Aerospace Engineering Seminar Series: "Rotorcraft Noise: Past, Present and Future” - Bhaskar Mukherjee

Thursday, January 29, 2026; 3:00pm-4:00pm
028 ECoRE
Speaker: Bhaskar Mukherjee from The Pennsylvania State University

Abstract: Rotor noise remains a major barrier to commercializing helicopters and emerging electric multirotor aircraft, often prompting curfews and flight caps. Accurate noise prediction has strong commercial value: it guides design tradeoffs and helps operators and airports manage community exposure. High-fidelity CFD is common for steady cases (e.g., hover), but real operations are unsteady; matching what communities hear requires time-accurate simulations over hundreds of revolutions—too expensive for CFD in practice. Mid-fidelity methods offer a better accuracy-to-cost balance, making maneuver noise prediction practical. As these models become faster and more accurate with growing computational power, new applications emerge beyond evaluating community noise impact. In autonomous operations, acoustics can complement vision and other sensors, adding cues that improve awareness and safety in shared airspace.

Speaker Bio: Bhaskar Mukherjee earned his PhD in Aerospace Engineering at Penn State, specializing in rotorcraft aeroacoustics, aerodynamics, and flight simulation. His dissertation developed mid-fidelity noise prediction tools for emerging electric vertical takeoff and landing (eVTOL) aircraft and helicopters. He received the Airport Cooperative Research Program (ACRP) Graduate Research Award for applying these methods to assess community noise around New York City heliports, considering both current helicopter operations and the potential introduction of eVTOL vehicles. He continues this research at Penn State, expanding noise prediction toward new applications in aircraft safety and autonomy.

Hosted by: Jessica Chhan,  jmc7050@psu.edu

Physics of nanoscale spectral imaging beyond diffraction limit

Wednesday, January 28, 2026; 121 Earth & Engineering Science Building
335PM-425PM
Speaker: Slava Rotkin from ESM

Abstract: Recent success in synthesis of new two-dimensional materials (2DM) beyond graphene (including TMDCs, heteronanotubes, hBN family, MXenes and atomic polar metals), was followed by a large number of works exploring their properties and seeking for novel applications in quantum technologies, biosensing, energy and computing. Atomically thin 2DMs have an ultimate surface-to-volume ratio. While it helps biosensing, electronics and other applications, surface non-uniformities may drastically increase variability of materials properties. Such non-uniformities are known to be a critical limiting factor for other types of nanomaterials as well. Modulation of optical properties at the nanometer scale due to atomic impurities or adsorbates or defects, wrinkles or ruptures, lattice mismatch, doping and work function variation is important to be able to control. However, even before developing synthetic approach to mitigate the problem, appropriate characterization tools are needed to detect such a modulation.

In this talk, several methods for nanoscale (sub-diffractional) optical characterization will be presented. Correlated multiplexed (multidimensional) optical imaging technique will be introduced using a few examples including: a vertical heterostructure comprised of monolayer graphene and single layer flakes of MoS2,[1] heteronanotubes with carbon core and hBN/MoS2 shell,[2] glass nanoindentations[3,9] and heterostructures of graphene/Ag/SiC atomic layers[4,10]. The correlation of several information channels (including microRaman[5,6]) allows one to obtain information on, e.g., local Fermi level and strain tensor components[1] or distribution of chemical bonds in a glassy material[3].

It will be shown that similar results could be obtained using scattering Scanning Near-field Optical Microscopy (sSNOM), the technique which produces multidimensional information in a single run. sSNOM will be shown to map polaritonic wavefunction and detect polaritonic confinement in heterostructures of atomic-thin metals[10]. As the time allows, a quantum theory of sSNOM imaging will be discussed [7,8].

Literature:

1. ACS Nano 2022, 16, 2598.

2. ACS Nano 2021, 15, 5600.

3. Acta Materialia 2021, 208, 116694.

4. Science Advances 2025, 11, eadw1800.

5. Nature Comm 2015, 6, 8429.

6. J Mat Chem B 2017, 5, 6536.

7. ACS Nano 2015, 20, 360.

8. S.V. Rotkin, Materials Science & Technology 2022 (October 9-13, Pittsburgh, PA).

9. Ceramics International 2024, 50 Part A, 32457.

10. X. Li, et.al, (submitted).

Bio:

Slava V. Rotkin is Frontier Professor of Engineering Science & Mechanics at Penn State University. He received MSc in Optoelectronics from Electrotechnical University and Ph.D. in Physics & Mathematics at Ioffe Institute (St. Petersburg, Russia). Rotkin is an editor of 3 books and author of 190 papers and proceedings. Most recently, his work is focused on near-field optics and plasmonics, nano-biophysics, and 2D quantum materials. Rotkin mentored 30+ graduate students, 10+ postdoctoral fellows, 60+ undergraduates and a dozen of high-school students. Rotkin is recipient of several scientific awards, including Fellow of the Electrochemical Society, The Fulbright-Nehru Academic and Professional Excellence Award, The Japan Society for the Promotion of Science Fellowship, the Japan Gateway: Kyoto University Distinguished Professor, Hillman Award, Class of '68 Fellowship, Libsch Early Career Research Award, Feigl Junior Faculty Chair, and Beckman Fellowship

Hosted by: Lana Fulton,  lub18@psu.edu

Aerospace Engineering Seminar Series: Matthew Synborski

Thursday, February 5, 2026; 3:00pm-4:00pm
028 ECoRE
Speaker: Matt Synborski from Resilienx

Hosted by: Jessica Chhan,  jmc7050@psu.edu

Systems Engineering in the Silicon to Systems Era

Friday, February 6, 2026; 11:00am to 12:15pm
101 Electrical Engineering East
Speaker: Jayraj Nair, Ansys from

Intelligent systems of today are silicon powered, Software defined and AI Infused. Complexity of systems has substantially increased alongside reduced Time to market. Gone are the days where physical prototype was the gold standard and the product development cycle has become digital first in key industries. Complex systems of today introduce Multi-scale and Multi-physics challenges. Learn about Simulation engineering from Ansys that delivers the expertise, capabilities and tools to transform the design and development processes of most every industry. We empower Innovators to Drive Human Advancement.

BIOGRAPHY
Jayraj Nair is an avid Technologist, Systems Engineer and a Design Thinking practitioner. In the 90’s, early in his Infosys career he was instrumental in developing India’s first offshore software development Infrastructure and banking software Finacle. He has been bringing innovations to market for over 35yrs with a mix of leadership roles in Product Engineering and Professional Services. He developed products and solutions in companies like Intel, EMC-Dell and Microsoft and realized business outcomes for end users with Systems Integrators like Infosys and Wipro.

Jayraj is a computer engineer by training, and graduated with an MBA from ISU and MS from MIT while working full time. Jayraj maintains residences in San Francisco Bay Area, Seattle Washington and currently lives with family in Tokyo Japan. He is a team builder, continuous learner, a lifelong student who loves to ideate, incubate and teach. In his current role he leads Ansys (part of Synopsys) as Field CTO Hi-Tech and APAC from their Japan office.

Hosted by: Lyndsey Biddle,  lrb5765@psu.edu

Engineering Design Strategies for Safe and Resilient Housing

Wednesday, February 4, 2026; 121 Earth & Engineering Science Building
3:35-4:25 p.m.
Speaker: Esther Obonyo from Global Building Network, Dept. of Nuclear Engineering

Dr. Esther Obonyo is a professor of Engineering Design and Architectural Engineering at Penn State. She is an affiliate faculty in the Colleges of Medicine, Arts and Architecture, and African Studies program. Between 2019 and 2024, she was the director of the Global Building Network, a partnership with the United Nations. Before joining Penn State, she was an Associate Professor at the University of Florida's (UF) Rinker School of Construction Management and a faculty entrepreneurship Fellow at UF’s Warrington College of Business. She has worked as an Engineer, Project Manager, and Innovations Analyst in Kenya, the UK, and the US. In her collaborative research, Dr Obonyo is developing integrated research methodologies for enhancing the building sector’s resilience to flood and heat-related disasters in a way that unlocks human and health benefits. Since 2008, she has led several NSF-funded projects in Florida, Pennsylvania in the US, Kenya, Tanzania, Uganda, Mozambique, Brazil, and Panama. Dr Obonyo worked with the USAID as a Senior policy advisor through being awarded a 2014/ 2015 US Department of State Jefferson Science Fellow. She is the lead PI for a Belmont Forum project on Climate, Environment and Health. This project builds on the findings of a recently concluded Belmont Forum project on Disaster Risk Reduction.

Hosted by: Lana Fulton,  lub18@psu.edu

Aerospace Engineering Seminar Series: TBA

Thursday, February 12, 2026; 3:00pm-4:00pm
028 ECoRE
Speaker: from

Hosted by: Jessica Chhan,  jmc7050@psu.edu

Threading the Innovation Chain: Scaling and Manufacturing Deep Tech in the United States

Wednesday, February 11, 2026; 121 Earth & Engineering Science Building
3:35-4:25 p.m.
Speaker: Melik Demirel from Engineering Science and Mechanics

Prof. Demirel, Lloyd and Dorothy Huck Chair in Biomimetic Materials, is a scientist and innovator (National Academy of Innovators-NAI member) with expertise in biotechnology, nanotechnology, and materials science. He also founded a climatech company for decarbonizing textiles (Tandem Repeat, Inc.) Over the last two decades, Professor Demirel and his research team have focused on developing functional nanoscale biomimetic materials. His team designed, fabricated, and synthesized advanced materials by studying the functional transitions of biomimetic systems, both computationally and experimentally. Prof. Demirel's achievements have been recognized, in part, through his receipt of a Young Investigator Award from the Department of Defense, an Alexander von Humboldt Fellowship, a Wyss Institute Visiting Scholar at Harvard University, an Institute for Complex Adaptive Matter Junior Fellowship, The Nicholas and Gelsa Pelick Biotechnology Innovation Award and the Pearce Development Professorship, and a Penn State Engineering Alumni Society Outstanding Research Award. Prof. Demirel received his PhD from Carnegie Mellon University, Pittsburgh, USA, and BS/MS degrees from Bogazici University, Istanbul, Turkey. Prof. Demirel is well known for his ground-breaking work on bioinspired programmable materials.

Hosted by: Lana Fulton,  lub18@psu.edu

Aerospace Engineering Seminar Series: Erika Alvarez

Thursday, February 19, 2026; 3:00pm-4:00pm
028 ECoRE
Speaker: Erika Alvarez from

Hosted by: Jessica Chhan,  jmc7050@psu.edu

Walking and swimming and flying, oh my: the multimodal biomechanics and fluid dynamics of freshwater insects

Wednesday, February 18, 2026; 121 Earth & Engineering Science Building
3:35-4:25 p.m.
Speaker: Margaret Byron from Mechanical Engineering

Many animals, including humans, can transition between multiple modes of locomotion between diverse environments. Bimodality is common, but trimodality—that is, the ability to successfully navigate between aerial, aquatic, and terrestrial environments—is relatively rare. Multimodality is also challenging to achieve in engineered devices, vehicles, and robots—however, several animals are capable of regularly traversing these environmental boundaries. In this talk, we will outline several of the general adaptations that living organisms use to locomote between land, air, and water. We will then focus on recent research in the Environmental and Biological Fluid Mechanics Laboratory which focus on the biomechanics of aquatic insects, many of which are capable of walking, swimming, and flying within the same life stage. These insects exhibit hybrid walking-swimming gaits when transitioning from land to shallow water; they also leverage surface tension, buoyancy, fluid drag, and aerodynamic forces to take off into flight directly from the water surface. They also display underwater agility, using their legs as paddles to propel themselves rapidly as they seek prey and/or escape from predators. Interesting morphological features enabling these transitions include superhydrophobic wings and hemelytra, and dense setae lining the metathoracic legs which create shape-morphing appendages for efficient swimming. We will present data from all three locomotor modes and discuss their implications for both fundamental biology and ecology as well as bioinspired engineering and technology development.

Bio: Dr. Margaret L. Byron is currently the Martin W. Trethewey Early Career Professor in Mechanical Engineering at Penn State University, and is a recipient of the NSF CAREER Award, the Beckman Young Investigator Award, and the American Chemical Society Doctoral New Investigator Award. She earned her B.S. in Mechanical and Aerospace Engineering from Princeton University in 2010 and her MS/PhD in Civil and Environmental Engineering from the University of California Berkeley in 2012/2015. She works at the interface of biology, physics, and engineering, with interests including the fluid dynamics of animal locomotion and the transport of irregularly shaped inertial particles in turbulent flows (including sediment, aggregates, and microplastics)

Hosted by: Lana Fulton,  lub18@psu.edu