ORIGINAL_ARTICLE
Creep behavior of 316 austenitic stainless steel under variant operating conditions
Creep behavior of AISI 316 austenitic stainless steel as one of the most fundamental materials utilized in high temperature operating conditions due to their good high-temperature mechanical properties in various industries such as high temperature power generation plants, gas and steam turbines, pipelines, weld joints, pressure vessels, and heat exchangers. This review attempted to cover some identifying factors on the creep behavior of the 316 stainless steel such as addition of alloying elements such as N and Cu into the matrix, presence of residual stress and pre-strain, microstructure and cold work. In addition, the creep-fatigue combination behavior of the 316 austenitic stainless steel was discussed.
https://www.ajnanomat.com/article_108093_b3ef3e44c5970a1d0a21e511d168d2f1.pdf
2020-10-01
266
279
10.26655/AJNANOMAT.2020.4.1
Creep AISI 316 stainless steel Residual stress Microstructure Creep
fatigue
Mohammad
Sajjadnejad
m.sajjadnejad@yahoo.com
1
Department of Materials Engineering, School of Engineering, Yasouj University, Yasouj, Iran
LEAD_AUTHOR
Seyyed Mohammad Saleh
Haghshenas
saleh_haghshenas@yahoo.com
2
Department of Materials Science and Engineering, School of Engineering, Shiraz University, Shiraz, Iran
AUTHOR
Mina
Tavangar
mina.tavangar1993@gmail.com
3
Department of Materials Engineering, School of Engineering, Yasouj University, Yasouj, Iran
LEAD_AUTHOR
Azin
Ghani Kolahloo
nilazin70@gmail.com
4
Department of Materials Engineering, School of Engineering, Yasouj University, Yasouj, Iran
LEAD_AUTHOR
[1]. Hossain S., Truman C.E., Smith D. J. Fatigue Fract. Eng. Mater. Struct., 2011, 34:654
1
[2]. Yan X.L., Zhang X.C., Tu S.T., Mannan S.L. Xuan F.Z., Lin Y.C., Int. J. Pres. Ves. Pip., 2015, 126:17
2
[3]. Coleman M., Miller D., Stevens R., Integrity of High-Temperature Welds, Conference, Nottingham, November, Professional Engineering Publishing Ltd., Bury St Edmunds, IP32 6BW, UK. 1998
3
[4]. Hormozi R., Biglari F., Nikbin K. Eng. Fract. Mech., 2015, 141:19
4
[5]. Sasikala G., Mannan, S.L., Mathew M.D., Bhanu Rao K. Metall. Mater. Trans., 2000, 31:1175
5
[6]. Ghosh A., Gurao N., Mater. Des., 2016, 109:186
6
[7]. Plaut R.L., Herrera C., Escriba D.M., Rios P.R., Padilha A. F. Mat. Res., 2007, 10:453
7
[8]. Viswanathan R., Damage mechanisms and life assessment of high temperature components; ASM international: 1989; p 1-440
8
[9]. Maruyama K., Baba, E., Yokokawa K. Tetsu-to-Hagane, 1994, 80:336
9
[10]. Spindler M.W., Spindler S.L. Int. J. Pres. Ves. Pip., 2008, 85:89
10
[11]. Holmström S., Auerkari P. Materials at High Temperatures, 2008, 25:103
11
[12]. Maruyama K., Armaki H.G., Yoshimi K. Int. J. Pres. Ves. Pip., 2007, 84:171
12
[13]. Srinivasan V., Valsan M., Bhanu Sankara Rao K., Mannan S.L., Raj B. Int. J. Fatigue., 2003, 25:1327
13
[14]. Hormozi R., Biglari F., Nikbin K. Int. J. Fatigue., 2015, 75:153
14
[15]. Mathew M.D., Laha K., Ganesan. V. Mater. Sci. Eng. A., 2012, 535:76
15
[16]. Ganesan V., Mathew M.D., Sankara Rao K.B. Mater. Sci. Tech-Lond, 2009, 25:614
16
[17]. Mathew M.D., Sasikala G., Bhanu Sankara Rao K., Mannan S.L. Mater. Sci. Eng. A., 1991, 148:253
17
[18]. Stoltz R., Vander Sande J. Metall. Mater. Trans., 1980, 11:1033
18
[19]. Lee H.J., Lee C.S., Chang Y.W. Metall. Mater. Trans, 2005, 36:967
19
[20]. Degallaix S., Foct S.J., Hendry A. J. Mater. Sci. Technol, 1986, 2:946
20
[21]. Müllner P., Solenthaler C., Uggowitzer P., Speidel M.O. Fundamental Aspects of Dislocation Interactions; Institute of Metallurgy, ETH Zürich (Switzerland): 1993; p 164-169
21
[22]. Mathew M.D., Kumar J.G., Ganesan V., Laha K. Metall. Mater. Trans., 2014, 45:731
22
[23]. Chi C.Y., Yu H.Y., Dong J.X., Liu W.Q., Cheng S.C., Liu Z.D., Xie Z.S. Pro. Nat. Sci-Mater., 2012, 22:175
23
[24]. Bai J.W., Liu P.P., Zhu Y.M., Li X.M., Chi C.Y., Yu H.Y., Xie X.S., Zhan Q. Mater. Sci. Eng. A, 2013, 584:57
24
[25]. Zhang Y., Wang. L., Jiang W., Bai G., Chen L. Mater. Trans., 2005, 46:2015
25
[26]. Sen I., Amankwah. E., Kumar N.S., Fleury, E., Oh-ishy K., Hono K., Ramamurty U. Mater. Sci. Eng. A, 2011, 528:4491
26
[27]. He S.M., Van Dijk N.H., Paladugu M., Schut H., Kohlbrecher J., Tichelaar F.D., Van der Zwaag S. Phys. Rev. B, 2010, 82:174111
27
[28]. Zhang S., Schut H., Bruck E., Van der Zwaag S., Van Dijk N.H. Journal of Physics: Conference Series 443, IOP Publishing, 2013
28
[29]. Zhang S., Schut H., Kohlbrecger J., Langelaan G., Bruck E., Van der Zwaag S., Van Dijk N.H. Philos. Mag, 2013, 93:4182
29
[30]. Laha K., Kyono J., Shinya N. Scr. Mater., 2007, 56:915
30
[31]. Cai B., Kang J.H., Hong C.W., Kim S.J. Mater. Sci. Eng. A, 2016, 662:198
31
[32]. Turski M., Bouchard P.J., Steuwer A., Withers P.J. Acta Mater, 2008, 56:3598
32
[33]. Bouchard P.J., Withers P.J., McDonald S.A., Heenan R.K. Acta Mater, 2004, 52:23
33
[34]. Energy B. Assessment procedure for the high temperature response of structures: British Energy Generation Limited; Document R5, 2003; Paper ID 458.
34
[35]. Holt P., Spindler M.W. A practical application of continuum damage mechanics to plant integrity assessment, Proceedings of the Symposium on Elasticity and Damage in Solids Subject to Microstructural Change, Newfoundland. 1996
35
[36]. Bradford R.A.W. Finite Element Modelling of Reheat Cracking Initiation in Austenitic Weldments, Institute of Mechanical Engineers ConferenceTransactions, International Conference on "Assuring It's Safe", 18-19 May1998, Heriot-Watt University, Edinburgh, UK, paper C535/023/98, pp 287-295
36
[37]. Spindler M. Fatigue Fract. Eng. Mater. Struct., 2004, 27:273
37
[38]. Hales R. Fatigue & Fracture of Engineering Materials & Structures, 1983, 6:121
38
[39]. Turski M., Sherry A.H., Bouchard P.J., Withers P.J. J. Neutron Res., 2004, 12:45
39
[40]. Hossain S. Residual stresses under conditions of high triaxiality, University of Bristol.
40
[41]. Skelton R.P., Goodall I.W., Webster G.A., Spindler M.W. Int. J. Pres. Ves. Pip., 2003, 80:441
41
[42]. Hossain S., Truman C.E, Smith D.J., Daymond M.R. Int. J. Mech. Sci., 2006, 48:235
42
[43]. Hossain S., Truman C.E, Smith D.J., Peng R.L, Stuhr U. Int. J. Solids Struct., 2007, 44:3004
43
[44]. Li K.S., Peng J., Key Engineering Materials, 2019, 795:152
44
[45]. Emerson R.W., Jackson R.W., Dauber C.A. Welding. J., 1962, 41:385
45
[46]. Curran R.M., Rankin A.W., Weld. J., 1955, 34:205
46
[47]. Arioka K., Yamada T., Terachi T., Chiba G. Corrosion, 2007, 63:1114
47
[48]. Kim Y.K., Youn S.J., Kim S.W., Hong J., Lee K.A. Mater. Sci. Eng. C., 2019, 763:138138
48
ORIGINAL_ARTICLE
The effect of doping graphene with silicon on the adsorption of cadmium(II): theoretical investigations
In this research, the influence of doping graphene with silicon on the adsorption of Cd2+ was investigated using the infrared (IR), natural bond orbital (NBO) and frontier molecular orbital (FMO) computations. The thermodynamic parameters including Gibbs free energy changes (ΔGad), enthalpy variations (ΔHad) and thermodynamic constant (Kth) revealed that, the Si impurity made the cadmium adsorption more spontaneous, exothermic, irreversible, and experimentally feasible. The effect of temperature and geometrical situation of silicon impurities at three ortho, meta and para conditions were also evaluated. The results indicated that, the adsorption efficiency was higher at room temperature and doping graphene with silicon at the ortho position. The NBO results demonstrated that, the cadmium interaction with both pristine and Si-doped graphenes was chemisorption, which was due to formation of the covalent bonds with Sp 3 hybridization in all of the evaluated configurations. The applicability of the pristine and Si-doped graphenes as an electrochemical sensing material for detection of the cadmium was also assessed by the FMO parameters including, bandgap, electrophilicity, and maximum transferred charge capacity. The ortho silicon doped graphene was found to be the best recognition element for the Cd(II) as the bandgap experienced the sharpest increase from 1.82 eV to 7.74 eV in the case of this adsorbent.
https://www.ajnanomat.com/article_110875_d8a23f17c2c8f9a538dad610201f6425.pdf
1999-11-30
280
290
10.26655/AJNANOMAT.2020.4.2
Cd (II)
graphene
Adsorption
Silicon
Detection
Mohammad Reza
Jalali Sarvestani
rezajalali93@yahoo.com
1
Young Researchers and Elite Club, Yadegar-e-Imam Khomeini (RAH) Shahr-e-Rey Branch, Islamic Azad University, Tehran, Iran
LEAD_AUTHOR
[1]. Pal P., Pal A. Int J Biol Macromol., 2017, 104:1548
1
[2]. Basu M., Guha A.K., Ray L. Process Saf Environ Prot., 2017, 106:11
2
[3]. Lin j., Su B., Sun M., Chen B., Chen Z. Sci Total Environ., 2018, 627:314
3
[4]. Fosso-Kankeua E., Mittal H., Waandersa F., Ray S. S. J Indust Eng Chem., 2017, 48:151
4
[5]. Kataria N., Garg V.K. Chemosphere., 2018, 208:818
5
[6]. Pyrzynska K. J Environ Chem Eng., 2019, 7:102795
6
[7]. Kaushala S., Badrua R., Singha P., Kumarb S., Mittal S.K. J Anal Chem., 2019, 74:800
7
[8]. Chen K., He J., Li Y., Cai X., Zhang K., Liu T., Hu Y., Lin D., Kong L., Liu J. J Colloid Interface Sci., 2017, 494:307
8
[9]. Bhanjana G., Dilbaghi N., Kim K.H., Kumar S. J Mol Liq., 2017, 242:966
9
[10]. Tabesh S., Davar F., Loghman-Estarki M.R. J. Alloy Compd., 2018, 730:441
10
[11]. Awual M.R., Khraisheh M., Alharthi N.H., Luqman M., Islam A., Karim M.R., Rahman M.M., Khaleque M.A. Chem Eng J., 2018, 343:118
11
[12]. Mohan C., Sharma K., Chandra S. Anal Bioanal Electrochem., 2017, 9:35
12
[13]. Rezvani Ivari S.A., Darroudi A., Arbab Zavar M.H., Zohuri G., Ashraf N. J Arab Chem., 2017, 10:S864
13
[14]. Aglan R.F., Hamed M.M., Saleh H.M. J Anal Sci Technol., 2019, 10:1
14
[15]. Bakhshi F., Farhadian N. Int J Hydrogen Energ., 2018, 43:8355
15
[16]. Farmanzadeh D., Abdollahi T. Surf Sci., 2018, 668:85
16
[17]. Özkaya S., Blaisten-Barojas E. Surf Sci., 2018, 674:1
17
[18]. Luo D., Zhang X. Int J Hydrogen Energ., 2018, 43:5668
18
[19]. Esrafili M.D., Dinparast L. J Mol Graph Model., 2018, 80:25
19
[20]. Janani K., John Thiruvadigal D. Appl Surf Sci., 2018, 449:829
20
[21]. Ahmadi R., Jalali Sarvestani M.R. Phys Chem Res., 2018, 6:639
21
[22]. Cortés-Arriagada D., Villegas-Escobar N. Appl Surf Sci., 2017, 420:446
22
[23]. Jalali Sarvestani M.R., Ahmadi R. J Water Environ. Nanotechnol., 2019, 4:48
23
[24]. Jalali Sarvestani M.R., Ahmadi R. Asian J Nanosci Mater., 2020, 3:103
24
[25]. GaussView, Version 6.1, R. Dennington, Keith T. A., Millam J. M., Semichem Inc., Shawnee Mission, KS, 2016
25
[26]. O'Boyle N.M., Tenderholt A.L., Langner K. M. J Comp Chem., 2008, 29:839
26
[27]. Gaussian 16, Revision C.01, Frisch M. J., Trucks G.W., Schlegel H.B., Scuseria G.E., Robb M.A., Cheeseman J.R., Scalmani G., Barone V.Petersson,, G.A., Nakatsuji H., Li X., Caricato M., Marenich A.V., Bloino J., Janesko B.G., Gomperts R., Mennucci B., Hratchian H.P., Ortiz J.V., Izmaylov A.F., Sonnenberg J.L., Williams-Young D., Ding F., Lipparini F., Egidi F., Goings J., Peng B., Petrone A., Henderson T., Ranasinghe D., Zakrzewski V.G., Gao J., Rega N., Zheng G., Liang W., Hada M., Ehara M., Toyota K., Fukuda R., Hasegawa J., Ishida M., Nakajima T., Honda Y., Kitao O., Nakai H., Vreven T., Throssell K., Montgomery J.A., Peralta J.E., Ogliaro F., Bearpark M.J., Heyd J.J., Brothers E.N., Kudin K.N., Staroverov V.N., Keith T.A., Kobayashi R., Normand J., Raghavachari K., Rendell A.P., Burant J.C., Iyengar S.S., Tomasi J., Cossi M., Millam J.M., Klene M., Adamo C., Cammi R., Ochterski J.W., Martin R.L., Morokuma K., Farkas O., Foresman J.B., Fox D.J., Gaussian, Inc., Wallingford CT, 2016
27
ORIGINAL_ARTICLE
Plant mediated green synthesis of lanthanum oxide (La2O3) nanoparticles: A review
Nanotechnology facilitates numerous magnificent applications due to the desired shapes and size of the nanoparticles (NPs). However, restricted study of synthesis and characterization of rare earth metal make them more fascinating to choose for further research, lanthanum oxide nanoparticles (La2O3 NPs) is an excellent choice for research due to their fabulous applications in electronics, sensors, insulators, antimicrobial agents, biomedicines, and biocatalyst. Due to countless importance of La2O3 NPs, in literature its synthesis is described by several chemical, physical methods, and there are quite a few reports exploring plants as catalyst to achieve synthesis goals. In a green synthesis of La2O3 NPs using plants, the plant extract is used as a surfactant that encompasses the biomolecule leds the bio-reduction of lanthanum salt into the La2O3 NPs. This review enlightens the synthesis, characterization, and applications of the La2O3 NPs obtained using various plant extracts.
https://www.ajnanomat.com/article_110886_a0e38ef100a6d8520daece2d57323489.pdf
2020-10-01
291
299
10.26655/AJNANOMAT.2020.4.3
Green synthesis
plant extract
Nanotechnology
La2O3 NPs
Harshal
Dabhane
hadabhane@gmdcollege.in
1
Department of Chemistry, G.M.D Arts, B.W Commerce and Science College, Sinnar, 422 103, Savitribai Phule Pune University, Maharashtra, India
AUTHOR
Suresh
Ghotekar
ghotekarsuresh7@gmail.com
2
Department of Chemistry, Sanjivani Arts, Commerce and Science College, Kopargaon 423 603, Savitribai Phule Pune University, Maharashtra, India
AUTHOR
Pawan
Tambade
pawan.tambade@gmail.com
3
Department of Chemistry, G.M.D Arts, B.W Commerce and Science College, Sinnar, 422 103, Savitribai Phule Pune University, Maharashtra, India
LEAD_AUTHOR
Vijay
Medhane
vjmedhane1664@gmail.com
4
Department of Chemistry, K.R.T. Arts, B.H. Commerce and A.M. Science College, Nashik, Savitribai Phule Pune University, Maharashtra, India
AUTHOR
[1]. Basnet P., Chanu T.I., Samanta D., Chatterjee S. Journal of Photochemistry and Photobiology B: Biology, 2018,183:201
1
[2]. Ghosh C.R., Paria S. Chemical Reviews, 2011, 112:2373
2
[3]. Daniel M.C., Astruc D. Chemical Reviews, 2004, 104:293
3
[4]. Ghotekar S. Asian J. Green Chem., 2019, 3:187
4
[5]. Nikam A., Pagar T., Ghotekar S., Pagar K., Pansambal S. Journal of Chemical Reviews, 2019, 1:154
5
[6]. Gawande M.B., Goswami A., Felpin F.X., Asefa T., Huang X., Silva R., Varma R.S. Chemical Reviews, 2016, 116:3722
6
[7]. Frewer L.J., Gupta N., George S., Fischer A.R., Giles E.L., Coles D. Trends in food science & technology, 2014, 40:211
7
[8]. Kamble D.R., Bangale S.V., Ghotekar S.K., Bamane S.R. J. Nanostruct., 2018, 8:144
8
[9]. Syedmoradi L., Daneshpour M., Alvandipour M., Gomez F.A., Hajghassem H., Omidfar K. Biosensors and Bioelectronics, 2017, 87:373
9
[10]. Ghotekar S., Pansambal S., Pagar K., Pardeshi O., Oza R. Nanochem. Res., 2018, 3:189
10
[11]. Savale A., Ghotekar S., Pansambal S., Pardeshi O. J. Bacteriol. Mycol. Open Access., 2017, 5:00148
11
[12]. Ghotekar S., Savale A., Pansambal S. J. Water Environ. Nanotechnol., 2018, 3:95
12
[13]. Pansambal S., Deshmukh K., Savale A., Ghotekar S., Pardeshi O., Jain G., Aher Y., Pore D. J. Nanostruct., 2017, 7:165
13
[14]. Bangale S., Ghotekar S. Int. J. Nano Dimens., 2019, 10:217
14
[15]. Pansambal S., Gavande S., Ghotekar S., Oza R., Deshmukh K. Int. J. Sci. Res. in Sci. and Tech., 2017, 3:1388
15
[16]. Pansambal S., Ghotekar S., Oza R., Deshmukh K. Int. J. Sci. Res. Sci. Tech., 2019, 5:122
16
[17]. Chaturvedi S., Dave P. Chemical Methodologies, 2019, 3:115
17
[18]. Hameed A., Fatima G., Malik K., Muqadas A., Fazal-ur-Rehman M. Journal of Medicinal and Chemical Sciences, 2019, 2:9
18
[19]. Fidelis G., Louis H., Tizhe T., Onoshe S. Journal of Medicinal and Chemical Sciences, 2019, 2:59
19
[20]. Fani M., Ghandehari F., Rezaee M. Journal of Medicinal and Chemical Sciences, 2018, 1:28
20
[21]. Gupta S., Lakshman M. Journal of Medicinal and Chemical Sciences, 2019, 2:51
21
[22]. Sajjadifar S., Rezayati S., Arzehgar Z., Abbaspour S., Torabi Jafroudi M. Journal of the Chinese Chemical Society, 2018, 65:960
22
[23]. Pagar T., Ghotekar S., Pagar K., Pansambal S., Oza, R. Journal of Chemical Reviews, 2019, 2:260
23
[24]. Pagar K., Ghotekar S., Pagar T., Nikam A., Pansambal S., Oza R., Sanap, D., Dabhane, H. Asian Journal of Nanosciences and Materials, 2020, 3:15
24
[25]. Ghotekar S., Pansambal S., Pawar S.P., Pagar T., Oza R., Bangale S. SN Applied Sciences, 2019, 1:1342
25
[26]. Pansambal S., Ghotekar S., Shewale S., Deshmukh K., Barde N., Bardapurkar, P. Journal of Water and Environmental Nanotechnology, 2019, 4:174
26
[27]. Ghotekar S. Nanochemistry Research, 2019, 4:163
27
[28]. Korde P., Ghotekar S., Pagar T., Pansambal S., Oza R., Mane D. Journal of Chemical Reviews, 2020, 2:157
28
[29]. Pagar T., Ghotekar S., Pansambal S., Oza R., Marasini, B.P. Journal of Chemical Reviews, 2020, 2:201
29
[30]. Ghotekar S., Dabhane H., Pansambal S., Oza R., Tambade P., Medhane, V. Advanced Journal of Chemistry-Section B, 2020, 2:102
30
[31]. Isao M. Journal of Chemical Engineering of Japan, 2005, 38:535
31
[32]. Salata O.V. Journal of Nanobiotechnology, 2004, 2:1
32
[33]. Ghidan A.Y., Al Antary T.M. Intech Open, 2019, p 1
33
[34]. Werner M., Kohly W., Simic M. Nanotechnologies in Automobiles-Innovative potentials in Hesse for the Automotive Industries and its Subcontractors, 2008, 3, p 1
34
[35]. Pathan A.A., Desai K.R., Bhasin C.P. Int. J. Nano. Chem., 2017, 3:21
35
[36]. Pathan A.A., Desai K.R., Vajapara S., Bhasin C.P. Advances in Nanoparticles, 2018, 7:28
36
[37]. Karthikeyan S., Prathima A. Utilization, and Environmental Effects, 2016, 38:3174
37
[38]. Zhou Q., Zhang H., Chang F., Li H., Pan H., Xue W., Hu D.Y., Yang S. Journal of Industrial and Engineering Chemistry, 2015, 31:385
38
[39]. Sisler J.D., Pirela S.V., Shaffer J., Mihalchik A.L., Chisholm W.P., Andrew M.E., Berry D.S., Castranova V., Demokritou P., Qian Y. Tox. Sci., 2016, 150:418
39
[40]. Balusamy B., Kandhasamy Y.G., Senthamizhan A., Chandrasekaran G., Subramanian M.S., Tirukalikundram K. Journal of Rare Earths, 2012, 30:1298
40
[41]. Naderi E., Akbarzadeh T.N., Kondori T.,Tahkor A. Eurasian Chem. Commun., 2020, 2:265
41
[42]. Jing F.J., Huang N., Liu Y.W., Zhang W., Zhao X.B., Fu R.K .Y., Wang J.B., Shao Z.Y., Chen J.Y., Leng Y.X., Liu X.Y., Chu P.K. Journal of Biomedical Materials Research Part A, 2008, 87A:1027
42
[43]. Liu J., Wang G., Lu L., Guo Y., Yang L. RSC Adv., 2017, 7:40965
43
[44]. Subhan M.A., Abul Monsur M. Fahim, Saha P.C., Rahman M.M., Begum K., Azad A.K. Nano-Structures & Nano-Objects, 2017, 10:30
44
[45]. Kunjie W., Yanping W.U., Hongxia L., Mingliang L., Deyi Z., Huixia F., Haiyan F. Journal of Rare Earths, 2013, 31:709
45
[46]. Yadav A.A., Kumbhar V.S., Patil S.J., Chodankar N.R., Lokhande C.D. Ceramics International, 2016, 42:2079
46
[47]. Ramjeyanthi N., Alagar M., Muthuraman D. International Journal of Interdisciplinary Research and Innovations, 2018, 6:389
47
[48]. Zhang Q., JI Z., Zhou J., Zhao X., Lan X. Materials Science Forum, 2012, 724:233
48
[49]. Wang G., Zhou Y., Evans D.G., Lin Y. Ind. Eng. Chem. Res., 2012, 51:14692
49
[50]. Jiawen D., Yanli W.U., Weili S., Yongiu L. Journal of Rare Earths, 2006, 24:440
50
[51]. Sheng J., Zhang S., Sa L.V., Sun W. J Mater Sci., 2007, 42:9565
51
[52]. Wang Z., Wu W., Bian X., Xue S. Advanced Materials Research, 2015, 1081:38
52
[53]. Tian Z., Huang W., Liang Y. Ceramics International, 2009, 35:661
53
[54]. Karthikeyan S., Selvapandiyan M. International Journal of Computer Science & Communication Networks, 2019, 7:70
54
[55]. Wang X., Wang M., Song H., Ding B. Materials Letters, 2006, 60:2261
55
[56]. Tang B., Ge J., Wu C., Zhuo L., Niu J., Chen Z., Shi Z., Dong Y. Nanotechnology, 2004, 15:1273
56
[57]. Salavati-Niasari M., Hosseinzadeh G., Davar F. Journal of Alloys and Compounds, 2011, 509:134
57
[58]. Todorovsky D., Todorovska R., Petrova N., Uzunova-Bujnova M., Milanova M., Anastasova S., Kashchieva E., Groudeva-Zotova S. Journal of the University of Chemical Technology and Metallurgy, 2006, 41:93
58
[59]. Pandas H.M., Fazli M. Propellants Explos. Pyrotech., 2018, 43:1
59
[60]. Abboudi M., Messali M., Kadiri N., Ali A.B., Moran E. Synthesis and Reactivity in Inorganic, Metal-Organic, and Nano-Metal Chemistry, 2011, 41:683
60
[61]. Sulaiman N., Yulizar Y., Apriandanu D.O.B. AIP Conference Proceedings, 2018, 2023:020105
61
[62]. Maheswari R.U., Yuvakkumar R., Ravi G., Hong S.I. Journal of Nanoscience and Nanotechnology, 2019, 19:4033
62
[63]. Manoj Kumar K.A., Hemananthan E., Renuka Devi P., Vignesh Kumar S., Hariharan R. Materials Today Proceedings, 2020, 21:887
63
[64]. Muthulakshmi V., Balaji M., Sundrarajan M. Journal of Rare Earths, 2020, 38:281
64
[65]. Chatterjee A., Archana L., Niroshinee V., Abraham J. Research Journal of Pharmaceutical, Biological and Chemical Sciences, 2016, 7:1461
65
[66]. Chakraborty P., Dam D., Abraham J. J. Pharm. Sci. & Res., 2016, 8:1253
66
ORIGINAL_ARTICLE
Photocatalytic degradation of industrial pigments by mil-125 derived porous Titanium Dioxide (TiO2) nanoparticles
Nowadays, metal-organic framework (MOF)-derived porous metal oxide nanoparticles (NPs) has attracted a great attention for remediation of environmental contamination. This work discussed the synthesis approach of the porous and single-phase TiO2 NPs via the thermal treatment of MIL-125 (Ti) at various temperatures. The influences of temperature on the single-phase synthesis and degree of crystallinity of this nanomaterial were investigated. It was revealed that 500 °C was the optimum temperature for the syn
https://www.ajnanomat.com/article_113301_38344a97661edfcc146c963de6b70410.pdf
1999-11-30
300
312
10.26655/AJNANOMAT.2020.4.4
metal
organic framework Titanium dioxide Optical properties Photocatalytic properties
Vahid
Sabaghi
v.sabaghi@ut.ac.ir
1
School of Chemistry, College of Science, University of Tehran, Tehran, Iran
AUTHOR
Maisam
Jalaly
maisam_jalaly@iust.ac.ir
2
Nanotechnology Department, School of Advanced Technologies, Iran University of Science & Technology (IUST), Tehran, Iran
LEAD_AUTHOR
Fatemeh
Rahsepar
frahsepar@ut.ac.ir
3
School of Chemistry, College of Science, University of Tehran, Tehran, Iran
AUTHOR
[1]. Lu G., Huang X., Li Y., Zhao G., Pang G., Wang G. J. Energy Chem., 2020, 43:8
1
[2]. Zhen H.G., Mao H., Ul-Haq I., Li S.H., Ahmad A., Zhao Z.P. Sep. Purif. Technol., 2019, 233:116042
2
[3]. Walle M.D., Zhang M., Zeng K., Li Y., Liu Y.N. Appl. Surf. Sci., 2019, 497:143773
3
[4]. Du Y., Li G., Chen M., Yang X., Ye L., Liu X., Zhao L. Chem. Eng. J., 2019, 378:122210
4
[5]. Li S., Zhang L., Liang X., Wang T., Chen X., Liu C., Li L., Wang C. Chem. Eng. J., 2019, 378:122175
5
[6]. Ma C., Li Y., Nian P., Liu
6
ORIGINAL_ARTICLE
Electrochemical determination of Vitamin B6 in fruit juices using a new nanostructure voltammetric sensor
In this study, MgO/CNTs nanocomposite was synthesized using a simple approach according to the hydrogen bonding between the oxygen atom in MgO and hydrogen atom in SWCNTs-COOH. The nanocomposite was characterized using the FESEM and EDS methods. The MgO/CNTs nanocomposite was used for amplification of the paste electrode (PE) at the presence of 1-methyl-3-buthyl imizazolonium tetrafluoroborate (MBITF) as the binder. The MgO/CNTs/MBITF/PE was used as an electroanalytical tool for electro-oxidation determination of vitamin B6 in food samples. In comparison to PE, the oxidation signal of vitamin B6 was improved up to 3.2 times at the surface of MgO/CNTs/MBITF/PE. At pH=6 as optimum condition, the MgO/CNTs/MBITF/PE revealed linear dynamic range of 0.1-400 µM for determination of vitamin B6 with the detection limit of 30.0 nM. In the final step, the MgO/CNTs/MBITF/PE showed acceptable recovery data for the determination of vitamin B6 in fruit juices samples, confirming the ability of the sensors in real sample analysis.
https://www.ajnanomat.com/article_113918_7be7837d90f9c3126fcb3c6802ccb39f.pdf
1999-11-30
313
320
10.26655/AJNANOMAT.2020.4.5
Vitamin B6
Modified electrode
MgO/CNTs nanocomposite
Sensor amplification
Farzaneh
Mehri-Talarposhti
farzanehmehri.t@gmail.com
1
Department of Food Hygiene, Ayatollah Amoli Branch, Islamic Azad University, Amol 46311-39631, Mazandaran, Iran
AUTHOR
Azade
Ghorbani-Hasan Saraei
azade380@yahoo.com
2
Department of Food Science and Technology, Ayatollah Amoli Branch, Islamic Azad University, Amol 46311-39631, Mazandaran, Iran
LEAD_AUTHOR
Leila
Golestan
golestan57@yahoo.com
3
Department of Food Hygiene, Ayatollah Amoli Branch, Islamic Azad University, Amol 46311-39631, Mazandaran, Iran
AUTHOR
Seyed-Ahmad
Shahidi
sashahidy@yahoo.com
4
Department of Food Science and Technology, Ayatollah Amoli Branch, Islamic Azad University, Amol 46311-39631, Mazandaran, Iran
AUTHOR
[1]. Metzler D.E., Ikawa M., Snell E.E. Am. Chem. Soc., 1954, 76: 648
1
[2]. Heaney R.P. Am J Clin Nutr., 2003, 78:350
2
[3]. O'neil CE., Nicklas TA., Keast DR., Fulgoni VL. Food Nutr. Res., 2014, 58:15784
3
[4]. Johansson S., Lindstedt S., Tiselius H.G. J. Biol. Chem., 1974, 249:6040
4
[5]. Hunt J.R. Nutr. Rev., 2002, 60:127
5
[6]. Drewnowski A. Front Nutr., 2019, 6:37
6
[7]. Kuchinskas E.J., Horvath A., Vigneaud V. Arch Biochem Biophys., 1957, 68:69
7
[8]. Ebbing M., Bønaa K.H., Nygård O., Arnesen E., Ueland P.M., Nordrehaug J.E. JAMA., 2009, 302:2119
8
[9]. Riggs K.M. Am J Clin Nutr., 1996, 6:3306
9
[10]. Wyatt K.M., Dimmock P.W., Jones P.W., O'Brien P.S. BMJ Clin. Res., 1999, 318:1375
10
[11]. Kashanian M., Mazinani R., Jalalmanesh S. Int. J. Gynaecol. Obstet., 2007, 96:43
11
[12]. Niebyl J.R. N. Engl. J. Med., 2010, 363:1544
12
[13]. Matthews A., Haas D.M., O'Mathúna DP., Dowswell T. Sao Paulo Med J., 2011, 129:55
13
[14]. Jacobsen D.W., Gata
14
ORIGINAL_ARTICLE
Systematically investigation for synthesis of Pt doped NiO decorated single wall carbon nanotubes and effect of synthesis nanomaterials for reduction of charge transfer reduction
In this study, we discussed the synthesis of Pt doped NiO decorated single wall carbon nanotubes nanocomposite (Pt-NiO/SWCNTs/NC) and investigated the effect of this nanocomposite on the reduction of charge transfer resistance (Rct) in electrochemical systems (solution of 1.0 mM [Fe(CN)6]3-/4-+0.1 M KCl). For this goal, we synthesized the NiO nanoparticle, NiO/SWCNTs nanocomposite and Pt/SWCNTs nanocomposite and then mo
https://www.ajnanomat.com/article_115541_61b65753340c9168f4bcab8850cd7f05.pdf
1999-11-30
321
329
10.26655/AJNANOMAT.2020.4.6
Nanocomposite
Pt doped NiO decorated single wall carbon nanotubes
Charge transfer resistance
NiO nanoparticle
Polyol
Kobra
Niazazari
azariali087@gmail.com
1
Department of Physics, Sari Branch, Islamic Azad University, Sari, Iran
AUTHOR
Ali
Pahlavan
pahlavan1292000@yahoo.com
2
Department of Physics, Sari Branch, Islamic Azad University, Sari, Iran
AUTHOR
Hassan
Karimi-Maleh
h.karimi.maleh@gmail.com
3
Department of Chemical Engineering, Quchan University of Technology, Iran
LEAD_AUTHOR
Ahmad
Ahmadi Fouladi
alitaherkhani0151@gmail.com
4
Department of Physics, Sari Branch, Islamic Azad University, Sari, Iran
AUTHOR
[1]. Malekmohammadi S., Hadadzadeh H., Farrokhpour H., Amirghofran Z. Soft Matter., 2018, 14:2400
1
[2]. Malekmohammadi S., Hadadzadeh H., Rezakhani S., Amirghofran Z. ACS Biomater. Sci. Eng., 2019, 5:4405
2
[3]. Malekmohammadi S., Hadadzadeh H., Amirghofran Z. J. Mol. Liq., 2018, 265:797-806
3
[4]. Targhoo A., Amiri A., Baghayeri M. Microchim Acta., 2018, 185:15
4
[5]. Rayati S., Malekmohammadi S. J. Exp. Nanosci., 2016, 11:872
5
[6]. Baghayeri M., Rouhi M., Lakouraj M.M., Amiri-Aref M. J. Electroanal. Chem., 2017, 784:69
6
[7]. Baghayeri M., Alinezhad H., Fayazi M., Tarahomi M., Ghanei-Motlagh R., Maleki B. Electrochim. Acta., 2019, 312:80
7
[8]. Baghayeri M., Ansari R., Nodehi M., Razavipanah I., Veisi H. Microchim. Acta, 2018, 185:320
8
[9]. Karimi F., Zakariae N., Esmaeili R., Alizadeh M., Tamadon A.M. Curr. Biochem. Eng., 2020, 20:114
9
[10]. Karimi F., Zakariae N., Esmaeili R., Alizadeh M., Tamadon A.M. Front. Chem., 2020, 8:677
10
[11]. Ma P.C., Liu M.Y., Zhang H., Wang S.Q., Wang R., Wang K., Wong Y.K., Tang B.Z., Hong S.H., Paik K.W., Kim J.K. ACS Appl. Mater. Interfaces., 2009, 1:1090
11
[12]. Arabali V., Malekmohammadi S., Karimi F. Microchem. J., 2020, 158
12
ORIGINAL_ARTICLE
Reduced graphene oxide/nanohydroxy Apatite-Bismuth nanocomposites for osteogenic differentiation of human mesenchymal stem cells
Graphene/hydroxyapatite nanocomposites (NCs) is attracted more attention in bone tissue engineering due to their osteoconductive properties. Adding different ionic substitutions to graphene/hydroxyapatite NCs may increase its osteogenic properties. In this research study, bismuth doped hydroxyapatite nano-rods (Bi-nHA) were decorated on the reduced graphene oxide (rGO) sheets. The formation and structure of the nanocomposites (rGO/Bi-nHA) was characterized using the transmission electron microscope (TEM), X-ray diffracti
https://www.ajnanomat.com/article_117900_9699299401cdaf5c184486ee1a82fce6.pdf
1999-11-30
330
339
10.26655/AJNANOMAT.2020.4.7
Seyedeh Mahsa
Khatami
mahsa.khatami@gmail.com
1
Department of Biology, Science and Research Branch, Islamic Azad University, Tehran, Iran
AUTHOR
Shadie
Hatamie
shadyhatamy@gmail.com
2
College of Medicine, National Taiwan University, 10048, Taipei, Taiwan
LEAD_AUTHOR
Alireza
Naderi Sohi
nanosohi@gmail.com
3
Stem Cell Technology Research Center, Tehran, Iran
AUTHOR
Kazem
Parivar
kazem_parivar@yahoo.com
4
Department of Biology, Science and Research Branch, Islamic Azad University, Tehran, Iran
AUTHOR
Masoud
Soleimani
soleim_m@modares.ac.ir
5
Department of Hematology, Faculty of Medical Sciences, Tarbiat Modares University, Tehran, Iran
AUTHOR
Hana
Hanaee-Ahvaz
hana5122001@yahoo.com
6
Department of Hematology, Faculty of Medical Sciences, Tarbiat Modares University, Tehran, Iran
AUTHOR
[1]. Ullah N., Ansir R., Muhammad W., Jabeen S. Asian Journal of Green Chemistry, 2020,4:340
1
[2]. Fardood ST., Forootan R., Moradnia F., Afshari Z., Ramazani A. Materials Research Express, 2020, 7:015086
2
[3]. Taghavi Fardood S., Moradnia F., Ramazani A. Nanochemistry Research, 2019, 4:86
3
[4]. Moradnia F., Fardood S.T., Ramazani A., Gupta VK. Journal of Photochemistry and Photobiology A: Chemistry, 2020, 392:112433
4
[5]. Fardood S.T., Moradnia F., Ramazani A. Micro & Nano Letters, 2019, 14:986
5
[6]. Taghavi Fardood S., Ramazani A., Azimzadeh Asiabi P., Bigdeli Fard Y., Ebadzadeha B. Asian Journal of Green Chemistry, 2017, 1:34
6
[7]. Singh P., Banik R.M. Plant Science Today, 2019, 6:583
7
[8]. Moradnia F. et al., Materials Research Express, 2019, 6:075057
8
[9]. Ajayan P.M., Schadler L.S., Braun P.V. Nanocomposite science and
9
ORIGINAL_ARTICLE
Connection of poly (Propylene imine) dendrimer to curcumin and investigation into anti-cancer effects of its products
The dendrimers are the macromolecules that branch out from the same nuclear and they finally reach the same central nucleus. The solubility of the dendrimer is strongly affected by the surface groups. These compounds are the ideal carriers for biomedical applications. One of the oldest identified dendrimer is poly (propylene imine) dendrimer (denoted as PPI dendrimer). The present study consists of two sections. In the first section, the interaction between the (PPI) dendrimer with different molar ratios of curcumin was investigated at the presence or absence of the ultrasonic waves. In the second section, the anti-cancer effects of this compound on BRC-9 cell line (of breast cancer cells) were investigated with the help of 3-(4, 5-dimethylthiazol-2-yl)-2, 5-diphenyl tetrazolium bromide (MTT) assay.
https://www.ajnanomat.com/article_117910_72d641a68df74c3580f3442536ba6961.pdf
1999-11-30
340
350
10.26655/AJNANOMAT.2020.4.8
Poly (propylene imine) dendrimer Curcumin BRC
9 Cancer cell
Keyhan
Mohammadpour
k.mohammadpouri68@gmail.com
1
Department of Chemistry, Faculty of Science, Khorramabad Branch, Islamic Azad University, Khorramabad, Iran
AUTHOR
Sabah
Salahvarzi
sabahsalahvarzi@yahoo.com
2
Department of Chemistry, Faculty of Science, Khorramabad Branch, Islamic Azad University, Khorramabad, Iran
LEAD_AUTHOR
Zeynab
Dadgar
z.dadgar67@gmail.com
3
Department of biology, Faculty of Science, Arak University, Arak, Iran
AUTHOR
[1]. Markman J.L., Rekechenetskiy A., Holler E., Ljubimova J.Y. Adv Drug Deliv Rev., 2013, 65:1866
1
[2]. Xu R., Zhang G., Mai J., Deng X., Segura-Ibarra V., Wu S., Shen J., Liu H., Hu Z., Chen L., Huang Y., Koay E., Huang Y., Liu J., Ensor J. E., Blanco E., Liu X., Ferrari M., Shen H., Nat Biotechnol., 2016, 34:414
2
[3]. Chittasupho C., Anuchapreeda S., Sarisuta N., Eur J Pharm Biopharm, 2017, 119:310
3
[4]. Manzur A., Oluwasanmi A., Moss D., Curtis A., Hoskins C. Pharmaceutics, 2017, 9:39
4
[5]. Myung J.H., Tam K.A., Park S.J., Cha A., Hong S. Wiley Interdiscip Rev Nanomed Nanobiotechnol, 2016, 8:223
5
[6]. Rosen J.E., Chan L., Shieh D.B., Gu F.X. Nanomedicine, 2012, 8:275
6
[7]. Jennifer M., Maciej W., Journal of Biomaterials and Nanobiotechnology, 2013, 4:53
7
[8]. Petros R.A., De Simone J.M. Nat Rev Drug Discov, 2010, 9:615
8
[9]. Kesharwani P., Xie L., Banerjee S., Mao G., Padhye S., Sarkar F.H., Iyer A.K., Colloids Surf B Biointerfaces, 2015, 136:413
9
[10]. Salahvarzi S., Shamaie S., ORGANIC CHEMISTRY RESEARCH., 2019, 5:202
10
[11]. Caminade A.-M., Turrin a.C.-O. Journal of Materials Chemistry B., 2014, 2:4055
11
[12]. Agrawal A., Kulkarni S., International Journal of Research and Development in Pharmacy and Life Sciences, 2015, 4:1700
12
[13]. Tsai H.C., Imae
13