-NH2)(DMF)(red) and Cu(BDC-NH2)(DMF)(black).
Figure 5(a) Nitrogen adsorption–desorption isotherm of the prepared Cu(BDC-NH2)(DMF) and Et-N-Cu(BDC-NH2) (DMF) samples. (b) Pore size distributions derived from NLDFT calculations.
Comparison of surface areas and total pore volums of Et-N-Cu(BDC-NH2)(DMF) and Cu(BDC-NH2)(DMF) with other Cu-MOFs reported in literature studies.
| Sample | Surface Area of BET (m2 g−1) | Total Pore Volume (cm3 g−1) | Ref. |
|---|---|---|---|
| Cu-BTC | 692–2211 | ~0.81 | [ |
| Cu(BDC)(DMF) | 241–903 | ~0.30 | [ |
| Cu(BDC-NH2)(4,4’-Bipy)0.5 | 124 | - | [ |
| Cu(BDC-NH2)(DMF) | 210.6 | 0.37 | present work |
| Et- | 108.24 | 0.30 | present work |
The maximum adsorption capacities for the metal cyanide complexes.
| Metal Cyanide Complexes | qmax, Et- | qmax, Cu(BDC-NH2) (DMF) | qmax, GAC |
|---|---|---|---|
| Pd(II) | 172.9 | 37.8 | 18.2 |
| Co(III) | 101.0 | 13.9 | 18.1 |
| Fe(III) | 102.6 | 20.6 | 20.7 |
Kinetic parameters of Pd(II) adsorption onto the Et-N-Cu(BDC-NH2)(DMF) adsorbents.
| Pseudo-First-Order Model | Pseudo-Second-Order Model | Intra-Particle Diffusion Model | |||
|---|---|---|---|---|---|
| qe, exp. (mg g−1) | 124.4 | qe, exp. (mg g−1) | 124.4 | Kp (mg g−1 min−0.5) | 6.628 |
| qe, cal. (mg g−1) | 38.58 | qe, cal. (mg g−1) | 128.4 | C | 91.72 |
| k1 (min−1) | 0.17 | k2 (g mg−1 min−1) | 0.008 | R2 | 0.7705 |
| R2 | 0.9647 | R2 | 0.9991 | ||
Figure 6(a) Pseudo-first-order, (b) pseudo-second-order and (c) intra-particle diffusion model at 298 K.
Langmuir and Freundlich isotherm parameters of Et-N-Cu(BDC-NH2)(DMF).
| Metal | qma (mg g−1) | Langmuir Isotherm | Freundlich Isotherm | ||||
|---|---|---|---|---|---|---|---|
| qmb (mg g−1) | B (L mg−1) | R2 | Kf (L g−1) | n | R2 | ||
| Pd | 172.9 | 180.5 | 0.213 | 0.9995 | 44.98 | 3.16 | 0.9496 |
a Experimental data. b Calculated value according to Langmuir isotherm model.
Figure 7(a) Langmuir and (b) Freundlich isotherm models.
Figure 8Van’t Hoff plot for the investigated adsorbents.
Thermodynamic parameters for the absorption of Pd(CN)42−.
| Temperature (K) | △G (kJ mol−1) | △S (J mol−1 K−1) | △H (kJ mol−1) |
|---|---|---|---|
| 293.15 | −4.48 | −239.4 | −74.7 |
| 298.15 | −3.29 | ||
| 303.15 | −2.09 | ||
| 308.15 | −0.89 |
Adsorption and separation of metal cyanide complexes from mixed solution.
| Metal Cyanide Complexes | Pd(CN)42− | Co(CN)63− | Fe(CN)63− |
|---|---|---|---|
| Initial concentration (mg L−1) | 50.1 | 25.3 | 25.4 |
| Adsorption rate (%) | 99.1 | 98.7 | 98.3 |
| The first elution rate (%) | 1.9 | 98.2 | 98.8 |
| The second elution rate (%) | 97.2 | ||
| Recovery rate (%) | 96.3 |
Figure 9(a) The XRD patterns of Et-N-Cu(BDC-NH2)(DMF) (6d) at different pH values, compared with the prepared one (Room temperature). pH = 7.0 (24 h), pH = 7.5 (24 h), pH = 8.0 (24 h), pH = 9.0 (2 h), pH = 9.5 (1 h), 5 cycles (pH = 7.0), 1 mol L−1 NaOH (1 h). (b) The photographs show adsorption and releasing metal cyanide complexes using Et-N-Cu(BDC-NH2)(DMF) adsorbent.
Figure 10The recovery rates for Pd(CN)42− in the mixed solution for five cycles.
Comparison of the maximum adsorption capacity, adsorption time, and adsorption selectivity for Pd(CN)42− with polymer resins and activated carbon.
| Adsorbent | Capacity (mg g−1) | Adsorption Time (h) | Optimum pH | Adsorption Selectivity | Refs. |
|---|---|---|---|---|---|
| Polymer resins | <80 | 8–48 h | 9–11 | Pd(CN)42− coexisting with other metal cyanide | [ |
| Activated carbon | 8–25 | 2–12 h | 9–11 | Pd(CN)42− coexisting with other metal cyanide | [ |
| Et- | >100 | <0.5 | 7–8 | Pd(CN)42− can eluted separation from other metal cyanide | Present work |
Scheme 1Synthesis of Et-N-Cu(BDC-NH2) (DMF) adsorbents.
Figure 11Quaternization reaction from Cu(BDC-NH2)(DMF) to Et-N-Cu (BDC-NH2) (DMF).
The reaction yield from Cu(BDC-NH2)(DMF) to Et-N-Cu(BDC-NH2)(DMF).
| Samples | Iodine Content (w%) | Reaction 7ield (%) |
|---|---|---|
| Et- | 3.5 | ~14 |
| Et- | 6.3 | ~26 |
| Et- | 7.8 | ~32 |