The Significant Properties of Silicate Based Luminescent Nanomaterials in Various Fields of Applications: A Review

S. Sharma¹ , S.K. Dubey²

Section:Review Paper, Product Type: Journal-Paper
Vol.9 , Issue.4 , pp.37-41, Aug-2021

Online published on Aug 31, 2021

Copyright © S. Sharma, S.K. Dubey . This is an open access article distributed under the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.
 

View this paper at   Google Scholar | DPI Digital Library

XML View     PDF Download

How to Cite this Paper

Abstract :
Silicate-based luminescent nanomaterials have various applications such as biomaterials, biomedical, public health, tissue engineering, bone materials, plasma display panels (PDPs) and drug delivery, orthopedic as well as dental implants. Their remarkable scope in scientific research performs significant role in useful optical modules to fulfill the demands of our societies, arise marketing and lighten industries that have inspired by the green nature of environment. It helps in forming a balanced industrial framework that increases potentiality, makes better use of natural nanomaterial resources, and also keeps our atmosphere green. The primary goal of this review paper is to provide updates on silicate-based luminescent nanomaterial applications, also to discuss the benefits, unique properties and their future research scopes.

Key-Words / Index Term :
Biomaterials, Tissue engineering, Bone materials, Plasma display panels (PDPs).

References :
[1]. V.B. Bhatkar, N.V. Bhatkar, “Combustion Synthesis and Photoluminescence Study of Silicate Biomaterials”, Bulletin of Materials Science, Vol. 34, Issue.6, pp. 1281–1284, 2011.
[2]. M. Cerruti & N. Sahai, “Silicate Biomaterials for Orthopaedic and Dental Implants”, Reviews in Mineralogy and Geochemistry, Vol. 64, Issue.1, pp. 283-313, 2006.
[3]. A.S. Hoffman, “Stimuli-Responsive Polymers: Biomedical Applications and Challenges for Clinical Translation”, Advanced Drug Delivery Reviews, Vol. 65, Issue.1, pp. 10-16, 2013.
[4]. L. Radev, V. Hristov, I. Michailova & B. Samuneva, “Sol-Gel Bioactive Glass-Ceramics Part II: Glass-Ceramics in the CaO-SiO2-P2O5-MgO System”, Central European Journal of Chemistry, Vol. 7, Issue.3, pp. 322-327, 2009.
[5]. J. Ou, Y. Kang, Z. Huang, X. Chen, J. Wu, R. Xiao & G. Yin,. “Preparation and In Vitro Bioactivity of Novel Merwinite Ceramic”, Biomedical Materials, Vol. 3, Issue.1, pp. 015015, 2008.
[6]. N.Y. Iwata, G.H.Lee, Y. Tokuoka & N. Kawashima, “Sintering Behavior and Apatite Formation of Diopside Prepared by Coprecipitation Process”, Colloids and Surfaces B: Biointerfaces, Vol. 34, Issue. 4, pp. 239-245, 2004.
[7]. C. Wu, J. Chang, “Degradation, Bioactivity, and Cytocompatibility of Diopside, Akermanite, And Bredigite Ceramics”, Journal of Biomedical Materials Research Part B: Applied Biomaterials: An Official Journal of the Society for Biomaterials, The Japanese Society for Biomaterials, and The Australian Society for Biomaterials and The Korean Society for Biomaterials, Vol. 83, Issue. 1, pp. 153-160, 2007.
[8]. M. Cerruti & N. Sahai, “Silicate Biomaterials for Orthopaedic and Dental Implants”, Reviews in Mineralogy and Geochemistry, Vol. 64, Issue.1, pp. 283-313, 2006.
[9]. A. Dora, C. Hernández, A. Luis, B. Aragón, W.O. Lara, D. Zamarrón Rentería & Y. Salinas-Delgado, Bioceramics, Vol. 21, pp. 527, 2008.
[10]. C. Wu, J. Chang, “A Novel Akermanite Bioceramic: Preparation and Characteristics”, Journal of Biomaterials Applications, Vol. 21, Issue. 2, pp. 119-129, 2006.
[11]. S. Hongli, W. Chengtie, D. Kerong, C. Jiang & T. Tingting, “Proliferation and Osteoblastic Differentiatioan of Human Bone Marrow-Derived Stromal Cells On Akermanite-Bioactive Ceramics”, Biomaterials, Vol. 27, pp. 5651-5657, 2006.
[12]. Q. Liu, L. Cen, S. Yin, L. Chen, G. Liu, J. Chang & L. Cui, “A Comparative Study of Proliferation and Osteogenic Differentiation of Adipose-Derived Stem Cells On Akermanite and ?-TCP Ceramics”, Biomaterials, Vol. 29, Issue. 36, pp. 4792-4799, 2008.
[13]. D. Yan, G. Zhou, X. Zhou, W. Liu, W.J. Zhang, X. Luo & Y. Cao, “The Impact of Low Levels of Collagen IX and Pyridinoline On the Mechanical Properties of In Vitro Engineered Cartilage”. Biomaterials, Vol. 30, Issue. 5, pp. 814-821, 2009.
[14]. M.N. Rahaman, D.E. Day, B.S. Bal, Q. Fu, S.B. Jung, L.F. Bonewald & A.P. Tomsia, “Bioactive Glass in Tissue Engineering”, Acta Biomaterialia, Vol. 7, Issue.6, pp. 2355-2373, 2011.
[15]. Online available from, https://www.stoodnt.com/blog/tissue-engineering-applications-scopes/
[16]. Cuy, J. Natural Polymers. (2004) University of Washington Engineered Biomaterials. https://www.uweb.engr.washington.
[17]. C. Wu, J. Chang, “Degradation, Bioactivity, And Cytocompatibility Of Diopside, Akermanite, And Bredigite Ceramics”, Journal of Biomedical Materials Research Part B: Applied Biomaterials: An Official Journal of the Society for Biomaterials, The Japanese Society for Biomaterials, and The Australian Society for Biomaterials and The Korean Society for Biomaterials, Vol. 83, Issue.1, pp. 153-160, 2007.
[18]. G.J. Talwar, C.P. Joshi, S.V. Moharil, S.M. Dhopte, P.L. Muthal & V.K. Kondawar, “Combustion Synthesis of Sr3MgSi2O8: Eu2+ and Sr2MgSi2O7: Eu2+ Phosphors”, Journal of Luminescence, Vol. 129, Issue.11, pp.1239-1241, 2009.
[19]. V.B. Bhatkar, N.V. Bhatkar, “Combustion Synthesis and Photoluminescence Characteristics of Akermanite: A Novel Biomaterial”, International Journal Advances Engineering Science and Technology, Issue. 5, pp. 184-186, 2011.
[20]. J.M.G. Ventura, D.U. Tulyaganov, S. Agathopoulos & J.M.F. Ferreira, “Sintering and Crystallization of Akermanite-Based Glass–Ceramics”, Materials Letters, Vol. 60, Issue. 12, pp. 1488-1491, 2006.
[21]. C. Wu, J. Chang, “Synthesis and Apatite-Formation Ability of Akermanite”, Materials Letters, Vol. 58, Issue. 19, pp. 2415-2417, 2004.
[22]. C. Wu, M. Zhang, D. Zhai, J. Yu, Y. Liu, H. Zhu & J. Chang, “Containerless Processing for Preparation of Akermanite Bioceramic Spheres With Homogeneous Structure, Tailored Bioactivity and Degradation”, Journal of Materials Chemistry B, Vol. 1, Issue. 7, pp. 1019-1026, 2013.
[23]. C. Wu, J. Chang, “A Novel Akermanite Bioceramic: Preparation and Characteristics”, Journal of Biomaterials Applications, Vol. 21, Issue. 2, pp. 119-129, 2006.
[24]. Vinicius Ribas De Morais, “Preparation Of Dy3+ Doped Calcium Magnesium Silicate Phosphors by a New Synthesis Method and Its Luminescence Characterization”, In the Proceedings of the 2018, 7th International Congress On Ceramics & 62th Congress Brasileiro De Ceramica, Foz Do Iguacu- Pr Brazil June 17-21, 2018.
[25]. C. Wu, J. Chang, S. Ni & J. Wang, “In Vitro Bioactivity of Akermanite Ceramics”, Journal of Biomedical Materials Research Part A: An Official Journal of the Society for Biomaterials, The Japanese Society for Biomaterials, and The Australian Society for Biomaterials and The Korean Society for Biomaterials, Vol. 76, Issue. 1, pp. 73-80, 2006.
[26]. X. Hou, G. Yin, X. Chen, X. Liao, Y. Yao & Z. Huang, “Effect of Akermanite Morphology On Precipitation of Bone-Like Apatite”, Applied Surface Science, Vol. 257, Issue. 8, pp. 3417-3422, 2011.
[27]. Q. Liu, L. Cen, S. Yin, L. Chen, G. Liu, J. Chang & L. Cui, “A Comparative Study of Proliferation and Osteogenic Differentiation of Adipose-Derived Stem Cells On Akermanite and ?-TCP Ceramics”, Biomaterials, Vol. 29, Issue.36, pp. 4792-4799, 2008.
[28]. H. Sun, C. Wu, K. Dai, J. Chang & T. Tang, “Proliferation and Osteoblastic Differentiation of Human Bone Marrow-Derived Stromal Cells On Akermanite-Bioactive Ceramics”. Biomaterials, Vol. 27, Issue. 33, pp. 5651-5657, 2006.
[29]. Y. Huang, X. Jin, X. Zhang, H. Sun, J. Tu, T. Tang & K. Dai, “In Vitro and In Vivo Evaluation of Akermanite Bioceramics for Bone Regeneration”, Biomaterials, Vol. 30, Issue. 28, pp. 5041-5048, 2009.
[30]. L. Xia, Z. Zhang, L. Chen, W. Zhang, D. Zeng, X. Zhang & X. Jiang, “Proliferation and Osteogenic Differentiation of Human Periodontal Ligament Cells On Akermanite and ?-TCP Bioceramics”, European Cell Materials, Vol. 22, Issue. 68, pp. e82, 2011.
[31]. B.P. Chandra, V.K. Chandra & P. Jha, “Models For Intrinsic And Extrinsic Fracto-Mechanoluminescence of Solids”, Journal of Luminescence, Vol.135, Issue.139-153, 2013.
[32]. Y. Chen, X. Cheng, M. Liu, Z. Qi & C. Shi, “Comparison Study of the Luminescent Properties of the White-Light Long Afterglow Phosphors: CaxMgSi2O5+ X: Dy3+ (X= 1, 2, 3)”, Journal of Luminescence, Vol. 129, Issue. 5, pp. 531-535, 2009.
[33]. P. Chandrakar, D.P. Bisen, R.N. Baghel & B.P. Chandra, “Synthesis and Optical Properties of CaMgSi2O6:Ce3+ Phosphors”, Journal of Electronic Materials, Vol. 44, Issue. 10, pp. 3450-3457, 2015.
[34]. Q. Fei, C. Chang & D. Mao, “Luminescent Properties of Sr2MgSi2O7 and Ca2MgSi2O7 Long Lasting Phosphors Activated By Eu2+, Dy3+”, Journal of Alloys and Compounds, Vol. 390, Issue. (1-2), pp. 133-137, 2005.
[35]. S.K. Gupta, M. Kumar, V. Natarajan & S.V. Godbole, “Optical Properties of Sol–Gel Derived Sr2SiO4: Dy3+–Photo and Thermally Stimulated Luminescence”, Optical Materials, Vol. 35, Issue. 12, pp. 2320-2328, 2013.
[36]. L.V. Akat’eva, S.A. Kozyukhin, “Luminophores Based On Synthetic Calcium Silicates”, Theoretical Foundations of Chemical Engineering, Vol. 49, Issue. 5, pp. 706-713, 2015.
[37]. C.C. Lin, A. Meijerink, Ru-Shi. Liu, Journal of Physical Chemistry Letters, Issue. 7, pp. 495–503, 2016.
[38]. L. Lin, M. Yin, C. Shi & W. Zhang, “Luminescence Properties of A New Red Long-Lasting Phosphor: Mg2SiO4:Dy3+, Mn2+”, Journal of Alloys and Compounds, Vol. 455, Issue. (1-2), pp. 327-330, 2008.
[39]. L. Jiang, C. Chang & D. Mao, “Luminescent Properties of CaMgSi2O6 and Ca2MgSi2O7 Phosphors Activated by Eu2+, Dy3+ And Nd3+”, Journal of Alloys And Compounds, Vol. 360, Issue. (1-2), pp. 193-197, 2003.
[40]. D. Pandey, R. Sharma & N. Brahme, “Study of Optical Properties of Di Calcium- Magnesium Di Silicate Based Phosphors Doped Rare Earth Material”, International Journal of Advanced Research, Vol. 4, Issue. 1, pp. 1639- 1646, 2016.
[41]. H. Sun, C. Wu, K. Dai, J. Chang & T. Tang, “Proliferation And Osteoblastic Differentiation of Human Bone Marrow-Derived Stromal Cells On Akermanite-Bioactive Ceramics”, Biomaterials, Vol. 27, Issue. 33, pp. 5651-5657, 2006.
[42]. C. Wu, J. Chang, W. Zhai, C. Ni & J. Wang, Journal of Biomedical Material Research Part B Applied Biomaterials, Vol. 47, pp. 788, 2006.
[43]. R.C. Somers, M.G. Bawendi & D.G. Nocera, “Cdse Nanocrystal Based Chem-Bio-Sensors”, Chemical Society Reviews, Vol. 36, Issue. 4, pp. 579-591, 2007.
[44]. R. Parkesh, S. Mohsin, T.C. Lee & T. Gannlaugsson, Chem. Mater, Issue. 19, pp. 1656, 2007.
[45]. P.A.S. Jorge, M. Mayeh, R. Benrashid, P. Caldas, J.L. Santos & F. Farahi, “Quantum Dots As Self-Referenced Optical Fibre Temperature Probes For Luminescent Chemical Sensors”, Measurement Science and Technology, Vol. 17, Issue. 5, pp. 1032, 2006.
[46]. A. Hreniak, J. Rybka, A. Gamian, K. Hermanowics, J. Hanuza & Maruszewski, Journal of Luminescence, Vol. 987, pp. 122-123, 2007.
[47]. S.M. Pauley, “Lighting For The Human Circadian Clock: Recent Research Indicates That Lighting Has Become A Public Health Issue”, Medical Hypotheses, Vol. 63, Issue. 4, pp. 588-596, 2004.
[48]. C.C. Lin, A. Meijerink & R.S. Liu, “Critical Red Components For Next-Generation White LEDs”, The Journal of Physical Chemistry Letters, Vol. 7, Issue. 3, pp. 495-503, 2016.
[49]. L. Lin, M. Yin, C. Shi & W. Zhang, “Luminescence Properties Of A New Red Long-Lasting Phosphor: Mg2SiO4:Dy3+, Mn2+”, Journal of Alloys and Compounds, Vol. 455, Issue. (1-2), pp. 327-330, 2008.
[50]. G.B. Zhang, Z.M. Qi, H.J. Zhou, Y.B. Fu, T.L. Huo, X.X. Luo & C.S. Shi, “Photoluminescence of (Eu2+ & Dy3+) Co-Doped Silicate Long Lasting Phosphors”, Journal of Electron Spectroscopy and Related Phenomena, Vol. 144, pp. 861-863, 2005.