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Mechanical Engineering & Mechanics Open Access Journals

Our open access Journals in Mechanical Engineering & Mechanics cover topics such as Modelling and Simulation, Mechanical and Materials Engineering, Friction, Mechanics of Advanced Materials, and Visualization in Engineering, to name a few.  Find a list of all journals here: 

Advanced Modeling and Simulation in Engineering Sciences

The journal covers the vast domain of the advanced modeling and simulation of materials, processes, and structures governed by the laws of mechanics. 

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Chinese Journal of Mechanical Engineering

CJME mainly contains articles which study the basic theories and their applications in the field of mechanical engineering. 

The journal covers all aspects of theoretical and experimental research works related to friction, lubrication, wear, surface engineering and basic sciences. 

International Journal of Advanced Structural Engineering

The aim of the journal is to provide a unique forum for the publication and rapid dissemination of original research on structural engineering. 

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International Journal of Concrete Structures and Materials

The journal covers various topics related to concrete, concrete structures and other allied materials 

International Journal of Mechanical and Materials Engineering

The journal provides a forum for cross-disciplinary research contributions covering a broad spectrum of issues pertaining to the mechanical and machining properties of materials as well as materials science.

Mechanics of Advanced Materials and Modern Processes

The journal publishes results of current analytical, experimental and numerical research in the broad area of mechanics of advanced materials, with a special emphasis on underpinning interrelations between physics of deformation, damage, and fracture with mechanics of manufacturing processes. 

Micro and Nano Systems Letters

The journal offers an express online publication of short research papers containing the latest advances in micro and nano-scaled devices and systems.  

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Top 150 Mechanical Engineering Research Topics [Updated]

Mechanical engineering is an intriguing discipline that holds significant sway in shaping our world. With a focus on crafting inventive machinery and fostering sustainable energy initiatives, mechanical engineers stand as pioneers in driving technological progress. However, to make meaningful contributions to the field, researchers must carefully choose their topics of study. In this blog, we’ll delve into various mechanical engineering research topics, ranging from fundamental principles to emerging trends and interdisciplinary applications.

How to Select Mechanical Engineering Research Topics?

Table of Contents

Selecting the right mechanical engineering research topics is crucial for driving impactful innovation and addressing pressing challenges. Here’s a step-by-step guide to help you choose the best research topics:

• Identify Your Interests: Start by considering your passions and areas of expertise within mechanical engineering. What topics excite you the most? Choosing a subject that aligns with your interests will keep you motivated throughout the research process.
• Assess Current Trends: Stay updated on the latest developments and trends in mechanical engineering. Look for emerging technologies, pressing industry challenges, and areas with significant research gaps. These trends can guide you towards relevant and timely research topics.
• Conduct Literature Review: Dive into existing literature and research papers within your field of interest. Identify gaps in knowledge, unanswered questions, or areas that warrant further investigation. Building upon existing research can lead to more impactful contributions to the field.
• Consider Practical Applications: Evaluate the practical implications of potential research topics. How will your research address real-world problems or benefit society? Choosing topics with tangible applications can increase the relevance and impact of your research outcomes.
• Consult with Advisors and Peers: Seek guidance from experienced mentors, advisors, or peers in the field of mechanical engineering. Discuss your research interests and potential topics with them to gain valuable insights and feedback. Their expertise can help you refine your ideas and select the most promising topics.
• Define Research Objectives: Clearly define the objectives and scope of your research. What specific questions do you aim to answer or problems do you intend to solve? Establishing clear research goals will guide your topic selection process and keep your project focused.
• Consider Resources and Constraints: Take into account the resources, expertise, and time available for your research. Choose topics that are feasible within your constraints and align with your available resources. Balancing ambition with practicality is essential for successful research endeavors.
• Brainstorm and Narrow Down Options: Generate a list of potential research topics through brainstorming and exploration. Narrow down your options based on criteria such as relevance, feasibility, and alignment with your interests and goals. Choose the most promising topics that offer ample opportunities for exploration and discovery.
• Seek Feedback and Refinement: Once you’ve identified potential research topics, seek feedback from colleagues, advisors, or experts in the field. Refine your ideas based on their input and suggestions. Iteratively refining your topic selection process will lead to a more robust and well-defined research proposal.
• Stay Flexible and Open-Minded: Remain open to new ideas and opportunities as you progress through the research process. Be willing to adjust your research topic or direction based on new insights, challenges, or discoveries. Flexibility and adaptability are key qualities for successful research endeavors in mechanical engineering.

By following these steps and considering various factors, you can effectively select mechanical engineering research topics that align with your interests, goals, and the needs of the field.

Top 50 Mechanical Engineering Research Topics For Beginners

• Analysis of the efficiency of different heat exchanger designs.
• Optimization of airfoil shapes for enhanced aerodynamic performance.
• Investigation of renewable energy harvesting using piezoelectric materials.
• Development of smart materials for adaptive structures in aerospace applications.
• Study of vibration damping techniques for improving vehicle ride comfort.
• Design and optimization of suspension systems for off-road vehicles.
• Analysis of fluid flow characteristics in microchannels for cooling electronics.
• Evaluation of the performance of different brake systems in automotive vehicles.
• Development of lightweight materials for automotive and aerospace industries.
• Investigation of the effects of friction stir welding parameters on joint properties.
• Design and testing of a small-scale wind turbine for rural electrification.
• Study of the dynamics of flexible multibody systems in robotics.
• Development of a low-cost prosthetic limb using 3D printing technology.
• Analysis of heat transfer in electronic packaging for thermal management.
• Investigation of energy harvesting from vehicle suspension systems.
• Design and optimization of heat sinks for electronic cooling applications.
• Study of material degradation in composite structures under various loading conditions.
• Development of bio-inspired robotic mechanisms for locomotion.
• Investigation of the performance of regenerative braking systems in electric vehicles.
• Design and analysis of an autonomous agricultural robot for crop monitoring.
• Optimization of gas turbine blade profiles for improved efficiency.
• Study of the aerodynamics of animal-inspired flying robots (bio-drones).
• Development of advanced control algorithms for robotic manipulators.
• Analysis of wear mechanisms in mechanical components under different operating conditions.
• Investigation of the efficiency of solar water heating systems.
• Design and optimization of microfluidic devices for biomedical applications.
• Study of the effects of additive manufacturing parameters on part quality.
• Development of assistive devices for individuals with disabilities.
• Analysis of the performance of different types of bearings in rotating machinery.
• Investigation of the feasibility of using shape memory alloys in actuator systems.
• Design and optimization of a compact heat exchanger for space applications.
• Study of the effects of surface roughness on friction and wear in sliding contacts.
• Development of energy-efficient HVAC systems for buildings.
• Analysis of the performance of different types of fuel cells for power generation.
• Investigation of the feasibility of using biofuels in internal combustion engines.
• Design and testing of a micro-scale combustion engine for portable power generation.
• Study of the mechanics of soft materials for biomedical applications.
• Development of exoskeletons for rehabilitation and assistance in mobility.
• Analysis of the effects of vehicle aerodynamics on fuel consumption.
• Investigation of the potential of ocean wave energy harvesting technologies.
• Design and optimization of energy-efficient refrigeration systems.
• Study of the dynamics of flexible structures subjected to dynamic loads.
• Development of sensors and actuators for structural health monitoring.
• Analysis of the performance of different cooling techniques in electronics.
• Investigation of the potential of hydrogen fuel cells for automotive applications.
• Design and testing of a small-scale hydroelectric power generator.
• Study of the mechanics of cellular materials for impact absorption.
• Development of unmanned aerial vehicles (drones) for environmental monitoring.
• Analysis of the efficiency of different propulsion systems in space exploration.
• Investigation of the potential of micro-scale energy harvesting technologies for powering wireless sensors.

Top 50 Mechanical Engineering Research Topics For Intermediate

• Optimization of heat exchanger designs for enhanced energy efficiency.
• Investigating the effects of surface roughness on fluid flow in microchannels.
• Development of lightweight materials for automotive applications.
• Modeling and simulation of combustion processes in internal combustion engines.
• Design and analysis of novel wind turbine blade configurations.
• Study of advanced control strategies for unmanned aerial vehicles (UAVs).
• Analysis of wear and friction in mechanical components under varying operating conditions.
• Investigation of thermal management techniques for high-power electronic devices.
• Development of smart materials for shape memory alloys in actuator applications.
• Design and fabrication of microelectromechanical systems (MEMS) for biomedical applications.
• Optimization of additive manufacturing processes for metal 3D printing.
• Study of fluid-structure interaction in flexible marine structures.
• Analysis of fatigue behavior in composite materials for aerospace applications.
• Development of energy harvesting technologies for sustainable power generation.
• Investigation of bio-inspired robotics for locomotion in challenging environments.
• Study of human factors in the design of ergonomic workstations.
• Design and control of soft robots for delicate manipulation tasks.
• Development of advanced sensor technologies for condition monitoring in rotating machinery.
• Analysis of aerodynamic performance in hypersonic flight vehicles.
• Study of regenerative braking systems for electric vehicles.
• Optimization of cooling systems for high-performance computing (HPC) applications.
• Investigation of fluid dynamics in microfluidic devices for lab-on-a-chip applications.
• Design and optimization of passive and active vibration control systems.
• Analysis of heat transfer mechanisms in nanofluids for thermal management.
• Development of energy-efficient HVAC (heating, ventilation, and air conditioning) systems.
• Study of biomimetic design principles for robotic grippers and manipulators.
• Investigation of hydrodynamic performance in marine propeller designs.
• Development of autonomous agricultural robots for precision farming.
• Analysis of wind-induced vibrations in tall buildings and bridges.
• Optimization of material properties for additive manufacturing of aerospace components.
• Study of renewable energy integration in smart grid systems.
• Investigation of fracture mechanics in brittle materials for structural integrity assessment.
• Development of wearable sensors for human motion tracking and biomechanical analysis.
• Analysis of combustion instability in gas turbine engines.
• Optimization of thermal insulation materials for building energy efficiency.
• Study of fluid-structure interaction in flexible wing designs for unmanned aerial vehicles.
• Investigation of heat transfer enhancement techniques in heat exchanger surfaces.
• Development of microscale actuators for micro-robotic systems.
• Analysis of energy storage technologies for grid-scale applications.
• Optimization of manufacturing processes for lightweight automotive structures.
• Study of tribological behavior in lubricated mechanical systems.
• Investigation of fault detection and diagnosis techniques for industrial machinery.
• Development of biodegradable materials for sustainable packaging applications.
• Analysis of heat transfer in porous media for thermal energy storage.
• Optimization of control strategies for robotic manipulation tasks in uncertain environments.
• Study of fluid dynamics in fuel cell systems for renewable energy conversion.
• Investigation of fatigue crack propagation in metallic alloys.
• Development of energy-efficient propulsion systems for unmanned underwater vehicles (UUVs).
• Analysis of airflow patterns in natural ventilation systems for buildings.
• Optimization of material selection for additive manufacturing of biomedical implants.

Top 50 Mechanical Engineering Research Topics For Advanced

• Development of advanced materials for high-temperature applications
• Optimization of heat exchanger design using computational fluid dynamics (CFD)
• Control strategies for enhancing the performance of micro-scale heat transfer devices
• Multi-physics modeling and simulation of thermoelastic damping in MEMS/NEMS devices
• Design and analysis of next-generation turbofan engines for aircraft propulsion
• Investigation of advanced cooling techniques for electronic devices in harsh environments
• Development of novel nanomaterials for efficient energy conversion and storage
• Optimization of piezoelectric energy harvesting systems for powering wireless sensor networks
• Investigation of microscale heat transfer phenomena in advanced cooling technologies
• Design and optimization of advanced composite materials for aerospace applications
• Development of bio-inspired materials for impact-resistant structures
• Exploration of advanced manufacturing techniques for producing complex geometries in aerospace components
• Integration of artificial intelligence algorithms for predictive maintenance in rotating machinery
• Design and optimization of advanced robotics systems for industrial automation
• Investigation of friction and wear behavior in advanced lubricants for high-speed applications
• Development of smart materials for adaptive structures and morphing aircraft wings
• Exploration of advanced control strategies for active vibration damping in mechanical systems
• Design and analysis of advanced wind turbine blade designs for improved energy capture
• Investigation of thermal management solutions for electric vehicle batteries
• Development of advanced sensors for real-time monitoring of structural health in civil infrastructure
• Optimization of additive manufacturing processes for producing high-performance metallic components
• Investigation of advanced corrosion-resistant coatings for marine applications
• Design and analysis of advanced hydraulic systems for heavy-duty machinery
• Exploration of advanced filtration technologies for water purification and wastewater treatment
• Development of advanced prosthetic limbs with biomimetic functionalities
• Investigation of microscale fluid flow phenomena in lab-on-a-chip devices for medical diagnostics
• Optimization of heat transfer in microscale heat exchangers for cooling electronics
• Development of advanced energy-efficient HVAC systems for buildings
• Exploration of advanced propulsion systems for space exploration missions
• Investigation of advanced control algorithms for autonomous vehicles in complex environments
• Development of advanced surgical robots for minimally invasive procedures
• Optimization of advanced suspension systems for improving vehicle ride comfort and handling
• Investigation of advanced materials for 3D printing in aerospace manufacturing
• Development of advanced thermal barrier coatings for gas turbine engines
• Exploration of advanced wear-resistant coatings for cutting tools in machining applications
• Investigation of advanced nanofluids for enhanced heat transfer in cooling applications
• Development of advanced biomaterials for tissue engineering and regenerative medicine
• Exploration of advanced actuators for soft robotics applications
• Investigation of advanced energy storage systems for grid-scale applications
• Development of advanced rehabilitation devices for individuals with mobility impairments
• Exploration of advanced materials for earthquake-resistant building structures
• Investigation of advanced aerodynamic concepts for reducing drag and improving fuel efficiency in vehicles
• Development of advanced microelectromechanical systems (MEMS) for biomedical applications
• Exploration of advanced control strategies for unmanned aerial vehicles (UAVs)
• Investigation of advanced materials for lightweight armor systems
• Development of advanced prosthetic interfaces for improving user comfort and functionality
• Exploration of advanced algorithms for autonomous navigation of underwater vehicles
• Investigation of advanced sensors for detecting and monitoring air pollution
• Development of advanced energy harvesting systems for powering wireless sensor networks
• Exploration of advanced concepts for next-generation space propulsion systems.

Mechanical engineering research encompasses a wide range of topics, from fundamental principles to cutting-edge technologies and interdisciplinary applications. By choosing the right mechanical engineering research topics and addressing key challenges, researchers can contribute to advancements in various industries and address pressing global issues. As we look to the future, the possibilities for innovation and discovery in mechanical engineering are endless, offering exciting opportunities to shape a better world for generations to come.

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Posted on Feb 16, 2023 We are now seeking submissions for Vol. 11, No. 1, 2023 issue. Please find the journal’s profile at http://mer.ccsenet.org and submit your manuscripts online. You may also e-mail submissions to... Read More

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UMass Amherst Engineers Create Bioelectronic Mesh Capable of Growing with Cardiac Tissues for Comprehensive Heart Monitoring

This story was originally published by the UMass News Office.

A team of engineers led by the University of Massachusetts Amherst and including colleagues from the Massachusetts Institute of Technology (MIT) recently announced in the journal Nature Communications that they had successfully built a tissue-like bioelectronic mesh system integrated with an array of atom-thin graphene sensors that can simultaneously measure both the electrical signal and the physical movement of cells in lab-grown human cardiac tissue. In a research first, this tissue-like mesh can grow along with the cardiac cells, allowing researchers to observe how the heart’s mechanical and electrical functions change during the developmental process. The new device is a boon for those studying cardiac disease as well as those studying the potentially toxic side-effects of many common drug therapies.

Cardiac disease is the leading cause of human morbidity and mortality across the world. The heart is also very sensitive to therapeutic drugs, and the pharmaceutical industry spends millions of dollars in testing to make sure that its products are safe. However, ways to effectively monitor living cardiac tissue are extremely limited.

In part, this is because it is very risky to implant sensors in a living heart, but also because the heart is a complex kind of muscle with more than one thing that needs monitoring. “Cardiac tissue is very special,” says Jun Yao , associate professor of electrical and computer engineering in UMass Amherst’s College of Engineering and the paper’s senior author. “It has a mechanical activity—the contractions and relaxations that pump blood through our body—coupled to an electrical signal that controls that activity.” 

But today’s sensors can typically only measure one characteristic at a time, and a two-sensor device that could measure both charge and movement would be so bulky as to impede the cardiac tissue’s function. Until now, there was no single sensor capable of measuring the heart’s dual properties without interfering with its functioning.

The new device is built of two critical components, explains lead author Hongyan Gao, who is pursuing his Ph.D. in electrical engineering at UMass Amherst. The first is a three-dimensional cardiac microtissue (CMT), grown in a lab from human stem cells under the guidance of co-author Yubing Sun, associate professor of mechanical and industrial engineering at UMass Amherst. CMT has become the preferred model for in vitro testing because it is the closest analog yet to a full-size, living human heart. However, because CMT is grown in a test tube, it has to mature, a process that takes time and can be easily disrupted by a clumsy sensor.

The second critical component involves graphene—a pure-carbon substance only one atom thick. Graphene has a few surprising quirks to its nature that make it perfect for a cardiac sensor. Graphene is electrically conductive, and so it can sense the electrical charges shooting through cardiac tissue. It is also piezoresistive, which means that as it is stretched—say, by the beating of a heart—its electrical resistance increases. And because graphene is impossibly thin, it can register even the tiniest flutter of muscle contraction or relaxation and can do so without impeding the heart’s function, all through the maturation process. Co-author Jing Kong, professor of electrical engineering at MIT, and her group supplied this critical graphene material. 

Gao, Yao and their colleagues then embedded a series of graphene sensors in a soft, stretchable porous mesh scaffold they developed that has close structural and mechanical properties to human tissue and which can be applied non-invasively to cardiac tissue.

“No one has ever done this before,” says Gao. “Graphene can survive in a biological environment without degrading for a very long time and not lose its conductivity, so we can monitor the CMT across its entire maturation process.”

“This is crucial for a number of reasons,” adds Yao. “Our sensor can give real-time feedback to scientists and drug researchers, and it can do so in a cost-effective way. We take pride in using the insights of electrical engineering to help build tools that can be useful to a wide range of researchers.”

In the future, Gao says, he hopes to be able to adapt his sensor to grander scales, even to in vivo monitoring, which would provide the best-possible data to help solve cardiac disease. 

This research was supported by the Army Research Office, the National Institutes of Health, the U.S. National Science Foundation, the Semiconductor Research Corporation, and the Link Foundation, as well as the Institute for Applied Life Sciences at UMass Amherst.

Nanoelectronic devices and sensors, Bioelectronic interfaces and wearable devices, 'Green' electronics made from biomaterials.

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