Your search keyword '"Akbar, Nabeela"' showing total 39 results

1. Al3+ doped CeO2 for proton conducting fuel cells

Author

Sarfraz, Rasool, Shahzad, Khalid, Muhammad, Shah, M. A. K. Yousaf, Zhu, Bin, Kim, Jung-Sik, Asghar, Muhammad Imran, Akbar, Nabeela, and Dong, Wenjing

Published

2024

2. Synergistically improving the performance of spinel cathode for efficient oxygen reduction electrocatalyst

Author

Lu, Yuzheng, Shah, M.A.K. Yousaf, Mushtaq, Naveed, Rauf, Sajid, Yousaf, Muhammad, Akbar, Nabeela, and Raza, Rizwan

Published

2024

3. Enhancing the performance of the BaTiO3 electrolyte via A-site-deficiency engineering for low-temperature ceramic fuel cells (LT-CFCs)

Author

Khalid, Muhammad, Shah, M.A.K. Yousaf, Akbar, Nabeela, Masood, M. Ahsan, Nazar, Atif, Zhu, Bin, Raza, Rizwan, and Jun, Wang

Published

2024

4. An innovative perovskite oxide enabling improved efficiency for low-temperature ceramic electrochemical cells

Author

Lu, Yuzheng, Shah, M. A. K. Yousaf, Mushtaq, Naveed, Yousaf, Muhammad, Akbar, Nabeela, Arshad, Naila, and Irshad, Sultan

Published

2024

5. Experiencing heightened oxygen reduction response in CaFe2O4-WO3 heterostructure for ceramic fuel cells

Author

Mushtaq, Naveed, Yousaf Shah, M.A.K., Almutairi, Badriah S., Rauf, Sajid, Akbar, Nabeela, Wu, Ping, Huang, Lijun, Mi, Xianwu, Zhu, Bin, and Lu, Yuzheng

Published

2024

6. Analyzing the composite heterostructure as an efficient electrolyte for low-temperature ceramic fuel cells

Author

Li, Junjiao, Shah, M.A.K. Yousaf, Lu, Yuzheng, Mushtaq, Naveed, Yousaf, Muhammad, Akbar, Nabeela, Arshad, Naila, and Irshad, Muhammad Sultan

Published

2024

7. Insight of proton transport phenomena in semiconductor ionic materials

Author

Rasool, Shahzad, Akbar, Nabeela, Shah, M.A.K. Yousaf, Afzal, Muhammad, Sarfraz, and Zhu, Bin

Published

2024

8. High entropy oxide coated BaTiO3 enabling high ionic transport

Author

Khalid, Muhammad, Akbar, Nabeela, Shah, M.A.K. Yousaf, and Zhu, Bin

Published

2024

9. Promoting electrocatalytic activity of single-phase semiconductor Y3Fe5O12 (YIG) dual-functional cathode/electrolyte for ceramic fuel cells

Author

Lu, Yuzheng, Noor, Asma, Akbar, Muhammad, Alomar, Muneerah, Akbar, Nabeela, Shah, M.A.K. Yousaf, Mushtaq, Naveed, and Yousaf, Muhammad

Published

2024

10. Uncovering proton transportation enabled via the surface and interfacial engineering for ceramic fuel cells

Author

Shah, M.A.K. Yousaf, Lu, Yuzheng, Mushtaq, Naveed, Alomar, Muneerah, Yousaf, Muhammad, Akbar, Nabeela, Arshad, Naila, Irshad, Muhammad Sultan, and Zhu, Bin

Published

2024

11. Designing highly active core/shell cathode materials for low-temperature PCFCs

Author

Lu, Yuzheng, Yousaf Shah, M.A.K., Almutairi, Badriah S., Mushtaq, Naveed, Yousaf, Muhammad, Akbar, Nabeela, Arshad, Naila, Irshad, Muhammad Sultan, and Dong, Yiwang

Published

2023

12. Semiconductor-membrane fuel cell (SMFC) for renewable energy technology

Author

Shah, M.A.K. Yousaf, Lu, Yuzheng, Mushtaq, Naveed, Yousaf, Muhammad, Akbar, Nabeela, Xia, Chen, Yun, Sining, and Zhu, Bin

Published

2023

13. Surfacial proton conducting CeO2 nanosheets

Author

Paydar, Sara, Zhu, Bin, Shi, Jing, Akbar, Nabeela, Islam, Quazi Arif, Yun, Sining, Muhammad, Akbar, Paydar, Mohammad Hossein, and Wu, Yan

Published

2023

14. Interfacial ionic transport in natural palygorskite-Na0.60CoO2 nanocomposite mineral materials

Author

Bi, Wenming, Huang, Liwen, Akbar, Nabeela, and Wu, Yan

Published

2022

15. Lithium zirconate coated LiNi0.8Co0.15Al0.05O2 as a high-performance electrode material for advanced fuel cells

Author

Zhao, Shuang, Huang, Liwen, Akbar, Nabeela, and Wu, Yan

Published

2022

16. Al3+ doped CeO2 for proton conducting fuel cells.

Author

Sarfraz, Rasool, Shahzad, Khalid, Muhammad, Shah, M. A. K. Yousaf, Zhu, Bin, Kim, Jung-Sik, Asghar, Muhammad Imran, Akbar, Nabeela, and Dong, Wenjing

Abstract

Developing high ionic conducting electrolytes is crucial for applying proton-conducting fuel cell (PCFCs) practically. The current study investigates the effect of alumina on the structural, morphological, electrical, and electrochemical properties of CeO2. Lattice oxygen vacancies are induced in CeO2 by a general doping concept that enables fast ionic conduction at low-temperature ranges (300–500°C) for PCFCs. Rietveld refinement of the X-ray diffraction (XRD) patterns established the pure cubic fluorite structure of Al-doped CeO2 (ADC) samples and confirmed Al ions' fruitful integration in the CeO2 lattice. The electronic structure of the alumina-doped ceria of the materials (10ADC, 20ADC, and 30ADC) has been investigated. As a result, it was found that the best composition of 30ADC-based electrolytes induced maximum lattice oxygen vacancies. The corresponding PCFC exhibited a maximum power output of 923 mW/cm2 at 500°C. Moreover, the investigation proves the proton-conducting ability of alumina-doped ceria-based fuel cells by using an oxide ion-blocking layer. [ABSTRACT FROM AUTHOR]

Published

2024

17. Tunning tin-based perovskite as an electrolyte for semiconductor protonic fuel cells

Author

Akbar, Nabeela, Paydar, Sara, Afzal, Muhammad, Akbar, Muhammad, Kamran Yousaf Shah, Muhammad Ali, Ge, Wen, and Zhu, Bin

Published

2022

18. Performance analysis of LiAl0.5Co0.5O2 nanosheets for intermediate-temperature fuel cells

Author

Paydar, Sara, Peng, Jin, Huang, Liwen, Shi, Quan, Akbar, Nabeela, Islam, Quazi Arif, Muhammad, Akbar, Xing, Yueming, Kim, Jung-Sik, and Wu, Yan

Published

2021

19. Nanoparticle exsolution in perovskite oxide and its sustainable electrochemical energy systems

Author

Islam, Quazi Arif, Paydar, Sara, Akbar, Nabeela, Zhu, Bin, and Wu, Yan

Published

2021

20. Electrical properties of Ni-doped Sm2O3 electrolyte

Author

Zhang, Jing, Paydar, Sara, Akbar, Nabeela, and Yan, Chunjie

Published

2021

21. Tuning an ionic-electronic mixed conductor NdBa0.5Sr0.5Co1.5Fe0.5O5+δ for electrolyte functions of advanced fuel cells

Author

Akbar, Nabeela, Paydar, Sara, and Wu, Yan

Published

2021

22. Developing cuprospinel CuFe2O4–ZnO semiconductor heterostructure as a proton conducting electrolyte for advanced fuel cells

Author

Paydar, Sara, Akbar, Nabeela, Shi, Quan, and Wu, Yan

Published

2021

23. Semiconductor Heterostructure (SrFe0.3TiO3-ZnO) Electrolyte with High Proton Conductivity for Low-Temperature Ceramic Electrochemical Cells.

Author

Shah, M. A. K. Yousaf, Yuzheng Lu, Mushtaq, Naveed, Yousaf, Muhammad, Rauf, Sajid, Akbar, Nabeela, Arshad, Naila, Irshad, Sultan, and Bin Zhu

Published

2024

24. Advanced fuel cell based on semiconductor perovskite La–BaZrYO3-δ as an electrolyte material operating at low temperature 550 °C

Author

Shah, M.A.K Yousaf, Mushtaq, Naveed, Rauf, Sajid, Akbar, Nabeela, Xing, Yueming, Wu, Yan, Wang, Baoyuan, and Zhu, Bin

Published

2020

25. Semiconductor Heterostructure (SrFe0.3TiO3-ZnO) Electrolyte with High Proton Conductivity for Low-Temperature Ceramic Electrochemical Cells

Author

Shah, M.A.K. Yousaf, Lu, Yuzheng, Mushtaq, Naveed, Yousaf, Muhammad, Rauf, Sajid, Akbar, Nabeela, Arshad, Naila, Irshad, Sultan, and Zhu, Bin

Abstract

In recent years, ceramic cells based on high proton conductivity have attracted much attention and can be employed for hydrogen production and electricity generation, especially at low temperatures. Nevertheless, attaining a high power output and durability is challenging, especially at low operational temperatures. In this regard, we design semiconductor heterostructure SFT-ZnO (SrFe0.3TiO3-ZnO) materials to function as an electrolyte for fuel cell and electrolysis applications. Using this approach, the functional semiconductor heterostructure can deliver a better power output and high ionic and proton conductivity at low operational temperatures. The prepared cell in fuel cell mode has demonstrated excellent performance of 700 mW cm–2and proton performance of 540 mW cm–2at the low temperature of 520 °C, suggesting dominant proton conduction. Further, the prepared cell delivers exceptional current densities of 1.18 and 0.38 A cm–2(at 1.6 and 1.3 V, respectively) at 520 °C in the electrolysis mode. Our electrochemical cell is stable in fuel and electrolysis mode at a low temperature of 500 °C.

Published

2024

26. Fluorite Alumina Fuel Cells

Author

Lund, Peter, primary, Shah, M.A.K. Yousaf, additional, Akbar, Nabeela, additional, Zhao, Wenjuan, additional, Mushtaq, Naveed, additional, Wan, Shuo, additional, Lu, Yuzheng, additional, Fan, Liangdong, additional, Yu, Yong, additional, Huang, Jiangbing, additional, He, Lunhua, additional, Hao, Jiazheng, additional, Lou, Chenjie, additional, Tang, Mingxue, additional, and Zhu, Bin, additional

Published

2023

27. High Entropy Oxide Coated BaTiO3 Enabling High Ionic Transport

Author

Khalid, Muhammad, primary, Akbar, Nabeela, additional, Shah, M.A.K. Yousaf, additional, and Zhu, Bin, additional

Published

2023

28. Uncovering proton transportation enabled via the surface and interfacial engineering for ceramic fuel cells

Author

Shah, M.A.K. Yousaf, primary, Lu, Yuzheng, additional, Mushtaq, Naveed, additional, Alomar, Muneerah, additional, Yousaf, Muhammad, additional, Akbar, Nabeela, additional, Arshad, Naila, additional, Irshad, Muhammad Sultan, additional, and Zhu, Bin, additional

Published

2023

29. Showcasing the Potential of Iron-Doped Electrolytes to Enhance the Ionic Conduction for a Low-Temperature Ceramics Fuel Cell

Author

Shah, M. A. K. Yousaf, primary, Lu, Yuzheng, additional, Mushtaq, Naveed, additional, Alomar, Muneerah, additional, Yousaf, Muhammad, additional, Akbar, Nabeela, additional, Arshad, Naila, additional, Irshad, Muhammad Sultan, additional, and Zhu, Bin, additional

Published

2023

30. Space Charge Polarization Effect in Surface-Coated BaTiO3 Electrolyte for Low-Temperature Ceramic Fuel Cell.

Author

Akbar, Nabeela, Paydar, Sara, Shah, M.A.K. Yousaf, Mushtaq, Naveed, Yousaf, Muhammad, Kim, Jung-Sik, Wu, Yan, and Zhu, Bin

Published

2024

31. Designing a Novel Semiconductor Electrolyte (LaSrTiCrCeO3) with Enhanced Ionic Conduction for Low-Temperature Ceramic Fuel Cells

Author

Shah, M. A. K. Yousaf, primary, Lu, Yuzheng, additional, Mushtaq, Naveed, additional, Yousaf, Muhammad, additional, Akbar, Nabeela, additional, Arshad, Naila, additional, Irshad, Muhammad Sultan, additional, and Zhu, Bin, additional

Published

2023

32. Semiconductor Heterostructure (SFT–SnO2) Electrolyte with Enhanced Ionic Conduction for Ceramic Fuel Cells.

Author

Lu, Yuzheng, Shah, M.A.K. Yousaf, Mushtaq, Naveed, Yousaf, Muhammad, Akbar, Nabeela, Arshad, Naila, Irshad, Muhammad Sultan, Lund, Peter D., Zhu, Bin, and Asghar, Imran

Published

2023

33. Designing a Novel Semiconductor Electrolyte (LaSrTiCrCeO3) with Enhanced Ionic Conduction for Low-Temperature Ceramic Fuel Cells.

Author

Shah, M. A. K. Yousaf, Lu, Yuzheng, Mushtaq, Naveed, Yousaf, Muhammad, Akbar, Nabeela, Arshad, Naila, Irshad, Muhammad Sultan, and Zhu, Bin

Published

2023

34. Surfacial Proton Conducting Ceo2 Nanosheets

Author

Paydar, sara, primary, Zhu, Bin, additional, Shi, Jing, additional, AKBAR, NABEELA, additional, Islam, Quazi Arif, additional, Yun, Sining, additional, Muhammad, Akbar, additional, paydar, mohammad Hossein, additional, and Wu, Yan, additional

Published

2022

35. Electrochemical Properties of a Co-Doped SrSnO3−δ-Based Semiconductor as an Electrolyte for Solid Oxide Fuel Cells

Author

Shah, M. A. K. Yousaf, primary, Zhu, Bin, additional, Rauf, Sajid, additional, Mushtaq, Naveed, additional, Yousaf, Muhammad, additional, Ali, Nasir, additional, Tayyab, Zuhra, additional, Akbar, Nabeela, additional, Yang, Chang Ping, additional, and Wang, Baoyuan, additional

Published

2020

36. Electrochemical Properties of a Co-Doped SrSnO3-δ-Based Semiconductor as an Electrolyte for Solid Oxide Fuel Cells.

Author

Shah, M. A. K. Yousaf, Zhu, Bin, Rauf, Sajid, Mushtaq, Naveed, Yousaf, Muhammad, Ali, Nasir, Tayyab, Zuhra, Akbar, Nabeela, Yang, Chang Ping, and Wang, Baoyuan

Published

2020

37. Deep Levels in InGaN/GaN-LEDs

Author

Naz, Nazir A., primary, Imran, M., additional, Akbar, Nabeela, additional, and Ali, Akbar, additional

Published

2015

38. ‘Glocalization of Politics’ in South Asia and Central Asia 2012-2016.

Author

Akbar, Nabeela and Ahmad, Rana Eijaz

Abstract

The Central Asia and South Asia have become pivotal in the contemporary global politics. The closing of the twentieth century and the beginning of the twenty-first century have developed complex political conditions in the region due to changed geo-political circumstances which has involved South Asia and Central Asia as well. The object of the paper is to analyze that the’ Glocalization of politics’ in South Asia and Central Asia focuses on the concept of thinking global and acting local. It my overcome a complex of geopolitical, logistical, and economic factors which are a barrier in inter-regional connectivity and to transport the natural resources of Central Asian states to the global market in order to meet the world’s growing energy demands. Though Central Asia has abundant of natural resources, yet its geopolitical conditions have made it difficult for transporting and marketing them to the world economic market. The main problem that foreign investors are facing in the Central Asia is that how to transport the energy reservoirs from these landlocked states to the world market. The transportation route is of great geopolitical significance. The regional and global actors are in pursuit of their own national interests and to get politico-economic benefits from these two strategically important regions. The presence of regional and global competitors has aggravated the affairs of both regions. The research methodology is descriptive and analytical and the conclusion of this research paper is that the’ Glocalization of politics’ in South Asia and Central Asia is inversely proportional to the inter-regional connectivity. [ABSTRACT FROM AUTHOR]

Published

2016

39. Semiconductor Heterostructure (SrFe 0.3 TiO 3 -ZnO) Electrolyte with High Proton Conductivity for Low-Temperature Ceramic Electrochemical Cells.

Author

Shah MAKY, Lu Y, Mushtaq N, Yousaf M, Rauf S, Akbar N, Arshad N, Irshad S, and Zhu B

Abstract

In recent years, ceramic cells based on high proton conductivity have attracted much attention and can be employed for hydrogen production and electricity generation, especially at low temperatures. Nevertheless, attaining a high power output and durability is challenging, especially at low operational temperatures. In this regard, we design semiconductor heterostructure SFT-ZnO (SrFe 0.3 TiO 3 -ZnO) materials to function as an electrolyte for fuel cell and electrolysis applications. Using this approach, the functional semiconductor heterostructure can deliver a better power output and high ionic and proton conductivity at low operational temperatures. The prepared cell in fuel cell mode has demonstrated excellent performance of 700 mW cm -2 and proton performance of 540 mW cm -2 at the low temperature of 520 °C, suggesting dominant proton conduction. Further, the prepared cell delivers exceptional current densities of 1.18 and 0.38 A cm -2 (at 1.6 and 1.3 V, respectively) at 520 °C in the electrolysis mode. Our electrochemical cell is stable in fuel and electrolysis mode at a low temperature of 500 °C.

Published

2024