Mesoporous molecular sieves, NbFAPO-5 and NbFAPSO-5 were hydrothermally synthesized with AlPO-5 type structure. Characterization of these molecular sieves was performed by X-ray diffraction to determine their structure, ICP-EAS for their elemental composition and infrared spectrometry to access their acidic properties. X-ray diffraction patterns confirmed well AlPO-5 type structure. ICP-EAS analysis confirmed the incorporation of silicon (12.9%), aluminium (15.4%), phosphorous (21.9%), iron (5.62%) and niobium (0.39%) into AlPO-5 framework. Infrared spectrometry analysis showed that both Bronsted and Lewis sites were found in the synthesized samples. The presence of both Bronsted and Lewis acid site led to bifunctional function of NbFAPO-5 and NbFAPSO-5 molecular sieve in promoting both oxidation and esterification reactions. NbFAPSO-5 Bronsted acidity was higher than that of NbFAPO-5 and for Lewis acidity, NbFAPO-5 was higher than that of NbFAPO-5.
Catalyst technology has increasingly played a key role in the economic development of countries around the word. Today, most of the chemicals, polymers, drugs, dyes and fabrics are prepared by using catalysts [
In this work, Nb was successfully introduced into FAPO-5 and FAPSO-5 type structure leading to NbFAPO-5 and NbFAPSO-5 and their acidic properties studied.
In 50 ml Erlern Mayer, a fixed amount of deionized water was added with 85% phosphoric acid and just after aluminum source was slowly added under stirring which took 20 minutes.
After adding the template (Triethylamine), the temperature was rised to 40˚C and the whole mixture was then stirred for another 30 minutes. The resulting mixture was then placed into a Teflon-line stainless steel autoclave and heated at 200˚C for 24 hours. After quenching to the room temperature, the product was washed repeatedly with deionized water, and then dried at 100˚C for 4 hours. The resulting product was calcined at 600˚C for 4 hours.
The synthesis of FeAIPO-5 follows the same procedure as described for AIPO4-5. With any priority, the iron source was added before aluminum source. The synthesis of FeAPSO-5 also follows the procedure described for FeAIPO4-5. Silicon source was added just after aluminum had form a homogenized mixture.
For the niobium solution preparation, a fixe quantity of niobium hydroxide was put in 80 g oxalic acid and 500 ml deionized water under stirring, and the temperature was rised to 70˚C - 80˚C. After a period of time, a clear solution of niobium complexed in oxacilic acid was obtained.
Synthesis of NbFeAPO-5 and NbFeAPSO-5 follows the same procedure as described for FeAPO-5 and Fe- APSO-5 except that niobium solution was added just after putting aluminum source for NbFeAPO-5 and silicon source for NbFeAPSO-5.
The raw materials for different synthesized catalysts are found in
X-ray powder diffraction data were obtained on a Rigaku D/max diffractometer using Cu ka radiation at 40 kv and 60 Ma. Elemental composition of different catalysts was accessed using ICP-AES performed on IRIS 1000 and the acidity by mean of infrared spectrometry performed on Nicolet Magna-IR 550.
Samples with iron content of 2.02 g (
Because the amount of iron incorporated is rather low, therefore changes in XRD patterns are not observed. Access inside the behavior of the iron incorporating AFI framework, using energy minimization technique [
Raw materials | Specifications | Molecular formula | Molecular weight (g/mol) | Purity | Vendor |
---|---|---|---|---|---|
Phosphoric acid | AR 500 ml | H3PO4 | 98.0 | 85.0% | Guanzhou Rikewei Chemical Co., Ltd |
Boehmite | Al2O3・2H2O | 138.0 | 95% | Zibo Yinghe Chemicals Co., Ltd | |
Triethylamine | AR 500 ml | (C2H5)3N | 101.19 | ≥99.0% | Shanghai Ruizheng Chemicals. Co., Ltd |
Niobium hydroxide | AR 500 g | Nb(OH)5 | 177.94 | 99.9% | Guanzhou Non-Ferrous Metals Co., Ltd |
Ferric nitrate | AR 500 g | Fe(NO3)3・9H2O | 404.00 | 98.5% | Xiamen Ditai Chemicals Co., Ltd |
Ethyl orthosilicate | AR 500 ml | (C2H5O)4Si | 208.33 | 40.45% | Qingdao Huatuo Chemicals Co., Ltd |
strong distortion around the Fe atom. According to this study, Fe (III) in tetrahedral sites destabilizes, but does not disrupt the structure. Fe incorporation increases the T-O distance, resulting in strong distortion of the frame- work. This is due to the fact that Fe-O distance is approximately larger than the Al-O one, and also owing to differences in tetrahedral atoms (Al, Fe)-Oxygen distances, the cell parameters will vary.
High silicon content in NbFAPSO-5 molecular sieve result in the disturbance of XRD patterns. In this study, 1 ml to 3 ml was successfully introduced into FAPO-5 molecular sieve without resulting in XRD patterns disturbance as shown in
Adding silicon into FAPO-5 resulted in the increase of acidic properties of these materials, by the formation of SiO2-Al2O3 oxides, which also increase the stability of this molecular sieve. Elemental analysis using ICP- AES technique shows that silicon content up to 12.9% was successfully incorporated into our prepared samples, maintaining AFI type structure. A fundamental question that arises regarding the substitution of silicon into the AIPO-5 structural framework is the location of this substituted ion. Silicon theoretically can substitute for aluminum or phosphorous, or both. If the silicon substitutes for aluminum, the charged on the framework will be positive, giving rise to anion exchange properties; substitution for phosphorous will result in anionic framework
similar to the zeolite molecular sieve; no net change in the framework will be observed if both aluminum and phosphorous are simultaneously substituted with two silicon atoms. The ability to exchange cations as well as observed acid activity in SAPO-5 materials indicates that the silicon does, indeed, substitute for phosphorous. SAPO-5 (AFI) has mole fraction for SixAIyPz with x + y greater than z, which is evidence for substitution of two silicon atoms for (AI + P) in addition to substitution of silicon for phosphorous.
Two sources of niobium were tested, niobium pentaoxide and niobium hydroxide. The first resulted in low solubility; niobium hydroxide complexed easily in oxalic acid as described in experimental section. The XRD patterns of NbFAPO-5 are shown in
The synthesis of NbFAPO-5 and NbFAPSO-5 exhibits many similarities to that of aluminosilicate molecular sieves. All are synthesized from reactive gels under the pH of 4 to 7, with the presence of organic additives helping
to promote crystallization of a specific phase.
Temperature plays an important role in the crystallization of these synthesized samples. At lower temperature (100˚C - 125˚C) AFI type structure was not obtained; this structure occurred only for temperature ranging from 150˚C to 200˚C. At higher crystallization temperature (200˚C), other non-zeolitic phases are observed to crystalllize with increased crystallization time. The optimum time needed to promote crystallization of these phases appears to be dependent on both the temperature and the nature of the organic species used in the reaction mixture.
The organic additives appear to promote crystallization of a specific aluminophosphates structure, although it is unclear if it is in the same way that the organic additive promotes crystallization of a specific structure in the synthesis of the aluminosilicates. Many organic amines have been claimed to promote the crystallization of the AIPO4-5 structure; but there appears to be little correlation among them. A wider range of neutral organic amines have been found to aid in crystallization of aluminophosphates structures, compared to the aluminosilicate system; however, this may be a result of the initially acidic environment of the aluminophosphates gel, which would encourage the formation of a protonated amine, thus generating the cationic form in situ. The preparation of several structures from a given organic amine is a result of changing other synthesis conditions.
Infrared spectra of different synthesized samples show three distinct regions. Peaks at 1450 and 1540 cm−1 are assigned to Lewis and Brönsted acid sites respectively. According to Fateley [
The infrared spectrum of FAPO-5 molecular sieve is shown in
From
After incorporation of Nb into FAPO-5 molecular sieve, NbFAPO-5 sample is obtained. The resulting infra- red spectrum of pyridine chemisorption is shown in
From
Infrared spectra of FAPSO-5 are shown in
Incorporation of Nb into FAPSO-5, leading to NbFAPSO-5 molecular sieve, infrared spectrum is shown in
Adsorption of probe molecule behaves in the same manner as in FAPSO-5. Brönsted and Lewis acidity of different synthesized samples are shown in
From
Acidity Catalysts | TL | TB | SL | SB | WL | WB |
---|---|---|---|---|---|---|
NbFAPO-5 | 36.33 | 26.33 | 0 | 0 | 36.33 | 26.334 |
FAPO-5 | 15.77 | 0 | 6.266 | 0 | 0 | 0 |
NbFAPSO-5 | 28.646 | 28.809 | 0 | 0 | 9.512 | 28.809 |
FAPSO-5 | 33.533 | 84.645 | 31.44 | 0 | 0 | 84.645 |
TL = total Lewis acid, TB = total Brönsted acid, SL = strong Lewis acid, SB = strong Brönsted acid, WL = weak Lewis acid, WB = weak Brönsted acid.
meaning furthermore his presence in FAPO-5 framework. Incorporation in FAPSO-5 leads to a decrease in acidity, where Brönsted and Lewis acid are nearly at equilibrium. This behavior is of great importance for this molecular sieve which should promote both oxidation and esterification reactions. The presence of only weak Brönsted acidity can be attributed to structural defects leading to terminal P-OH and Al-OH. The occurrence of weak and strong Lewis sites on this solid supports the idea of structural breakage after calcinations to yield defective Al sites. The incorporation of silicon in FAPO-5 catalyst generates a relatively high proportion of Brönsted acid sites.
Using triethylamine as template, boemite as aluminium source, phosphoric acid as phosphorous source, ferricni- trate as iron source, orthosilicate as silicate source, niobium hydroxide as niobium source, it was possible to hydrothermally synthesize AlPO-5, FAPO-5, NbFAPO-5 and NbFAPSO-5 molecular sieve with AFI type structure. Both Lewis and Brönsted acidity were found in the synthesized samples. Incorporation of niobium into FAPSO-5 framework should be done carefully because high content will lower the acidity, and also diminish the molecular sieve crystallinity.
Special thanks are due to Mr. Toumbe Mama and Dr. Mbowou Isaack for their technical assistance to accomplish this work.
Mominou Nchare,Lei Wang,Salomon Anagho, (2016) Synthesis of NbFAPO-5 and NbFAPSO-5 Molecular Sieve by Hydrothermal Method and Comparison of Their XRD Patterns and Their Acidic Properties Evaluation by Infrared Spectroscopy. Open Journal of Inorganic Chemistry,06,155-162. doi: 10.4236/ojic.2016.63011