Advancing Next-Gen PEM Fuel Cells: Role of Nanostructured Catalysts
The transition to sustainable energy sources has become imperative due to the exhaustion of conventional resources caused by excessive use and their detrimental impact on the environment. Currently, alternative energy sources, such as solar, wind, nuclear, tidal, and geothermal energy, hydro have been introduced. Over the last few decades, focus has shifted to the use of hydrogen energy as a promising alternative to traditional power sources in almost all sectors requiring energy applications.
However, a major challenge holding back their widespread use is the high cost and limited performance of a key component called the catalyst layer (CL). This layer is responsible for speeding up the chemical reaction that generates electricity, but it typically requires a large amount of platinum, a rare and expensive metal and often has a thick, disordered structure that reduces efficiency.
This research, titled “Towards Next-Generation proton exchange membrane fuel Cells: The role of nanostructured catalyst layers” led by Dr. Narayanamoorthy Bhuvanendran, Assistant Professor, Department of Environmental Science and Engineering, was published in the Q1 Journal, Chemical Engineering Journal, with an Impact Factor of 13.4. The paper focuses on designing advanced nanostructured catalyst layers that are thinner, more organised, and use much less platinum. These next-generation CLs can help fuel cells perform better, last longer, and become more affordable.
The study reviews recent progress in this field, highlights innovative methods for creating these new structures, and outlines future directions to improve their practicality and environmental impact. Ultimately, this work aims to bring us closer to clean, efficient, and widely accessible fuel cell technology.
Fuel cells offer clean energy with zero emissions when using hydrogen, and higher energy efficiency than diesel or gas engines. Among them, Proton Exchange Membrane Fuel Cells (PEMFCs) are one of the most promising technologies. PEMFCs produce only water as a byproduct, making them a clean energy alternative to fossil fuels.
Abstract:
Catalyst layer (CL) is the major component of proton exchange membrane fuel cells (PEMFCs) and routinely fabricated by a catalyst ink-based processing method. Such conventional CLs typically confront low activity, unaffordable Pt loading, and severe mass transport issues due to the thick and disordered structure, hampering the widespread commercial application of PEMFCs.
Engineering of nanostructured CLs with low/ultralow Pt loading, ordered and/or ultrathin CLs, provides a highly promising pathway for overcoming these limitations. For the practical application of the nanostructured CLs in PEMFCs, this review comprehensively summarises and comments on the important research and development of nanostructured CLs over recent years, involving ordered electronic conductor-based CLs, ordered ionomer-based CLs, and ultrathin CLs.
The reviewed processes include
(i) analysing the motivation and necessity to design and fabricate nanostructured CLs based on the structure and mass transport process of conventional CLs,
(ii) scrutinising structure and composition, preparation methods, advantages, as well as
some feasible strategies for the remaining challenges of various nanostructured CLs in
detail,
(iii) the progress of single cell activity and durability of the nanostructured CLs. Finally, some perspectives on remaining challenges and future development of the nanostructured CLs are presented to guide the exploitation for the next-generation of advanced CLs of PEMFCs.
Practical implementations:
The practical objective of this study is to facilitate the development of more efficient, cost-effective, and durable proton exchange membrane fuel cells (PEMFCs) through the redesign of the catalyst layer utilising advanced nanostructures. This enhancement has the potential to substantially decrease dependence on costly platinum, reduce production expenses, and enhance the overall performance of fuel cells.
In terms of societal impact, this research contributes to the transition towards clean and sustainable energy systems, thereby reducing greenhouse gas emissions and air pollution associated with conventional fossil fuels. By making fuel cell technology more accessible and scalable, particularly for transportation and portable power applications, it supports global initiatives to combat climate change and improve energy security for future generations.
Collaborations:
Prof. Huaneng Su, Institute for Energy Research, Jiangsu University, Zhenjiang, China.
- Published in Departmental News, ENVS News, News, Research News
Critical agendas for the areal linguistics: locating Sindhi within South Asia
The Sindhi language presents a compelling case for examining the intersections of language, territory, and identity in the post-Partition context. In India, Sindhi often survives as a spoken language, primarily confined to the domestic sphere. This restricted use raises important questions about the conditions necessary for linguistic vitality.
Exploring the complexities surrounding Sindhi Dr Soni Wadhwa, Assistant Professor in the Department of Literature and Languages, has published a research article titled “Critical agendas for the areal linguistics: locating Sindhi within South Asia” in the Q1 journal Journal of Critical Inquiry in Language Studies. This publication contributes significantly to scholarly discussions on areal linguistics, offering critical insights into the precarious position of Sindhi and the broader implications for language studies in postcolonial South Asia.
This article explores these dynamics to foreground the often-overlooked role of technological, epistemological, and aesthetic resources in sustaining minority languages. In doing so, it positions Sindhi as a critical lens through which to understand the challenges faced by minoritised languages in the Global South, particularly those without a clear territorial anchoring.
Abstract
As a concept within applied linguistics, areal linguistics concerns itself with investigating the nature of structural similarities among languages produced by contact rather than by history or by genetic similarities. A critical look at its descriptive linguistic agendas reveals that the domain needs to be revisited in terms of questions of power relations and linguistic inequalities within specific linguistic
areas. Such investigations reconfigure the dynamics of geography and regionality within language as a site of power.
This study seeks to make an intervention into India as a linguistic area with a focus on Sindhi, a non-regional language in India. Given that the language and the community do not have a state or a linguistic territory within India, the condition of Sindhi is characterised by a sense of precarity. Seen through the prism of India as a linguistic area, this precarity is not quite visible. In revisiting the celebrated concept of India as a linguistic area, this study suggests ways of asking contemporary questions about areal linguistics that go beyond describing the nature of contact among languages, and instead ask how this contact impacts the markers of hegemony over minor languages in terms of technological,epistemological, and aesthetic leverage.
Social Implications of the Research
This research might help in building further study around minority languages in India as well as elsewhere in the Global South, we empower more languages. This will help people who know regional languages access the Internet and other aspects that Digital India aspires to address.
Sindhis in India are scattered in different cities and speak the regional or state languages or English at home. This work helps in pushing more research on the language and the community which can further inform policies for linguistic empowerment.
- Published in Departmental News, English Current Happenings, News, Research News
A Full-bridge Multiple-load LED Driver Offering Clean Energy
The Department of Electrical and Electronics Engineering proudly announces that the invention “Zero Voltage Switching Full-bridge Converter for Multiple LED Lighting Loads with Reduced Switch Current” with Application number: 202241076718 has been granted to Dr Ramanjaneya Reddy, Assistant Professor, Dr Tousif Khan Nizami, Associate Professor, and Ms Aswini Patakamoori, PhD Scholar in the Indian Patent Office Journal.
The research focuses on creating an energy-efficient power supply for LED lights, especially in areas that use a DC electricity system. The team has designed a system that can power multiple LED lights from a single unit, saving energy and cost. This system works at a very high efficiency of about 97.5%, which means very little energy is wasted as heat.
The special design uses a method called “soft switching,” which helps the internal parts of the system turn on and off with less stress, reducing heat and improving lifespan. It also needs fewer parts for each light, making it simpler, more reliable, and cheaper to produce. Additionally, the system allows the lights to be dimmed easily using a basic on-off control method, giving flexibility in brightness as needed.
Abstract
A 110 W soft-switched full-bridge multiple load LED driver is designed for DC-grid applications, achieving a high efficiency of 97.52%. The full-bridge configuration ensures that the switches carry minimal current, reducing conduction losses, and offers zero-voltage switching, significantly lowering switching losses. The reduced component count per lamp simplifies the design, enhances reliability, and reduces overall system costs. Additionally, the driver supports PWM-based dimming through simple on-off control, offering flexibility in illumination levels.
Practical Implementation/ Social Implications of the Research
The developed 110 W soft-switched full-bridge multiple-load LED driver is a highly efficient and scalable solution tailored for DC-grid applications, particularly those integrated with solar and battery-based energy systems. Operating at an impressive efficiency of 97.52% ensures minimal energy loss. This technology promotes sustainable development by enabling cleaner energy usage and reducing carbon emissions. Its simple, cost-effective design makes advanced lighting more accessible, especially in low-income or remote communities. Additionally, the ability to dim lights easily helps conserve energy further and allows users to adapt lighting to different needs, enhancing comfort and minimising waste.
Future Research Plans
To design more efficient, adaptable, and sustainable LED driver circuits,
- Extending soft-switching techniques to automotive, industrial, and smart lighting systems for broader applications.
- Incorporating digital control strategies for intelligent dimming, adaptive power regulation, and real-time performance monitoring.
- Exploring advanced semiconductor materials, such as Gallium Nitride (GaN) and Silicon Carbide (SiC), to enhance switching performance and thermal stability. Integration of energy harvesting techniques to create self-sustaining LED driver systems powered by renewable sources such as solar energy.
- Published in Departmental News, EEE NEWS, News, Research News
A New Phase of Engineering Education: Insights from Prof. Archana Sharma
The Department of Electrical and Electronics Engineering invited Prof. Archana Sharma, Distinguished Professor at Dr Shyama Prasad Mukherjee International Institute of Information Technology, Naya Raipur, and Senior Professor at HBNI Mumbai, for a Distinguished Lecture on May 01, 2025. Prof. Archana Sharma delivered an insightful session on “Era of Multi-Disciplinary Research and Networking in Engineering Education” emphasising the significance of multidisciplinary research and networking in engineering education, commending institutes driving innovation for a progressive, Viksit Bharat.
Prof. Sharma, a globally acclaimed expert in beam technology and nuclear applications, elucidated that as India aspires to become a developed nation by 2047 during its ‘Amrit Kaal’, synergy among academia, industry, and researchers is vital. She also shed light on her pioneering contributions—from developing India’s first multi-gigawatt pulsed power system to driving sustainable technologies in wastewater treatment.
The talk sparked vibrant discussions around emerging research opportunities, with special focus on the possible installation of an electron beam accelerator at SRM AP for material and agricultural applications. The session provided invaluable insights to students and researchers on navigating the evolving landscape of science and technology with a multi-disciplinary lens.
- Published in Departmental News, EEE NEWS, News
Special Lecture on Future of Migration in India
The Department of Economics, Easwari School of Liberal Arts, organised a lecture on the topic “Future of Migration in India”. Prof. S Irudaya Rajan, Distinguished Visiting Faculty at the Department and Chairman of the International Institute of Migration and Development (IIMAD), Kerala, delivered an engaging talk for the special lecture.
Prof. Rajan, a leading demographer and renowned expert in migration studies, provided an in-depth analysis of India’s internal and international migration trends. He discussed the implications of demographic changes, urbanisation, labour market dynamics, and policy challenges. Drawing from empirical data and his extensive research, he stressed the urgent need for a comprehensive migration policy in India, particularly in light of reverse migration during COVID-19 and the growing issue of climate-induced displacement. He also touched upon the demographic consequences of migration, including its impact on fertility and mortality rates.
The talk attracted participants from diverse academic backgrounds, including faculty members, undergraduate students, and research scholars. The lecture concluded with a lively Q&A session, reflecting a strong interest in migration and development issues among attendees.
The event was a resounding success, contributing meaningfully to academic dialogue at SRM University-AP. It reinforced the institution’s commitment to interdisciplinary research and public policy engagement, while offering valuable insights into one of India’s most pressing socio-economic challenges.
- Published in Departmental News, Economics Current Happenings, News
Lecture on Large Values of Fourier Coefficients
The Department of Mathematics organised a guest lecture on May 07, 2025. Dr Krishnarjun Krishnamoorthy, a post-doctoral fellow at the Beijing Institute of Mathematical Sciences and Applications delivered an insightful talk on “Large Values of Fourier Coefficients”. He discussed a modification of Soundararajan’s resonance method to produce large values of Fourier coefficients of half-integral weight Hilbert modular forms.
Around 30 participants, including faculty members and research scholars, attended the lecture. Following the talk, a vibrant question-and-answer session allowed attendees to engage deeply with the topic, showcasing their enthusiasm and curiosity.
The event was a great success, fostering academic interest and collaboration within the university. It provided a valuable opportunity for the academic community to interact with an active researcher in the field and gain deeper insights into advanced mathematical topics.
- Published in Departmental News, Math News, News
Skill Development Workshop on Next Gen Power Electronics
The Department of Electrical and Electronics Engineering organised a Skill Development Workshop on Next-Gen Power Electronics: Magnetics, Gate Drivers & Converter Design. Mr Sadeep Sasidharan, Director, Reliamotive Labs, Dr Ashiq Muhammed, Assistant Professor, NIT Calicut and Mr Aravind Gopalakrishnan, Co-founder, Reliamotive Labs, were the resource persons for the workshop along with faculty members of SRM University-AP.
The workshop provided participants with a comprehensive understanding of the rapidly evolving field of power electronics, combining theoretical knowledge with practical insights. Participants enhanced their expertise through offline sessions delivered by in-house faculty and industry experts from Reliamotive Labs, Bangalore.
The workshop covered the latest trends and technologies in power electronics, with a particular focus on hardware design and development of converters, the design of magnetics for the Flyback Converter, and designing PCBs using KiCad software. It offered hands-on learning opportunities and provided exposure to real-world applications. Participants had the chance to network with professionals, researchers, and experts, fostering collaboration and the exchange of innovative ideas. The workshop has resulted in the participants developing technical skills in circuit design, analysis, and troubleshooting, as well as gaining proficiency with industry tools and software.
An insightful Q&A session helped participants clarify concepts and deepen their understanding during interactions with industry experts. Post-workshop, attendees applied the knowledge gained through mini-projects or continued practice, especially in hardware design and magnetics. Networking with peers and staying connected with resource persons opened doors for collaborative opportunities and further learning.
- Published in Departmental News, EEE NEWS, News, Workshop
MSc Mathematics Student Secures Mitacs Globalink Research Award
Ms Kaavya R, first-year MSc Mathematics student, has been awarded the prestigious Mitacs Globalink Research Award, a global award for international students. Under this honour, she will pursue a 12–24 week research project titled “Improved Order Computation in Class Groups of Real Quadratic Fields” at the University of Calgary, Canada, under the supervision of Prof. Michael John Jacobson. Prof. Kalyan Chakraborty, her mentor at SRM University-AP, continues to play a pivotal role in her academic journey.
This award offers a grant of $6,000 CAD (approx. ₹3,67,000) and marks Kaavya’s second major research opportunity, following her selection for the IASc-INSA-NASI Summer Research Fellowship, under which she will work at the Indian Statistical Institute, Bengaluru, with a monthly stipend of ₹12,500.
Kaavya credits her professors and department faculty for their constant support, especially Prof. Chakraborty, whose mentorship has helped shape her interests in number theory and research.
Kudos to Ms Kaavya for her remarkable achievement and continued success in exploring new mathematical horizons
- Published in Departmental News, Math News, News, Research News, Students Achievements
Analysing the Dynamism of AR Comics Through Ram Devineni’s Priya Series
Dr Partha Battacharjee, Assistant Professor from the Department of Literature and Languages, and his PhD scholar Mr Rounak Gupta have published a research article titled “Traversing through Transmedia: Dynamism of Augmented Reality Comics and Gender-based Violence in Ram Devineni’s Priya Series” in the Q1 journal, Journal of Graphic Novels and Comics.
The paper points out how augmented reality can enhance the reading and receptive experience of comics that can address, teach, and educate people on complex social problems like gender-based violence.
Abstract
This article looks at how Ram Devineni’s comic series—Priya’s Shakti, Priya’s Mirror, and Priya and the Lost Girls—use augmented reality and Hindu mythology to raise awareness about gender-based violence in India. It shows how these comics break traditional storytelling methods to engage readers on serious issues like rape, acid attacks, and trafficking.
Practical Implementation/ Social Implications of the Research
It is an analytical research that helps understand how basic building blocks towards gender sensitisation can be developed using comics and augmented reality technology to ‘educate’ people in a much more immersive and interesting way.
The team will continue to develop a theoretical foundation for addressing transmedia approaches in comics and other seemingly static art forms.
Collaboration
Dr Priyanka Tripathi, Associate Professor, Department of Humanities and Social Sciences, IIT Patna
- Published in Departmental News, English Current Happenings, English news, News, Research News
Biofilm-forming Marine Bacteria and their Role in Plastic Degradation
One of the major risks to the world’s ecosystems today is plastic pollution, it affects both the terrestrial and marine ecosystems alike. While India generates around 9.4 million tons of plastic annually, around 5.6 million tons are recycled, and the remaining 3.8 million tons goes uncollected or improperly disposed turning the country into a plastic pollution hotspot.
Addressing the existing gaps in understanding marine plastic and biodegradation which is the breakdown of these plastic materials by microorganisms, Dr Prasun Goswami, Assistant Professor, Department of Environmental Science and Engineering, has recently published a research paper titled “Microplastics Under Siege: Biofilm-forming Marine Bacteria from the Micro Plastisphere and their Role in Plastic Degradation”. The paper was published in the Q1 journal, Science of the Total Environment, with an Impact Factor of 8.2.
Over a period of time plastic debris degrade into smaller pieces, eventually forming microplastics (less than 5mm) which are increasingly found in water sources, including drinking water, and pose a potential threat to human health and aquatic life. Some studies suggest that ingested microplastics may have negative health effects, including reproductive damage. Microbial biodegradation has been regarded as one of the effective ways to deal with plastic pollution.
Abstract
Microplastics, laden with toxins and microorganisms, threaten marine ecosystems by affecting both living organisms and environmental processes. This study explores the diversity and plastic-degrading potential of culturable bacteria colonizing microplastics collected from three coastal sites of the Andaman and Nicobar Islands. Low-density polyethylene (LDPE) was the most prevalent polymer identified in the plastic debris. Among 24 bacterial isolates screened, strain NIOT-MP-52 demonstrated the highest LDPE degradation efficiency (10.79%) which means breaking down the plastic and was subjected to detailed characterization. Analytical techniques (FT-IR, SEM, AFM, DSC) confirmed microbial degradation through surface alterations and thermal changes. The findings underscore the promising role of marine bacteria in biodegrading plastics, offering potential solutions for sustainable plastic waste management.
Practical Implementations of the Research
This research offers a sustainable solution to marine plastic pollution by identifying native bacteria capable of degrading low-density polyethylene (LDPE), a common plastic pollutant. The most efficient strain, NIOT-MP-52, showed significant potential for breaking down plastic, indicating its practical use in eco-friendly bioremediation systems like biofilters or wastewater treatment setups. Socially, this approach supports healthier marine ecosystems, reduces human exposure to microplastics, and encourages nature-based waste management strategies, potentially creating green jobs in coastal communities.
Collaborations
This research was originally carried out at the Atal Centre for Ocean Science and Technology for Islands, National Institute of Ocean Technology, Ministry of Earth Sciences, Government of India, Sri Vijaya Puram, India. National Institute of Ocean Technology, Ministry of Earth Sciences, Government of India, Chennai, India.
- Published in Departmental News, ENVS News, News, Research News