Currently, working as a Sr Assistant Professor at SIT Pune
EDUCATION
PhD from MNNIT Allahabd
M.Tech from NIT Hamirpur
RESEARCH, TEACHING, or OTHER INTERESTS
Electrical and Electronic Engineering, Renewable Energy, Sustainability and the Environment
39
Scopus Publications
Scopus Publications
Designing the future of connectivity: a systematic and bibliometric review of nanomaterial microstrip patch antennas in the context of the sustainable development goals Vikas Kaduskar, Sankit Kassa Discover Sustainability, 2026 The need for small, energy-efficient, and ecologically friendly antenna technology has increased dramatically as wireless communication has advanced, especially in 5G and IoT. With a focus on their contribution to the Sustainable Development Goals (SDGs) of the UN, this work provides a thorough bibliometric and systematic assessment of nanomaterial-based microstrip patch antennas (MPAs). The research identifies the leading materials—graphene, carbon nanotubes, and metamaterials—known for their superior electrical, thermal, and miniaturization capabilities by using data from 342 peer-reviewed papers published between 2015 and 2025 in databases including Web of Science, and Scopus, IEEE Xplore. The most common contributors, according to the bibliometric study, are China, the United States, and India. Green electronics and sustainable 5G are among the major issues. Using VOSviewer and Bibliometrix to map research clusters and collaborations, the study shows how nanomaterial-enhanced MPAs match with SDGs 9 (Industry, Innovation, and Infrastructure) and 13 (Climate Action), among other goals. Despite encouraging technology developments, issues with material toxicity, economic effectiveness, and large-scale deployment still exist.
Optimized design of digital comparator using QCA V Ramesh Kumar, B Maneendra Mahan, Jadav Chandra Das, Sankit Kassa, Debashis De Physica Scripta, 2025 This study introduces a single-bit comparator circuit designed using QCA. The proposed design surpasses existing designs comprehensively in every aspect. This study introduces an innovative approach to enhancing the robustness of a QCA-based single-bit comparator through a newly developed design. This approach contributes to its low complexity and potentially reduced energy consumption. In the comparison with the literature, the proposed design comprises of only 19 cells and best clock latency is observed with a value of 0.25 clock cycles. Fault tolerance analysis is performed on the comparator to identify potential vulnerabilities and optimize the fabrication process. To evaluate the performance of this comparator, software tools such as QCA Designer-E and QCA Pro are used to estimate its overall energy dissipation. The detailed findings are presented within the broader context of the paper.
A nano-design of a quantum-based arithmetic and logic unit for enhancing the efficiency of the future IoT applications Seyed Sajad Ahmadpour, Maryam Zaker, Nima Jafari Navimipour, Neeraj Kumar Misra, Muhammad Zohaib, Sankit Kassa, Arash Heidari, Ahmad Habibizad Navin, Mehdi Hosseinzadeh, Musawer Hakimi Aip Advances, 2025 The Internet of Things (IoT) is an infrastructure of interconnected devices that gather, monitor, analyze, and distribute data. IoT is an inevitable technology for smart city infrastructure to ensure seamless communication across multiple nodes. IoT, with its ubiquitous application in every sector, ranging from health-care to transportation, energy, education, and agriculture, comes with serious challenges as well. Among the most significant ones is security since the majority of IoT devices do not encrypt normal data transmissions, making it easier for the network to breach and leak data. Traditional technologies such as CMOS and VLSI have the added disadvantage of consuming high energy, further creating avenues for security threats for IoT systems. To counter such problems, we require a new solution to replace traditional technologies with a secure IoT. In contrast to traditional solutions, quantum-based approaches offer promising solutions by significantly reducing the energy footprint of IoT systems. Quantum-dot Cellular Automata (QCA) is one such approach and is an advanced nano-technology that exploits quantum principles to achieve complex computations with the advantages of high speed, less occupied area, and low power consumption. By reducing the energy requirements to a minimum, QCA technology makes IoT devices secure. This paper presents a QCA-based Arithmetic Logic Unit (ALU) as a solution to IoT security problems. The proposed ALU includes more than 12 logical and arithmetic operations and is designed using majority gates, XOR gates, multiplexers, and full adders. The proposed architecture, simulated in QCADesigner 2.0.3, achieves an improvement of 60.45% and 66.66% in cell count and total occupied area, respectively, compared to the best of the existing designs, proving to be effective and efficient.
An implementation of high-speed digital reconfigurable FIR filter using low power carry look ahead adder-review Journal of Advanced Research in Dynamical and Control Systems, 2018
