in engineering thesis

MS in Mechanical Engineering - Thesis Guidelines

Students may choose to pursue a thesis as part of their MS degree program, but only with the consent of a faculty advisor willing to supervise the thesis work. 

Preparation of a thesis representing an independent research work is a pivotal phase of this MS degree program. It provides the student with an opportunity to work on an open-ended problem, developing a particular solution that is not pre-determined and involving synthesis of knowledge and intellectual creativity. The thesis may involve an investigation that is fundamental in nature, or may be applied, incorporating theory, experimental testing and/or analytical modeling, and/or creative design. Through the thesis, candidates are expected to give evidence of competence in research and a sound understanding of the area of specialization involved. Students are also strongly encouraged to present their research at scientific conferences and publish the results of their thesis research in a peer-reviewed journal.

Students receive a grade of Y (incomplete) in these courses as long as the thesis in progress. Eventual thesis grades replace the incomplete grades upon formal completion of the thesis. In order to receive a grade of Y for ME-0296, students must submit a  thesis prospectus  that outlines the area of work, thesis goals, proposed approach and a review of relevant past work in the literature before the end of the first semester in which the student enrolls in ME-0296, typically the third semester of full-time study. An example of a recent MS thesis prospectus can be found in the Mechanical Engineering office.

The examining committee for MS candidates completing theses should be composed of three (3) members.

• Thesis advisor (committee chair)
• One technical expert outside of the ME department
• A third member of the committee, often another faculty member in the ME department

The committee chair is normally a full-time, tenure-track faculty member. One committee member must be from outside the ME department. Thesis normally counts as 9 credits towards the MS degree requirements. However, a student, with the approval of his/her thesis advisor, has the option to complete a 6-credit thesis by submitting a petition form to the Department. This petition must be signed by the student and the thesis advisor and will become part of the student's academic record. With a 6-credit thesis, a student must complete an extra graduate-level course (for a total of 8 courses) to fulfill the 30-credit requirement for graduation. This option is not typically available to those intending to pursue a Ph.D. degree. 

Thesis Completion

The MS thesis is completed upon:

• A successful oral defense (open to the community)
• Submittal of an approved thesis to the Office of Graduate Studies

The student should consult the  Graduate Student Handbook  for specific dates and deadlines for this process in the graduation semester.

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Civil Engineering Masters Theses Collection

Theses from 2024 2024.

Machine and Statistical Learning for Sustainable Infrastructure and Mobility Systems , Atanas Apostolov, Civil Engineering

Theses from 2023 2023

The Current State of Practice of Building Information Modeling , Kevin P. Brooks, Civil Engineering

Loads Analysis of Fixed-Bottom and Floating Offshore Wind Structures , Michael G. Davis, Civil Engineering

Comparison Of Scaling Performance Between Sidewalks Placed Using Hot and Cold Weather Concreting Procedures , Likhitha Rudraraju, Civil Engineering

CORRELATION BETWEEN LABORATORY TESTING RESULTS AND IN-SITU SIDEWALK SCALING , Brian R. Shea, Civil Engineering

The Effects of Hurricane Wind Field Characteristics on Wind Blade Loads , Michael S. Tsai, Civil Engineering

Post-Fire Damage Inspection of Concrete Tunnel Structures , James Viglas, Civil Engineering

Theses from 2022 2022

Measuring Accessibility to Food Services to Improve Public Health , Efthymia Kostopoulou, Civil Engineering

Euplectella Aspergillum’s Natural Lattice Structure for Structural Design & Stability Landscape of Thin Cylindrical Shells with Dimple Imperfections , Zoe Y. Sloane, Civil Engineering

Theses from 2021 2021

Post-Fire Assessment of Concrete Tunnel Structures , Nicholas C. Menz, Civil Engineering

Utilizing Unmanned Aerial Vehicles (UAVs) for the Estimation of Beam Corrosion of Steel Bridge Girders , Gabrielle Pryor, Civil Engineering

Parametric Study of Integral Abutment Bridge Using Finite Element Model , Asako Takeuchi, Civil Engineering

Theses from 2020 2020

School Bus Routing To Allow Later School Start Times , Rana Eslamifard, Civil Engineering

QUANTIFICATION OF THERMAL BRIDGING EFFECTS IN COLD-FORMED STEEL WALL ASSEMBLIES , Divyansh Kapoor, Civil Engineering

Theses from 2019 2019

Sustainable Travel Incentives Optimization in Multimodal Networks , Hossein Ghafourian, Civil Engineering

High Fidelity Modeling of Cold-Formed Steel Single Lap Shear Screw Fastened Connections , Rita Kalo, Civil Engineering

Modeling the Effect of New Commuter Bus Service on Demand and the Impact on GHG Emissions: Application to Greater Boston , Christopher Lyman, Civil Engineering

Performance of Concrete Tunnel Systems Subject to Fault Displacement , Michael Morano, Civil Engineering

Behavior of Prestressed Concrete Bridges with Closure Pour Connections and Diaphragms , Gercelino Ramos, Civil Engineering

Analysis of Adhesive Anchorage Systems Under Extreme In-Service Temperature Conditions , Rachel Wang, Civil Engineering

Theses from 2018 2018

Driver Understanding of the Flashing Yellow Arrow and Dynamic No Turn on Red Sign for Right Turn Applications , Elizabeth Casola, Civil Engineering

Evaluating the Impact of Double-Parked Freight Deliveries on Signalized Arterial Control Delay Using Analytical Models and Simulation , Aaron J. Keegan, Civil Engineering

Reward Allocation For Maximizing Energy Savings In A Transportation System , Adewale O. Oduwole, Civil Engineering

Impact of S-Curve on Speed in a Modern Roundabout , Akshaey Sabhanayagam, Civil Engineering

All-Red Clearance Intervals for Use in the Left-Turn Application of Flashing Yellow Arrows , Francis Tainter, Civil Engineering

Theses from 2017 2017

Evaluation of New England Bridges for Bat Roosting Including Methodology and Case Studies , Angela Berthaume, Civil Engineering

Evaluating Variances Between Departments of Transportation in New England to Create a Strategic Transportation Workforce , Chelsea Bouchard, Civil Engineering

Development of High Early-Strength Concrete for Accelerated Bridge Construction Closure Pour Connections , Stephanie Castine, Civil Engineering

I. THE HIGH STRAIN RATE RESPONSE OF HOLLOW SPHERE STEEL FOAM; II. THE DYNAMIC RESPONSE OF AN AMERICAN ELM TREE , Ignacio Cetrangolo, Civil Engineering

Performance of Adhesive and Cementitious Anchorage Systems , Mirna Mendoza, Civil Engineering

Theses from 2016 2016

Integrated Solar Technologies with Outdoor Pedestrian Bridge Superstructure Decking , Richard K. Racz, Civil Engineering

LIVE LOAD DISTRIBUTION FACTORS FOR HORIZONTALLY CURVED CONCRETE BOX GIRDER BRIDGES , Mohammed Zaki, Civil Engineering

Theses from 2015 2015

Bonded Anchors in Concrete Under Sustained Loading , Douglas Droesch, Civil Engineering

An Observational Evaluation of Safety Resulting from Driver Distraction , Christina M. Dube, Civil Engineering

Measuring the Resilience of Transportation Networks Subject to Seismic Risk , Mark N. Furtado, Civil Engineering

Nano-Scale Investigation of Mechanical Characteristics of Main Phases of Hydrated Cement Paste , Shahin Hajilar, Civil Engineering

Driver Behavior Evaluation of Variable Speed Limits and a Conceptual Framework for Optimal VSL Location Identification , Curt P. Harrington, Civil Engineering

A Real-time Signal Control System to Minimize Emissions at Isolated Intersections , Farnoush Khalighi, Civil Engineering

Structural Vulnerability Assessment of Bridge Piers in the Event of Barge Collision , David A. Ribbans, Civil Engineering

Towards Sustainable Roundabouts: An Evaluation of Driver Behavior, Emissions, and Safety , Derek Roach, Civil Engineering

Resilience of Transportation Infrastructure Systems to Climatic Extreme Events , Alexandra C. Testa, Civil Engineering

Theses from 2014 2014

Short and Long-term Performance of a Skewed Integral Abutment Prestressed Concrete Bridge , Rami Bahjat, Civil Engineering

Performance of Circular Reinforced Concrete Bridge Piers Subjected to Vehicular Collisions , Nevin L. Gomez, Civil Engineering

Field and Analytical Studies of the First Folded Plate Girder Bridge , Man Hou Sit, Civil Engineering

Theses from 2013 2013

The Effect of Roadside Elements on Driver Behavior and Run-Off-the-Road Crash Severity , Cole D. Fitzpatrick, Civil Engineering

Evaluating At-Grade Rail Crossing Safety along the Knowledge Corridor in Massachusetts , Timothy P. Horan, Civil Engineering

An Evaluation of Alternative Technologies to Estimate Travel Time on Rural Interstates , Qiao Li, Civil Engineering

Operational and Safety-based Analyses of Varied Toll Lane Configurations , Ian A. Mckinnon, Civil Engineering

Preferred Sensor Selection for Damage Estimation in Civil Structures , Matthew Styckiewicz, Civil Engineering

An Evaluation of Drivers’ Cell Phone Use Prevalence and Safety Related Impacts , Keith E. Wenners, Civil Engineering

Theses from 2012 2012

Probabilistic Analysis of Offshore Wind Turbine Soil-Structure Interaction , Wystan Carswell, Civil Engineering

Vehicle Miles Traveled (vmt) Fee Financing Alternatives: Lessons Learned and Future Opportunities , Ashley L. Costa, Civil Engineering

Evaluating and Modeling Traveler Response to Real-Time Information in the Pioneer Valley , Tyler De Ruiter, Civil Engineering

An Optimal Adaptive Routing Algorithm for Large-scale Stochastic Time-Dependent Networks , Jing Ding, Civil Engineering

A Quantitative Analysis of the Impacts from Selected Climate Variables Upon Traffic Safety in Massachusetts , Katrina M. Hecimovic, Civil Engineering

Automated Enforcement Using Dedicated Short Range Communication , Gilbert Kim, Civil Engineering

New Technologies in Short Span Bridges: A Study of Three Innovative Systems , Andrew Lahovich, Civil Engineering

Driver Dynamics and the Longitudinal Control Model , Gabriel G. Leiner, Civil Engineering

Interfacial Strength Between Prestressed Hollow Core Slabs and Cast-in-Place Concrete Toppings , Ryan M. Mones, Civil Engineering

User Equilibrium in a Disrupted Network with Real-Time Information and Heterogeneous Risk Attitude , Ryan J. Pothering, Civil Engineering

Spatial and Temporal Correlations of Freeway Link Speeds: An Empirical Study , Piotr J. Rachtan, Civil Engineering

Evaluation of Live-Load Distribution Factors (LLDFs) of Next Beam Bridges , Abhijeet Kumar Singh, Civil Engineering

Material Characterization and Computational Simulation of Steel Foam for Use in Structural Applications , Brooks H. Smith, Civil Engineering

Varied Applications of Work Zone Safety Analysis through the Investigation of Crash Data, Design, and Field Studies , Erica Swansen, Civil Engineering

Using Micro-Simulation Modeling to Evaluate Transit Signal Priority in Small-to-Medium Sized Urban Areas; Comparative Review of Vissim and S-Paramics Burlington, Vermont Case Study , Joseph C. Tyros, Civil Engineering

Theses from 2011 2011

Evaluating Alternative Toll-Based Financing Approaches: A Case Study of the Boston Metropolitan Area , Rosaria M. Berliner, Civil Engineering

Analysis of Measurement Errors Influence on the Quantitative and Qualitative Results of Car-Following Model Calibration , Mariya A. Maslova, Civil Engineering

Development of Anchorage System for Frp Strengthening Applications Using Integrated Frp Composite Anchors , Geoffrey N. Mcguirk, Civil Engineering

An Application of Spatially Based Crash Analyses and Road Safety Investigations to Increase Older Driver Safety , Deanna A. Peabody, Civil Engineering

Safety and Operational Assessment of Gap Acceptance Through Large-Scale Field Evaluation , Steven Maxwell Tupper, Civil Engineering

Theses from 2010 2010

Historic Bridge Evaluation Using Finite Element Techniques , Helena M. Charron, Civil Engineering

A Quantitative Analysis of the Impacts from Selected Variables Upon Safety Belt Usage in Massachusetts , Samuel W. Gregorio, Civil Engineering

Analysis of Curved Integral Abutment Bridges , Emre Kalayci, Civil Engineering

Material Characterization and Structural Response of Historic Truss Bridges , Sean L. Kelton, Civil Engineering

Earthquake Engineering Simulation with Flexible Cladding System , Jun Jie Li, Civil Engineering

Route Choice Behavior in Risky Networks with Real-Time Information , Michael D. Razo, Civil Engineering

Route Choice Behavior in a Driving Simulator With Real-time Information , Hengliang Tian, Civil Engineering

Investigation of the Behavior of Open Cell Aluminum Foam , Patrick J. Veale, Civil Engineering

Theses from 2009 2009

Computer-Assisted Emergency Evacuation Planning Using TransCAD: Case Studies in Western Massachusetts , Steven P. Andrews, Civil Engineering

Value of Traveler Information for Adaptive Routing in Stochastic Time-Dependent Networks , He Huang, Civil Engineering

Analytical Modeling of Tree Vibration Generated during Cutting Process , Payman Karvanirabori, Civil Engineering

Optimal Adaptive Departure Time Choices with Real-Time Traveler Information Considering Arrival Reliability , Xuan Lu, Civil Engineering

Seismic Energy Dissipation of Steel Buildings Using Engineered Cladding Systems , Quan Viet Nguyen, Civil Engineering

Developing an Evaluation Approach to Assess Large Scale Its Infrastructure Improvements: I-91 Project , Melissa Paciulli, Civil Engineering

Enhancing Concrete Barrier Reflectivity With A Focus On Recycled Glass Aggregate Replacement , Regina Shklyan, Civil Engineering

Theses from 2008 2008

Performance Evaluation Of Existing Steel And Concrete Girder Bridges Through Non-destructive Live-load Testing , Andrew E. Jeffrey, Civil Engineering

Evaluation of Traffic Simulation Models for Work Zones in the New England Area , Pothu Raju Khanta, Civil Engineering

The Application of Traffic Calming and Related Strategies in an Urban Environment , Stacy A. Metzger, Civil Engineering

Terrazzo Cracking: Causes and Remedies , Michael J. Mitchell III, Civil Engineering

Anchorage of Carbon Fiber Reinforced Polymers to Reinforced Concrete in Shear Applications , Carl W. Niemitz, Civil Engineering

Measurement and Computational Modeling of the Mechanical Properties of Parallel Strand Lumber , Russell S. Winans, Civil Engineering

An Evaluation of Simulation Models To Assess Travel Delay In Work Zones , Fan Wu, Civil Engineering

Theses from 2007 2007

An Analysis Of The Saftey Effects Of Crosswalks With In-pavement Warning Lights , George Gadiel, Civil Engineering

The Development of a Dynamic-Interactive-Vehicle Model for Modeling Traffic Beyond the Microscopic Level , Dwayne A. Henclewood, Civil Engineering

A Comparative Evaluation of Crash Data Quality Identification Methods , Arianna M. Mickee, Civil Engineering

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Thesis Proposal

Note: This article is partially based on the 2017-2018 MechE Graduate Student Guide (PDF) . Please check the latest guide for the most-up to date formatting requirements.

Criteria for Success

A strong thesis proposal…

• Motivates your project and introduces your audience to the state-of-the-art for the problem you’re working on.
• Explains the limitations in the current methods through literature review and/or original analysis. This should also explain why the limitations matter and why they’re the right ones to focus on.
• Clearly explains your technical approach to make specific improvements to some part of the field.
• Uses original analysis and literature to support the feasibility of the approach.
• Describes what is original about your work.
• Provides a practical outline for completing this research : a degree timeline laying out quantifiable hypotheses, experimental/numerical/theoretical techniques, and metrics for evaluation .

Structure Diagram

Meche-specific structure requirements.

Your thesis proposal should be limited to 6 pages including figures and references.

In addition, you need a cover page that (only) includes:

• tentative title of the thesis
• brief abstract
• committee chair and/or advisor should be indicated
• include their official titles, departmental affiliations, and email addresses

The purpose of your thesis proposal is to introduce your research plan to your thesis committee. You want the committee members to come away understanding what your research will accomplish, why it is needed ( motivation ), how you will do it ( feasibility & approach ), and most importantly, why it is worthy of a PhD ( significance ).

You intend to solve a real and important problem, and you are willing to dedicate years of your life to it, so use your proposal to get the committee excited about your research!

Analyze your audience

Unlike many of the papers and presentations you will write during graduate school, only a select few people will read your thesis proposal. This group will always include your PhD committee and your research advisor, and may include other interested MechE faculty or scientists and engineers at your funding source.

Therefore, you will typically have a good understanding of your audience before it is written. This can allow you to tailor your message to the technical level of your specific audience. If you aren’t sure what your audience could reasonably be expected to know, be conservative! Regardless, your audience is always looking to answer the questions: “ what is this research, how will you perform it, and why does it matter?”

While the small audience may make you less interested in committing time to your proposal, the exercise of motivating and justifying your work plan will be critical to your PhD.

Follow the standard structure for research proposals

While some variation is acceptable, don’t stray too far from the following structure. See also the Structure Diagram above.

• Introduction . Provide only the necessary information to motivate your research, and show how it fits into the broader field. What is the problem you are trying to solve? By the end of the introduction, your audience should understand the basics of what you will do and why you will do it.
• Background/Methodology . Describe the current state of the art and related research fields in sufficient technical detail. The goal is provide just enough detail to give the reader a sound understanding of the limitations and the need for new work. Do not go into detail that does not directly help in understanding your You are not trying to make your reader understand everything about the topic or demonstrate how much you know.
• Objectives . Although not strictly necessary, this section lets you summarize concrete goals of your work, and can help to serve as a checklist for yourself as you move through the process. This is best for projects that tackle many interrelated problems. Think of this as a list of concrete (quantifiable) goals that you want to accomplish.
• Proposed Work. Explain how your work will solve the problems that you have identified. How will you address the objectives above? Provide just enough technical specificity to leave the reader with a firm grasp of what you will do.
• Provide a set of time-structured goals and deliverables. While this is not strictly necessary, your committee will want a timeline when you meet with them, so it can help to start planning now. You want to graduate, so make sure that you have a plan to do so!
• This is a standard section listing references in an appropriate format (MLA, APA, etc.)

Consider the logical sequence of your sections. After the introduction, your audience should be intrigued by a key problem, and intrigued that you know how to solve it. Through the background, they learn that this problem is more difficult than they originally realized. Finally, in the proposed work they learn that your proposal addresses the additional complexity introduced in the background, and they have confidence that you can actually solve the problem.

Summarize the current research field

You need to have a strong grasp of the broader research community. How can you contribute, if you don’t know what is done and what needs to be done?

The point here is not to educate your audience, but rather to provide them with the tools needed to understand your proposal. A common mistake is to explain all of the research that you did to understand your topic and to demonstrate that you really know your field. This will bore your audience, who either already knows this information or does not see why they should care. It’s more important to show where current gaps are. Cut anything that doesn’t answer the what and why of what people are doing. Your depth of knowledge will come through in your thoughtful proposal.

Justify the significance of your work

Answer the question: “What happens if your work is successful?” Again, you are trying to convince your readers either to give you funding or to work with you for three (or more) years. Convince them that your project is worth it.

Your research doesn’t have to revolutionize your field, but you need to explain concretely how it will move your field forward. For example, “Successful development of the proposed model will enable high-fidelity simulation of boiling” is a specific and convincing motivation, compared to, “The field of boiling modeling must be transformed in order to advance research.”

Justify your research plan

Identify the steps needed to overcome your identified problem/limitation. Though your PhD will evolve over time, the tasks and timeline that you identify in your proposal will continue to help determine the trajectory of your research. A good plan now can save a lot of work a few years down the road.

A strong research plan answers three key questions:

• g., “In order to engineer material properties using mesoscopic defects, it is necessary to characterize the defects, measure how they affect material response, and identify techniques to reproducibly create the defects at specific sites within a material.”
• g., “In my PhD, I will focus on developing high-speed dynamic imaging techniques to characterize transient defect states in metallic nanowires. I will then use these techniques to measure the properties of nanowires fabricated with three different processes known to produce different defect structures.”
• How will you evaluate success in each step? These metrics should be concrete and measurable! Putting the thought into metrics now will make it easier for your committee (and yourself) to check a box and say ‘you can graduate.’

Each of these questions should be supported by details that reflect the current state of the art. Technical justification is critical to establish credibility for your plan. Reference the material that you introduced in the background section. You should even use your research plan to tailor your background section so that your committee knows just enough to believe what you’re claiming in your plan.

Based on the tasks and metrics in your plan, establish specific reflection points when you’ll revisit the scope of your project and evaluate if changes are needed.

Include alternative approaches

You won’t be able to predict all of the challenges you will encounter, but planning alternative approaches early on for major methods or decision points will prepare you to make better game-time decisions when you come up against obstacles. e.g.,

I will develop multi-pulse, femtosecond illumination for high speed imaging following Someone et al. Based on the results they have shown, I expect to be able to observe defect dynamics with micron spatial resolution and microsecond temporal resolution. If these resolutions are not achievable in the nanowire systems, I will explore static measurement techniques based on the work of SomeoneElse et al.

Resources and Annotated Examples

Annotated example 1.

This is a recent MechE thesis proposal, written in the style of an IEEE paper. 1,022 KB

Master's Thesis Program Overview - School of Industrial Engineering - Purdue University

Program Overview

The Master's degree with a thesis option allows students to work with world-renowned faculty to dig deeper in an area of interest. The development of a thesis involves utilizing the knowledge gained in a sub-field of study (e.g., human factors) to a novel engineering problem. In addition, students deepent their competence in surveying cutting-edge research, leading a project independently, design (especially in emerging fields), and communication. 

A thesis is a major undertaking, requiring deep interest in the subject matter and a close relationship with the faculty member supervising the research. Prospective students are encouraged to consider the research profiles of IE faculty, including recent publications, to determine program fit. Pursuing a thesis-option Master's degree is often a step toward pursuing a Doctor of Philosophy degree, and may be required for admission to some doctoral programs. However, the skills gained through completing a thesis-option Master's program still are highly sought after in industry. Students who intend to earn the doctoral degree must pursue this option. 

Prospective Thesis Master's students are encouraged to consult with faculty members with whom their interests align prior to applying for admission.  You can learn about our  research areas and the faculty doing work in them here , and can directly peruse faculty profiles via our  IE Faculty Directory .

ProgramHighlights 

• Ranking . Consistently ranked in the top #10 by U.S. News & World Report (April 2023).
• Enrollment & Statistics . A total of 9407 students from abroad, representing 127* countries and 1514 international faculty and staff representing 84* nations, claim Purdue University as their home this fall semester.
• Two-year program:  Students complete a combination of advanced technical courses, focusing their studies on areas of interest, culminating in a Master of Science in Industrial Engineering degree.
• Career Catalyzation:  Graduates pursue diverse careers, often on advanced leadership tracks.
• Degree Requirements:  Courses selected for the thesis option are intended to provide in-depth study in a specific area of interest. Prerequisites ensure a minimum level of knowledge in the general field of industrial engineering. The curriculum allows for significant student choice in coursework, which should be made in consultation with the faculty member supervising the research project to ensure alignment with the research topic.
• Human Factors Engineering
• Manufacturing Systems Engineering
• Operational Research (Mathematical Programming; Simulation & Stochastic Processes)
• Production Systems Engineering
• Thesis/Defense:  Development of a thesis document meeting all requirements of the faculty and Graduate School, followed by a successful oral defense of the thesis before a committee of faculty members.

Why Industrial Engineering?

Increased Employment Opportunities:  A master's thesis degree is traditionally for students planning to continue in research or academia. However, this research-focused program also equips students with technical skills highly sought after in industry, such as decision making, systems engineering, operations, and oral and written communications.

Increased Earning Potential:  Purdue Industrial Engineering Master's graduates report earning 15% or more than their peers with a Bachelor's degree.

Field Defining Innovation & Research:  The School of Industrial Engineering has been shaping the field and educating future leaders in industrial engineering for 65 years. The graduate program is ranked in the top 10, and the IE online degree program is ranked #1 in the nation. Our researchers conduct field-defining research that is recognized worldwide for its impact and quality.

Excellence at Scale:  As one of the top 10 engineering graduate programs in the nation, Purdue's College of Engineering is one of the largest and strongest programs in the nation with 13 different schools and departments.

Affordable Tuition:  Our program's tuition is significantly cost-effective compared to other programs.

Low Cost of Living:  The cost of living in the Greater Lafayette-West Lafayette area is among the lowest in the nation, with housing rent ranging from 23% to 179% less expensive than competing university cities (numbeo.com).

Funding Resources: There are several funding options for Purdue graduate students to explore, including  assistantships ,  fellowships ,  grants ,  loans and other financial aid . Financial support for graduate students at Purdue is primarily awarded in the form of assistantships and fellowships. Over 60 percent of graduate students at the University are on assistantships. Furthermore, the Fellowship Office hosts many  resources  for students applying for fellowships.

Most funding decisions for assistantships are made by each individual graduate program. 

Degree Requirements 

Minimum 30 Total Credit Hours

• 21 credit hours of coursework
• At least 12 credit hours must come from IE-listed courses
• A maximum of 9 credit hours of master's thesis research credits (IE 69800)
• Advisory committee
• Development of a thesis document meeting all requirements of the faculty and Graduate School
• Successful defense of the thesis through an oral examination to a committee of faculty members

Graduate Program Student Guide : New, Returning & Online Student Resources, Plan of Study & Course Requirements for Master's Thesis , Final Examination Guidelines for Master's Thesis , Completion Guidelines for Master's Thesis , Academic Calendars, and more

Tuition & Fees

See  Graduate Tuition and Fees  for access to detailed information regarding Purdue tuition, rates and fees for graduate students, including summer, fall/spring and winter rate information as well as other case-specific fees that may not be included with the seasonal fee information.

Application Requirements

Prospective Student Events

Contact 

IE Graduate Office: [email protected]

Heather Bagshaw

Sr. Graduate Program Administrator

+1 765 494-0680

[email protected]

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Undergraduate thesis

Undergraduate Thesis

UNSW Engineering students are required to complete an undergraduate thesis project during the 4th year of their study. Students can choose from a variety of projects, with research and industry thesis options available. The standard thesis is 4 UoC (Unit of Credit) per term starting T1, T2 or T3.

You’ll enrol Thesis A, Thesis B and Thesis C and complete the thesis across three consecutive terms. Once Thesis A is taken, Thesis B and Thesis C must be taken consecutively in the two terms that follow.

Your school may also offer the option to complete a practice thesis. You’ll enrol in Thesis A and Thesis B, each worth 6 UoC over two consecutive terms.

For further information or questions, please contact your  Undergraduate Thesis Coordinator .

All undergraduate students enrolled in the dual degree with Biomedical Engineering (regardless of undergraduate major), must enrol in 12 UoC of thesis courses with the Graduate School of Biomedical Engineering.

Students will complete their thesis over three terms (4+4+4) or over two terms (4+8). A summary of the assessment is as follows:

BIOM4951 Thesis A : It is intended that Thesis A cover the scoping, planning, and completing preparations for the project.

BIOM4952 Thesis B : The primary intention behind Thesis B is to ensure students stay on track with their projects and project work as they progress through the year.

BIOM4953 Thesis C : Thesis C continues the project work. The key deliverable is the Written Report, alongside a poster presentation.

Before commencing Thesis A

You must nominate 3 different supervisors to work with.

Please follow the below instructions in order to view the projects available and to find a supervisor.

The instructions to view the projects are as follows:

You must complete this process and have a project allocated BEFORE starting BIOM4951. If you are planning on doing a project with industry, this requires an industry supervisor and a supervisor from GSBmE. Please contact me  [email protected] .

• Go the Moodle course  Selection of Biomedical Thesis Project  
• Self-enrol as a student using the key Student50
• The projects are listed under Thesis Database
• Contact the supervisor directly if you have any questions
• When ready, follow the instructions on the Moodle page for nominating your three supervisors. Project selection opens midway through the previous term (e.g. for Thesis commencing in T2, selection opens in Week 6 of T1). Selection closes on the last day of exams of previous term.

Undergraduate students are required to complete at least 12 UOC of thesis courses. The table below shows the default Thesis course sequence for your stream and any additional options you may have. The following sections provide more information about each of these sequences.

Research thesis (CEIC4951/2/3)

Research thesis  consists of three courses worth 4 units of credit each –  CEIC4951  Research thesis A,  CEIC4952  Research Thesis B &  CEIC4953  Research Thesis C. Undergraduate students may commence Research Thesis once they have completed at least 126 UOC from a School of Chemical Engineering discipline stream and their 3rd year core.

You  must  identify a supervisor and project prior to commencing CEIC4951. To find out more about Research Thesis courses, the projects available and how to find a supervisor, please join the  Research Thesis Projects  page on Moodle (enrolment key co3shyh).

• These courses are normally taken over three consecutive terms. However, students that make excellent progress in Thesis A, may be allowed to take Thesis B and Thesis C in the same term.
• High performing students may be permitted to take  CEIC9005  (or CEIC4005) in lieu of their regular Research Thesis courses. Contact the course coordinator for more information.

Product Design Project Thesis (CEIC4007/8)

Product Design Project Thesis  consists of two courses both worth 6 UOC –  CEIC4007  Product Design Project Thesis A and  CEIC4008  Product Design Project Thesis B. Undergraduate students may commence Research Thesis once they have completed at least 126 UOC from a School of Chemical Engineering discipline stream.  CEIC6711  Complex Fluids Microstructure and Rheology is a co-requisite course.

You do not need to secure a supervisor before commencing Product Design Project Thesis A.

Research Thesis Extension (CEIC4954)

Research Thesis Extension  ( CEIC4954 ) aims to provide you with an opportunity to go extend your thesis project by exploring your research problem in more breath &/or depth. The work you do in this course builds on the work completed in CEIC4951, CEIC4952 and CEIC4953. This course is especially relevant for undergraduate students considering a research career in fields related to chemical engineering and food science. The activities in this course are designed to introduce you to the ways in which research is practiced and communicated in a higher degree environment.

CEIC4954 is considered a practice elective in the Chemical Engineering stream (CEICAH) and a discipline elective in all other streams.

Students enrolled in an undergraduate degree within the School of Civil and Environmental Engineering need to complete a thesis as part of their program. Students have the option of taking one of the following course combinations to complete their thesis requirement:

CVEN4951 / 4952 / 4953  (Research Thesis A/B/C)

Students must complete the  Thesis Application Form to be registered for the course. This combination of courses are worth 12UOC in total, and will take 3 terms to complete (or 2 with prior approval from the supervisor). A minimum WAM of 70 is required for entry.

CVEN4961 / 4962 / 4963  (Higher Honours Thesis A/B/C)

Students must complete the  Thesis Application Form  to be registered for the course. This combination of courses are worth worth 24UOC in total and requires students to have a minimum WAM of 80.

Note: If you choose to undertake the Research Thesis option (CVEN4951/4952/4953 or CVEN4961/4962/4963) you must also complete CVEN4701 prior to finishing your studies.

CVEN4050 / 4051  (Thesis A/B)

Students are able to enrol themselves into this course directly via myUNSW, it has no minimum WAM requirement, and does not require students to find a supervisor.

If you would like to register for Research Thesis subjects in Summer, you must first obtain approval from your supervisor prior to Summer enrolment. Please check the course notes for more information.

Thesis Submissions

As of Summer 2024, students will need to submit their Thesis submissions via Moodle instead of the School’s intranet.

For the list of topics and available supervisors, you can visit:  Find a Supervisor or Project

UNSW  Bachelor of Computer Science (Honours)  and  Bachelor of Engineering (Honours)  students can find a guide to getting started with Thesis A on the  CSE Thesis Topics Moodle site . Use cse-44747437 to enter the site as a student.

On this site, you will find the Thesis Topic Database. You can look through the topics or visit the academic supervisors' profile pages to find a topic you would like to work on. Once you have chosen your topic(s), you will then need to contact the relevant Supervisor for confirmation.

On this site, you can also find the course outlines of Thesis A, Thesis B and Thesis C, and the detailed instructions about finding a supervisor.

Final year students in Mechanical Engineering and Postgraduate coursework students are required to undertake a three-term, year long project. These projects are usually open-ended research or design projects, where the student works with an academic supervisor to find an answer to an engineering question. Students are required to manage and plan their projects over the three terms. The Thesis course can be started in any term and is generally completed in the final three terms of the degree.

If taking a Research Thesis (individual project), enrol in  Research Thesis A (MMAN4951) ,  Research Thesis B (MMAN4952)  and  Research Thesis C (MMAN4953) .

For Research thesis, you will first need to find a supervisor and get their approval. An approved application is required to undertake Research and to gain permission to enrol. The deadline to enrol in MMAN4951/MMAN9451 is Friday Week 1, but get in early to get the project and supervisor you want.

For information on available projects and the enrolment process, please see our  Sharepoint site , or contact Professor  Tracie Barber .

If you’re an Electrical Engineering student and planning to take Thesis course, you will need to find a supervisor and get their approval prior to enrolling to the course. The deadline to find a supervisor and enrol into the course is Friday week 1. Please follow the procedure below to look for potential supervisors, their topics and enrol into the course

• Go to:  https://moodle.telt.unsw.edu.au/course/view.php?id=20890
• Enrol yourself as student using the enrolment key: EETTPstudent
• Login to Moodle course: 'EET School Thesis/Project'
• View research profiles of prospective supervisors and topics in 'Research Topics' section.
• Contact potential supervisor to discuss the possibility of working with them.. You must get their written permission to sign up on a topic before you can proceed to next step.
• a. Go to ‘Select Supervisor’, find the supervisor and click action box to become a member
• b. Go to ‘Register Topic,’ ‘Add Entry’ and enter your details and topic title.
• Enrol into Thesis course on myUNSW.

Research Thesis

Research Thesis is a compulsory pathway in the Mining Engineering (Hons) degree, Engineering (Hons) – Petroleum Engineering [Main Stream], and an optional pathway for high WAM students doing Petroleum Engineering. This thesis allows a student to work closely with a particular supervisor, learn particular skills – like programming or laboratory work, conduct research and write up their findings. To take this stream, you will need to first enrol in MERE4951 Research Thesis A.

MERE4951 Research Thesis A

In this course you will be required to find a supervisor and topic to work on. You can find a list of our research strengths here:

https://www.unsw.edu.au/engineering//our-schools/minerals-and-energy-resources-engineering/our-research

You can also find an individual academic and ask them about topics that they work on. Academics from our school are available here:

https://www.unsw.edu.au/engineering/ourschools/minerals-and-energy-resources-engineering/about-us/our-people

Once you enrol, make sure you have access to the Microsoft Team (the link is on the Moodle page), which is filled with information and has active forums for asking questions:

MERE4952 & MERE9453 Research Thesis B & C

These two units (4UoC each) can be taken in the same term or separately. Thesis B involves submitting a video/audio reflection of the work so far and an interim report. Thesis C involves writing your thesis and recording and submitting a scientific presentation of your results./engineering/our-schools/minerals-and-energy-resources-engineering/our-researchengineering/our-schools/minerals-and-energy-resources-engineering/our-research

All undergrad thesis sudents can find a list of thesis topics will posted on the  Thesis A Moodle site . The student key to access the site will be sent out by the thesis co-ordinator to all students who will be taking thesis the following term. You should review the list and discuss the topics with the relevant supervisor to get an idea of what it entails.

Once both the supervisor and student have agreed on the topic, a Thesis Nomination Form should be completed. This is submitted to the Thesis Coordinator and uploaded to the SOLA 4951 Moodle site prior to the student commencing work on their topic. All students must have chosen a supervisor by 9am Monday week 1 of term.

You can develop your own thesis topic, if you can find a supervisor from within the School. This will require you to attach a one page description of the thesis topic and signed by the supervisor to the Thesis Nomination Form.

The School also encourages students who wish to do an industry-led thesis topic. In this case the mentor from industry would be the student’s co-supervisor, however an academic staff member from the School must act as the supervisor of the thesis.

For an industry-led thesis, you must obtain approval from an academic of the School to supervise the topic. You should submit a signed letter from the industry representative and academic supervisor with a brief outline of the project with a Thesis Nomination Form.

All information needed for the deliverables of thesis A can be found in the course outline which is available on the SOLA4951 Moodle site.

Undergraduate Thesis FAQs

The Engineering thesis will be taken for the duration of three terms - as Thesis A, Thesis B and Thesis C.

Each course will carry 4 Units of Credit (UoC) for a total of 12 UoC. The total UoC requirement remains unchanged from current.

Students will have two options to take Thesis from 2019:

• Option 1 - Standard: (4 UoC per term starting T1, T2 or T3) : Students enrol in Thesis A, Thesis B and thesis C and complete the Thesis across three consecutive terms. Total of 12 UoC.  Note than once Thesis A is taken, Thesis B and Thesis C must be taken consecutively in the two terms that follow.  
• Option 2: (4+8: 4 UoC in one term and 8 UoC in the following term) : Students who demonstrate satisfactory progress in Thesis A may apply to their School to take a 4+8 UoC structure where both Thesis B and C are taken in the next single term of that year. Total of 12 UoC.  This option is subject to having demonstrated satisfactory progress in Thesis A.

Students who do not maintain satisfactory performance in Option 2 will revert to Option 1 and take Thesis across three terms.

Thesis A, Thesis B and Thesis C will run in every term (T1, T2 and T3).

Yes, it’s possible to start your thesis in any term, however once Thesis A is taken, Thesis B and Thesis C must be completed in each term consecutively afterward.

Depending on the thesis course you take, your topic may be provided to you or you will need to develop one.

If you need to develop one, most schools have a website that lists available topics and the staff willing to supervise those topics. You may wish to select a topic based on areas of engineering interest, extracurricular interests (such as the  ChallENG Projects ), or preference for working with a particular academic in your field.  You can even come up with your own in consultation with your thesis supervisor. Take a look!

The process is different for each school, so review the information above.

If you still have questions, contact your school’s  postgraduate thesis coordinator .

Doing thesis in industry is a great opportunity and worth pursuing. Some students are able to arrange a thesis project that follows on from an industrial training placement.

Students wanting to take an industry-based project still need to take the Research Thesis courses for their specialisation. You need to arrange a UNSW academic as a co-supervisor and apply for permission to take thesis offsite.

Please check with your school’s  Undergraduate Thesis Coordinator  for further details.

Yes, there are a number of Humanitarian Engineering Thesis Supervisors within UNSW Engineering who can potentially supervise a thesis.

Students who demonstrate satisfactory progress in Thesis A may apply to their School to take a 4+8 UoC structure where both Thesis B and C are taken in the next single term of that year.

The 4+8 UoC option is intended for high performing students to finish their thesis project in two terms. Students enrolled in this structure will take Thesis A in the first term and then, provided that satisfactory progress has been reached, will take Thesis B and C in the term following Thesis A.

Yes. In addition to the Thesis, you can enrol in up to two additional courses per term. You should enrol in these courses when annual enrolment opens. Overloading is possible but will require program authority approval.

If progress is deemed as unsatisfactory at the end of Thesis A, the student will move to the default Thesis option: Thesis A, B and C (4 UoC).

Yes, you’ll still be able to enrol in up to two additional courses. Given the increased workload of having to do Thesis B and C together, two courses per term would be the maximum recommended by the Faculty.

An enrolment continued (EC) grade will appear against your Thesis A/Thesis B subjects until you’ve completed your thesis. At this time your final grade will appear against your Thesis C. Around a week after you have received your final mark, a roll back process will be run so that the EC grades previously against Thesis A and Thesis B will be updated to reflect your overall Thesis mark.

Information on honours calculations are available on the  Bachelor of Engineering (Honours) program  rules page.

It’s possible to take leave and then continue your thesis on your return. Talk to your supervisor about your situation and the dates involved so that you can work out a suitable plan together.

Most schools have a Moodle, intranet, or web page with detailed information about their thesis program. That should be your next port of call – check your school’s section above for access instructions.

Schools often run information sessions during the year. These will be advertised via email, on social media and/or during class. Keep an eye out for these events.

If you have questions related to enrolment or progression, contact the  Nucleus .

Finally, each school has an  Undergraduate Thesis Coordinator  who can answer specific questions related to your personal circumstances.

• Northeastern University
• College of Engineering
• Department of Mechanical and Industrial Engineering
• Mechanical and Industrial Engineering Theses and Dissertations
• Mechanical and Industrial Engineering Master's Theses
• Engineering Management Master's Theses

Engineering Management Master's Theses Collection

http://hdl.handle.net/2047/D20233329

Chemo prevention treatment for women with high risk to develop breast cancer

Design for internet of things

An environmental input-output analysis of Boston's climate action plan

Examining agile management methods and non-agile management methods in global software development projects

Multi-resolution approach to identification of recurring patterns in process signal

Proposing a measure to evaluate the impact of the sharing economy: a critical analysis of short-term residential rentals.

Reference management. Clean and simple.

How to write an excellent thesis conclusion [with examples]

Restate the thesis

Review or reiterate key points of your work, explain why your work is relevant, a take-away for the reader, more resources on writing thesis conclusions, frequently asked questions about writing an excellent thesis conclusion, related articles.

At this point in your writing, you have most likely finished your introduction and the body of your thesis, dissertation, or research paper . While this is a reason to celebrate, you should not underestimate the importance of your conclusion. The conclusion is the last thing that your reader will see, so it should be memorable.

A good conclusion will review the key points of the thesis and explain to the reader why the information is relevant, applicable, or related to the world as a whole. Make sure to dedicate enough of your writing time to the conclusion and do not put it off until the very last minute.

This article provides an effective technique for writing a conclusion adapted from Erika Eby’s The College Student's Guide to Writing a Good Research Paper: 101 Easy Tips & Tricks to Make Your Work Stand Out .

While the thesis introduction starts out with broad statements about the topic, and then narrows it down to the thesis statement , a thesis conclusion does the same in the opposite order.

• Restate the thesis.
• Review or reiterate key points of your work.
• Explain why your work is relevant.
• Include a core take-away message for the reader.

Tip: Don’t just copy and paste your thesis into your conclusion. Restate it in different words.

The best way to start a conclusion is simply by restating the thesis statement. That does not mean just copying and pasting it from the introduction, but putting it into different words.

You will need to change the structure and wording of it to avoid sounding repetitive. Also, be firm in your conclusion just as you were in the introduction. Try to avoid sounding apologetic by using phrases like "This paper has tried to show..."

The conclusion should address all the same parts as the thesis while making it clear that the reader has reached the end. You are telling the reader that your research is finished and what your findings are.

I have argued throughout this work that the point of critical mass for biopolitical immunity occurred during the Romantic period because of that era's unique combination of post-revolutionary politics and innovations in smallpox prevention. In particular, I demonstrated that the French Revolution and the discovery of vaccination in the 1790s triggered a reconsideration of the relationship between bodies and the state.

Tip: Try to reiterate points from your introduction in your thesis conclusion.

The next step is to review the main points of the thesis as a whole. Look back at the body of of your project and make a note of the key ideas. You can reword these ideas the same way you reworded your thesis statement and then incorporate that into the conclusion.

You can also repeat striking quotations or statistics, but do not use more than two. As the conclusion represents your own closing thoughts on the topic , it should mainly consist of your own words.

In addition, conclusions can contain recommendations to the reader or relevant questions that further the thesis. You should ask yourself:

• What you would ideally like to see your readers do in reaction to your paper?
• Do you want them to take a certain action or investigate further?
• Is there a bigger issue that your paper wants to draw attention to?

Also, try to reference your introduction in your conclusion. You have already taken a first step by restating your thesis. Now, check whether there are other key words, phrases or ideas that are mentioned in your introduction that fit into your conclusion. Connecting the introduction to the conclusion in this way will help readers feel satisfied.

I explored how Mary Wollstonecraft, in both her fiction and political writings, envisions an ideal medico-political state, and how other writers like William Wordsworth and Mary Shelley increasingly imagined the body politic literally, as an incorporated political collective made up of bodies whose immunity to political and medical ills was essential to a healthy state.

Tip: Make sure to explain why your thesis is relevant to your field of research.

Although you can encourage readers to question their opinions and reflect on your topic, do not leave loose ends. You should provide a sense of resolution and make sure your conclusion wraps up your argument. Make sure you explain why your thesis is relevant to your field of research and how your research intervenes within, or substantially revises, existing scholarly debates.

This project challenged conventional ideas about the relationship among Romanticism, medicine, and politics by reading the unfolding of Romantic literature and biopolitical immunity as mutual, co-productive processes. In doing so, this thesis revises the ways in which biopolitics has been theorized by insisting on the inherent connections between Romantic literature and the forms of biopower that characterize early modernity.

Tip: If you began your thesis with an anecdote or historical example, you may want to return to that in your conclusion.

End your conclusion with something memorable, such as:

• a call to action
• a recommendation
• a gesture towards future research
• a brief explanation of how the problem or idea you covered remains relevant

Ultimately, you want readers to feel more informed, or ready to act, as they read your conclusion.

Yet, the Romantic period is only the beginning of modern thought on immunity and biopolitics. Victorian writers, doctors, and politicians upheld the Romantic idea that a "healthy state" was a literal condition that could be achieved by combining politics and medicine, but augmented that idea through legislation and widespread public health measures. While many nineteenth-century efforts to improve citizens' health were successful, the fight against disease ultimately changed course in the twentieth century as global immunological threats such as SARS occupied public consciousness. Indeed, as subsequent public health events make apparent, biopolitical immunity persists as a viable concept for thinking about the relationship between medicine and politics in modernity.

Need more advice? Read our 5 additional tips on how to write a good thesis conclusion.

The conclusion is the last thing that your reader will see, so it should be memorable. To write a great thesis conclusion you should:

The basic content of a conclusion is to review the main points from the paper. This part represents your own closing thoughts on the topic. It should mainly consist of the outcome of the research in your own words.

The length of the conclusion will depend on the length of the whole thesis. Usually, a conclusion should be around 5-7% of the overall word count.

End your conclusion with something memorable, such as a question, warning, or call to action. Depending on the topic, you can also end with a recommendation.

In Open Access: Theses and Dissertations you can find thousands of completed works. Take a look at any of the theses or dissertations for real-life examples of conclusions that were already approved.

• USF Research
• USF Libraries

Digital Commons @ USF > College of Engineering > Civil and Environmental Engineering > Theses and Dissertations

Civil and Environmental Engineering Theses and Dissertations

Theses/dissertations from 2023 2023.

The Influence of Corrosion Mitigating Fluids on Post Tensioned Tendon Grout Properties and Steel to Grout Bond Strength , Sarita Ale Magar

Exploring Alternative Electron Donors for Heterotrophic Denitrification at a Water Reclamation Facility in Tampa Bay , Tejas Athavale

Mechanisms Contributing to Hydrogen-Influenced Early Failure of Bridge Tendons , David Dukeman

The Influence of Bipolar Electrochemical Cell Geometry on the Studies of Pitting Corrosion , Amin Kazem Ghamsari

Field-Base Exploratory Study of Microbial Activity in Eight Potable Water Storage Tanks in Barbados , Katelyn M. Long

Land Use/Land Cover Uncertainty Analysis Using Hydrological Modeling in the Northern Watershed of Lake Okeechobee , Andres Lora Santos

Modeling Leachate Treatment Processes in Adsorbent-amended Hybrid Constructed Wetland , Ishfaqun Nisa

Effects of Downdrag on Pile Performance , Ruthvik Pendyala

Anaerobic Digestion of Brewery Waste Including Spent Yeast and Hops , Dhanashree Rawalgaonkar

Characteristics and Hydraulic Behavior of Adsorptive Media for Use in Permeable Reactive Barriers , Shelby Rocha

Exploratory Data-Driven Models for Water Quality: A Case Study for Tampa Bay Water , Sandra Sekyere

Interdependency between Water and Road Infrastructures: Cases and Impacts , Shihab Uddin

Hurricanes and Tropical Storms’ Impact on Water Quality in Lake Okeechobee, Florida , Daniela Vasquez Diaz

Exploration of Shared Passenger Urban Air Mobility – Integrated Network Design, Operation Scheduling and System Configuration , Zhiqiang Wu

Rehabilitation Technologies to Abate Infiltration in Sanitary Sewers , Steve Youssef

Adsorption of Long and Short Per- and Polyfluoroalkyl Substances (PFAS) onto Granular Activated Carbon and Porous Organic Polymers , Yan Zhang

Adiabatic Temperature Rise and Durability Performance of Slag Blended Concrete , Hai Zhu

Theses/Dissertations from 2022 2022

Effects of Downdrag on Pile Performance , Malaak Omelia Araujo

Quantifying a 21-year Surface Water and Groundwater Interaction in a Ridge and Valley Lake Environment Using a Highly Constrained Modeling Approach , Richard T. Bowers Jr.

A Convergent Approach to Aqueous Lead (Pb) Mitigation of a Supplemental Self-Supply Shallow Groundwater Source Accessed by Handpumps in Madagascar , Adaline Marie Buerck

Identifying Significant Factors Affecting the Likelihood and Severity Level of Shared E-scooter Crashes , Recep Can Cakici

Evaluation of Aluminum Dissolution, Current Density, and Pitting Patterns During Electrocoagulation , Monica Castro Carias

Carbon Diversion, Partial Nitritation/Anammox Enrichment, and Ammonium Capture as Initial Stages for Mainstream Ion Exchange-Deammonification Process , Sheyla Chero-Osorio

Data Driven Approaches for Understanding and Improving Urban Mobility , Yujie Guo

Assessment of Scoured Bridges Subjected to Vessel Impact Using Nonlinear Dynamic Analysis , Amir S. Irhayyim

Assessment and Prevention of Bacterial Regrowth in Stored Household Water in Eastern Coastal Madagascar , Lauren Judah

The Impact of Land Use Change on Hydrology Using Hydrologic Modelling and Geographical Information System (GIS) , Nattachan Luesaksiriwattana

Simulating Flood Control in Progress Village, Florida Using Storm Water Management Model (SWMM) , Azize Minaz

Effects of Slurry Type on Drilled Shaft Strength , Cesar Quesada Garcia

Comparison Study of Consumer’s Perception toward Urban Air Mobility in the United States and Rest of the World Using Social Media Information , S M Toki Tahmid

Advanced Methods for Railroad Station Operation Decisions: Data Analytics, Optimization, Automation , Yuan Wang

High-Risk Traffic Crash Pattern Recognition and Identification Using Econometric Models and Machine Learning Models , Runan Yang

Biochar Amended Biological Systems for Enhanced Landfill Leachate and Lignocellulosic Banana Waste Treatment , Xia Yang

Passive Radiative Cooling by Spectrally Selective Nanoparticles in Thick Film Nanocomposites , David Allen Young

Theses/Dissertations from 2021 2021

A System Architecture for Water Distribution Networks , Noha Abdel-Mottaleb

Sustainability Assessment of a Pressure Retarded Osmosis System , Samar Al Mashrafi

Health Risk Assessment of Local Populations Ingesting Water with Naturally Occurring Arsenic and Fecal Related Contaminants in Lake Atitlan, Guatemala , Marisol Alvarez

Influence of Coating Defects Within the Lock Seams on the Corrosion Performance of Aluminized Steel Drainage Pipes , Mohammed Al Yaarubi

Longitudinal Trajectory Tracking Analysis for Autonomous Electric Vehicles Based on PID Control , Hossein Amiri

An Assessment and Exploration of Recent Methodological Advances in Safety Data Analysis , Suryaprasanna Kumar Balusu

Pressure Retarded Osmosis: A Potential Technology for Seawater Desalination Energy Recovery and Concentrate Management , Joshua Benjamin

Assessing the Feasibility of Microbially Managed Biological Filtration in U.S. Drinking Water Systems for Removal of Contaminants of Emerging Concern , Andrew J. Black

The Effect of Cement and Blast Furnace Slag Characteristics on Expansion of Heat-Cured Mortar Specimens , Jair G. Burgos

A Systems Approach for Improving the Performance of Rural Community-Managed Water Systems Using SIASAR: Case Studies in Bolivia and Colombia , Rachel A. Cannon

Passive Nitrifying Biofilters for Onsite Treatment of Saline Domestic Wastewater , Daniel Arnulfo Delgado

Plastic Pollution in Urban Rivers: Spatial and Temporal Patterns of Plastic Release and Transport , Charlotte Juliane Haberstroh

Effects of Nitrate on Arsenic Mobilization during Aquifer Storage and Recovery , Hania Hawasli

Prediction of the Effects of Turbulence on Vehicle Hydroplaning using a Numerical Model , Thathsarani Dilini Herath Herath Mudiyanselage

Shortcut Nitrogen Removal in Photo-sequencing Batch Reactor, Experiments, Dynamic Model and Full-scale Design , Sahand Iman Shayan

Chorine Conversion: Biological and Water Quality Impact on Activated Carbon Block Point of Use Filters , Horace S. Jakpa

Efficient Management of Nitrogen and Phosphorus at Centralized Water Reclamation Facilities , Helene Kassouf

Building and Characterizing a Lab-Scaled Aquifer Storage and Recovery System , Murat Can Kayabas

Corrosion Rate Prediction in FRP-Concrete Repair , Mohammad A. Khawaja

Use of Biochar and Zeolite for Landfill Leachate Treatment: Experimental Studies and Reuse Potential Assessment , Thanh Thieu Lam

Feasibility of Epoxy Bond Enhancement on High-Strength Concrete , Amanda A. Lewis

Leaf Cutter Ant Nest Soil Cement Stabilized Earthen Bricks: Materials and Methods for Engineering Field Applications , Faith Malay

Minimum Cut-Sets for the Identification of Critical Water Distribution Network Segments , Xiliang Mao

An Assessment of Nutrient Improvement in Surface Water Due to the Conversion of Onsite Sewage Treatment and Disposal Systems to Sewerage , Jenelle A. Mohammed

Development of a Numerical Process Model for Adsorbent-amended Constructed Wetlands , Lillian Mulligan

Corrosion Propagation of Stainless Steel Reinforced Concrete , Nelly Sofía Orozco Martínez

Corrosion Durability Service Life of Calcium Silicate-Based Reinforced Concrete , Carolina Páez Jiménez

Assessment of the Environmental Sustainability of a Small Water Production Facility in Madagascar , Jesal Patel

Computational Fluid Dynamics (CFD) Analysis of the Hydraulic Performance and Bio-kinetics in a Full-Scale Oxidation Ditch , Kiesha C. Pierre

Biochar Amended Bioretention Systems for Nutrient and Fecal Indicator Bacteria Removal from Urban and Agricultural Runoffs , Md Yeasir Arif Rahman

Understanding the Leaching Mechanism for Lead (Pb) Found in Components of Locally Manufactured Handpumps in Eastern Madagascar , Nidhi Shah

Impacts of Automated Vehicle Technologies on Future Traffic , Xiaowei Shi

Community Assessment of Water Perceptions and Household Point-of-Use Treatment Methods in Madagascar , Isabella Rose Silverman

Laboratory Examination of Lead Weights Harvested from Pitcher Pumps in Eastern Madagascar , Madelyn Wilson

Impact of grain morphology on the temporal evolution of interfacial area during multi-phase flow in porous media , Fizza Zahid

EAV Fleet Management in Transportation and Power Systems , Dongfang Zhao

Theses/Dissertations from 2020 2020

A Framework for Assessing the Reliability, Availability, Maintainability, and Safety (RAMS) of Decentralized Sanitation , Adefunké Adeosun

Development of an Organic Processor Assembly (OPA) for Sustainable Resource Recovery to Enable Long-Duration, Deep-Space Human Exploration (LoDDSHE) , Talon James Bullard

Black Lives Matter in Engineering, Too! An Environmental Justice Approach towards Equitable Decision-Making for Stormwater Management in African American Communities , Maya Elizabeth Carrasquillo

Coral Reef Restoration in the Tropical West Atlantic Amid the COVID-19 Pandemic , Linden Cheek

Designing Next-generation Transportation Systems with Emerging Vehicle Technologies , Zhiwei Chen

Strength Restoration of Corrosion Damaged Piles Repaired with Carbon Fiber Reinforced Polymer Systems , Jethro Clarke

Water Quality and Sustainability Assessment of Rural Water Systems in the Comarca Ngäbe-Buglé, Panama , Corbyn Cools

Rapid Cross-Section Imaging with Magnetic and Impedance Sensors for Grout Anomaly Detection in External Post-Tensioned Tendons , Hani Freij

Enhanced Nitrogen, Organic Matter and Color Removal from Landfill Leachate by Biological Treatment Processes with Biochar and Zeolite , Bisheng Gao

Bond Life of Structural Epoxy-Concrete Systems Under Accelerated Hygrothermal Aging , Philip W. Hopkins

Socio-Technical Transitions in the Water Sector: Emerging Boundaries for Utility Resilience in Barbados , Wainella N. Isaacs

Structural and Agricultural Value at Risk in Florida from Flooding during Hurricane Irma , Alexander J. Miller

An Inferential Study of the Potential Consumer Value of Free Charging for Users of Public Electric Vehicle Charging Infrastructure , Divyamitra Mishra

Reimagining Bottom-up Participatory Climate Change Adaptation in the Philippines , Emily Clark Nabong

Effects of Physical and Chemical Characteristics of Slags and Cements on Durability of Portland Cement-Slag Blended Systems , Farzaneh Nosouhian

Using a Systems Thinking Approach and Health Risk Assessment to Analyze the Food-Energy-Water System Nexus of Seaweed Farming in Belize , Estenia J. Ortiz Carabantes

Implementation of Large-Scale Anaerobic Digestion of Food Waste at the University of South Florida , Karamjit Panesar

Enhanced Fluoride Removal in Biosand Filters Using Aluminum Oxide Coated Media and Modified Filter Design , Madison Leigh Rice

Use of Sugarcane Bagasse Ash as Partial Cement Replacement in Interlocking Stabilized Soil Blocks (ISSBs) , Adah Shair

Bio-electrochemical Denitrification Systems and Applications for Nitrogen Removal in On-Site Wastewater Treatment , Kamal Ziad Taha

Development of an Integrated Direct Membrane Filtration (DMF) and Anaerobic Membrane Bioreactor (AnMBR) System for Dilute Municipal Wastewater Treatment , Ahmet Erkan Uman

Post-overlay Flexible Pavement Performance Modeling and Its Application in Sustainable Asphalt Overlay Policy Making , Chunfu Xin

Sustainable Nutrient Management Through Technology-Level Evaluation and System-Level Optimization , Xiaofan Xu

Influence of Glass Fiber Reinforced Polymer Wraps on Corrosion Progression of Bridge Piles in Marine Environments , Shayan Yazdani

Theses/Dissertations from 2019 2019

Seepage-Coupled Finite Element Analysis of Stress Driven Rock Slope Failures for BothNatural and Induced Failures , Thomas Becket Anyintuo

Statistical Analysis of the Role of Socio-Demographic and Health Factors in Shared Mobility Related Behaviors and Usage Likelihoods , Natalia M. Barbour

Model of a Sulfur-based Cyclic Denitrification Filter for Marine Recirculating Aquaculture Systems , Zhang Cheng

Exploring the Equity Performance of Bike-Sharing Systems with Disaggregated Data: A Story of Southern Tampa , Zhiwei Chen

Prioritizing Rehabilitation of Sanitary Sewers in Pinellas County, FL , Jesse T. Hillman

Highway Lane Management Policy for Existing and Connected Autonomous Vehicles , Md Mokaddesul Hoque

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Engineering: The Literature Review Process

• How to Use This Guide

What is a literature review and why is it important?

Further reading ....

• 2. Precision vs Retrieval
• 3. Equip Your Tool Box
• 4. What to look for
• 5. Where to Look for it
• 6. How to Look for it
• 7. Keeping Current
• 8. Reading Tips
• 9. Writing Tips
• 10. Checklist

A literature review not only summarizes the knowledge of a particular area or field of study, it also evaluates what has been done, what still needs to be done and why all of this is important to the subject.  

• The Stand-Alone Literature Review A literature review may stand alone as an individual document in which the history of the topic is reported and then analyzed for trends, controversial issues, and what still needs to be studied.  The review could just be a few pages for narrow topics or quite extensive with long bibliographies for in-depth reviews.   In-depth review articles are valuable time-savers for professionals and researchers who need a quick introduction or analysis of a topic but they can be very time-consuming for authors to produce. Examples of review articles:   Walker, Sara Louise (2011)   Building mounted wind turbines and their suitability for the urban scale - a review of methods of estimating urban wind resource .   Energy and Buildings  43(8):1852-1862. For this review, the author focused on the different methodologies used to estimate wind speed in urban settings.  After introducing the theory, she explained the difficulty for in-situ measuring, and then followed up by describing each of the different estimation techniques that have been used instead.  Strengths and weaknesses of each method are discussed and suggestions are given on where more study is needed.   Length: 11 pages. References: 59. Calm, J.M. (2008)   The next generation of refrigerants - historical review, considerations, and outlook.   International Journal of Refrigeration  31(7):1123-1133. This review focuses on the evolution of refrigerants and divides the evolution into 4 generations.  In each generation the author describes which type of refrigerants were most popular and discusses how political, environmental, and economic issues as well as chemical properties effected choices.  Length: 11 pages.  References: 51.  
• The Literature Review as a Section Within a Document Literature reviews are also part of dissertations, theses, research reports and scholarly journal articles; these types of documents include the review in a section or chapter that discusses what has gone before, how the research being presented in this document fills a gap in the field's knowledge and why that is important.   Examples of literature reviews within a journal article:  Jobert, Arthur, et al. (2007) Local acceptance of wind energy: factors of success identified in French and German case studies.  Energy Policy  35(5):2751-2760.  In this case, the literature review is a separate, labeled section appearing between the introduction and methodology sections.  Peel, Deborah and Lloyd, Michael Gregory (2007)   Positive planning for wind-turbines in an urban context.   Local Environment  12(4):343-354. In this case the literature review is incorporated into the article's introduction rather than have its own section.   Which version you choose (separate section or within the introduction) depends on format requirements of the publisher (for journal articles), the ASU Graduate College and your academic unit (for ASU dissertations and theses) and application instructions for grants.   If no format is specified choose the method in which you can best explain your research topic, what has come before and the importance of the knowledge you are adding to the field.    Examples of literature reviews within a dissertation or thesis :  Porter, Wayne Eliot (2011)   Renewable Energy in Rural Southeastern Arizona: Decision Factors: A Comparison of the Consumer Profiles of Homeowners Who Purchased Renewable Energy Systems With Those Who Performed Other Home Upgrades or Remodeling Projects .    Arizona State University, M.S. Thesis.  This author effectively uses a separate chapter for the literature review for his detailed analysis.  Magerman, Beth (2014)   Short-Term Wind Power Forecasts using Doppler Lidar.   Arizona State University, M.S. Thesis. The author puts the literature review within Chapter Two presenting it as part of the background information of her topic.   Note that the literature review within a thesis or dissertation more closely resembles the scope and depth of a stand- alone literature review as opposed to the briefer reviews appearing within journal articles.  Within a thesis or dissertation, the review not only presents the status of research in the specific area it also establishes the author's expertise and justifies his/her own research.   

Online tutorials:

• Literature Reviews: An Overview for Graduate Students Created by the North Caroline State University Libraries

Other ASU Library Guides: 

• Literature Reviews and Annotated Bibliographies More general information about the format and content of literature reviews; created by Ed Oetting, History and Political Science Librarian, Hayden Library. ​

Readings: 

• The Literature Review: A Few Tips on Conducting It Written by Dena Taylor, Health Sciences Writing Centre, University of Toronto
• Literature Reviews Created by The Writing Center at the University of North Carolina, Chapel Hill. 
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• Next: 2. Precision vs Retrieval >>
• Last updated: Jan 2, 2024 8:27 AM
• URL: https://libguides.asu.edu/engineeringlitreview

The ASU Library acknowledges the twenty-three Native Nations that have inhabited this land for centuries. Arizona State University's four campuses are located in the Salt River Valley on ancestral territories of Indigenous peoples, including the Akimel O’odham (Pima) and Pee Posh (Maricopa) Indian Communities, whose care and keeping of these lands allows us to be here today. ASU Library acknowledges the sovereignty of these nations and seeks to foster an environment of success and possibility for Native American students and patrons. We are advocates for the incorporation of Indigenous knowledge systems and research methodologies within contemporary library practice. ASU Library welcomes members of the Akimel O’odham and Pee Posh, and all Native nations to the Library.

Theses and Dissertations Guide: For Engineering Students

• Graduation Deadlines
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For Students in the School of Engineering

* All theses and dissertations should be sent to [email protected]  e lectronically  for a format check at least one week prior to the final submission date. This will prevent the unnecessary reprinting of documents or other delays if errors in formatting are found.

School of Engineering students should submit their finalized thesis or dissertation to their respective departments.  If the student wants to have one or more commercially bound copies, they must submit a paper copy for each bound copy desired to Graduate Academic Affairs (St. Mary's Hall, Room 200). Up to three bound copies may be requested at no additional charge. Additional copies may be bound for a nominal fee.

Optional LaTeX Template with Accessibility Update

• Optional LaTeX Template 07/23 This is a zip file.

An optional LaTeX template has been provided by the School of Engineering. Please consult your thesis committee for assistance, if needed. The Libraries do not provide training or support for LaTeX.

Please convert any LaTeX document to PDF before submitting to Graduate Academic Affairs.

Find out more about LaTeX at  http://www.latex-project.org/

Sample Approval Page

• Sample Engineering Approval Page

All School of Engineering graduate students should construct their approval page according to the attached sample. If you have questions or concerns about constructing this page, please contact the administrative assistant in your department.

See the Sample Pages tab for information about constructing other preliminary pages.

Delaying Publication

Delaying Electronic Publication of a Thesis or Dissertation

In some circumstances, a student may wish to delay the electronic publication of a thesis or dissertation. While the University generally promotes the publication of theses and dissertations as quickly as possible, it is recognized that under certain circumstances, a delay is warranted. These may include: when the student wishes to publish an article from the thesis or dissertation in a journal whose policy is not to publish material that has already been published electronically; when the student wishes to publish the thesis or dissertation with a publisher whose policy is not to publish material that has already been published electronically; or, when the student is in the process of applying for a patent on research contained in the thesis or dissertation and does not wish to disclose its contents until a patent application has been filed.

With approval from his or her thesis/dissertation advisor and program director, a student may delay publication of their thesis or dissertation for one or two years. Under no circumstances may publication be indefinitely or permanently delayed.

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• Last Updated: Apr 16, 2024 2:17 PM
• URL: https://libguides.udayton.edu/etd

The program of study for the Master of Science with a major in engineering technology is a comprehensive program that provides for a degree of specialization with the proper selection of courses within the major. A non-thesis project option,  Engineering Technology (non-thesis project option), MS   , and a non-thesis course work–only option,  Engineering Technology (non-thesis integrative course option), MS   , are also available.

Requirements

The graduate credit requirement for the MS degree with a major in engineering technology, thesis option, is 30 semester hours chosen in one of the following concentrations. A formal proposal and an oral defense of the thesis are required of all degree candidates.

Construction management concentration

Block a, 12 hours.

• MGMT 5240 - Project Management
• MSET 5010 - Graduate Seminar (1 hour; repeat 3 times)
• MSET 5020 - Design of Experiments
• MSET 5040 - Analytical Methods in Engineering Technology

Block B, 12 hours

Chosen from the following in consultation with the major professor.

• MGMT 5210 - Human Resource Management Seminar
• MSET 5200 - Advanced Construction Scheduling
• MSET 5220 - Building Information Modeling
• MSET 5230 - Risk Management in Construction

Additional options in block B

A maximum of 6 credits, with the approval of the major professor and department.

• MSET 5800 - Studies in Engineering Technology
• MSET 5900 - Special Problems
• One course substitution

Block C, 6 hours

• MSET 5950 - Master’s Thesis

Electrical systems concentration

• MSET 5300 - Embedded Systems Organization
• MSET 5310 - Industrial Process Controls
• MSET 5320 - Introduction to Telecommunications
• MSET 5330 - Instrumentation System Design
• MSET 5340 - Digital Logic Design Techniques

 A maximum of 6 credits, with the approval of the major professor and department.

Engineering management concentration

• MSET 5130 - Product Reliability and Quality

Select 2 courses from

• MSET 5030 - Product Design and Development
• MSET 5060 - Technology Innovation
• ACCT 5020 - Accumulation and Analysis of Accounting Data
• MGMT 5120 - Managing Organizational Design and Change
• MGMT 5140 - Organizational Behavior and Analysis
• MGMT 5280 - Analysis and Design of Operations System
• MGMT 5760 - Strategic Management
• MKTG 5150 - Marketing Management

Mechanical systems concentration

• MSET 5100 - Advanced Manufacturing Processes and Technologies
• MSET 5150 - Applications of Electron Microscopy and Failure Analysis
• MSET 5160 - Creep and Fatigue in Engineering Design and Systems Performance

Dual degree

The Department of Engineering Technology, in collaboration with the College of Business, offers a dual degree in engineering technology and operations and supply chain management. See Engineering Technology, MS/Operations and Supply Chain Management, MBA   for more information.

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Engineering Thesis

Engineering thesis presentation, premium google slides theme and powerpoint template.

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Maggie Braunreuther PhD Thesis Defense

A magnetic microwire rheometer for in situ measurement of mucus rheology on live epithelial cell cultures, event details:, this event is open to:.

Maggie Braunreuther PhD Candidate Chemical Engineering Academic advisors: Professor Gerald Fuller

Abstract: A Magnetic Microwire Rheometer for in situ Measurement of Mucus Rheology on Live Epithelial Cell Cultures

Mucus that lines the eyes, airway, and intestines acts as the primary defense against foreign particles and infectious agents by trapping the invaders and preventing them from penetrating the tissue layer. Effective mucus clearance, and consequently removal of the trapped invaders, is vital for healthy immune function. Changes in mucus rheology can inhibit mucus transport, leading to a breakdown in mucus clearance.

The rheological properties of mucus, such as viscosity and elasticity, can vary dramatically with diseases such as asthma and cystic fibrosis, where thickened and concentrated mucus tends to build up and block the airway. Characterization of mucus rheology in health and disease is crucial to understanding underlying mechanisms of disease progression and developing targeted therapeutic strategies to address muco-obstructive disorders. However, studies of mucus rheology thus far have been limited by difficulty of mucus collection, small sample volumes, and changes in properties due to collection and handling procedures. To address these limitations, I present a custom device to measure mucus rheology directly on live human epithelial cell cultures for the first time. I will then show how we have used this device to investigate the intricate relationship between epithelial cell physiology and pathologic mucus secretion.

I will start by presenting the development of my custom device: the magnetic microwire live cell rheometer. This instrument consists of a micron-scale magnetic wire (microwire) probe that is placed on the sample of interest, with the sample positioned between two electromagnetic coils. By supplying current to the electromagnetic coils, we generate a magnetic force on the microwire, causing it to translate along its longitudinal axis. We then record the displacement of the microwire in response to the applied force. The relationship between the applied force and the measured microwire displacement is used to assess the material properties of the sample. With this tool, we demonstrate the ability to make nondestructive rheological measurements of small volumes of biomaterials.

I will then show how we have used this instrument to characterize mucus rheology in situ on live epithelial cell cultures. We demonstrate the ability to quantify changes in mucus viscoelasticity with various disease models and drug treatments, giving us unique insight into the mechanisms of pathologic mucus production. Overall, my work demonstrates the power of this in situ rheometry method to probe the relationship between epithelial cell physiology and the secreted mucus rheology.

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2024 Theses Doctoral

Engineering a versatile dendrimer-based nanomedicine platform for the development of advanced drug delivery for inflammation and pain

Bhansali, Divya

This thesis presents the design and optimization of a dendrimer-based cationic nanoparticle system tailored for versatile applications, ranging from anti-inflammatory scavenging to targeted pain relief through endosomal delivery. By harnessing the unique attributes of this platform, various strategies were devised to overcome hurdles in drug delivery, offering promising avenues for nanomedicine in anti-inflammatory and nociceptive treatments. In our scavenging screening project, we rigorously screened various materials to find the best universal anti-inflammatory carrier. We started by exploring the potential of dendrimer-based materials as scavengers of inflammatory signals and studied how they could be used to develop therapeutic carriers. With intrinsic therapeutic properties and the ability to create tunable nanocarriers, dendrimer-based delivery systems are powerful multimodal delivery systems. The dendrimer base of our delivery system, cationic PAMAM Generation 3 dendrimer (PAMAM-G3), was selected due to its efficient scavenging ability and low biotoxicity. Conjugation with cholesterol facilitated the formation of polymeric micelles, exhibiting a cationic and hydrophilic exterior coupled with a hydrophobic interior, resulting in a high drug-loading capacity. Among the developed scavengers, PAMAM-Cholesterol (PAMAM-Chol) nanoparticles demonstrated a potent reduction in toll-like receptor activation with minimal toxicity and extended endosomal retention. We then exploited the endosomal retention of PAMAM-Chol nanoparticles to target the activated PAR2 receptor within endosomes of relevant cancer cells, aiming to alleviate oral cancer-induced nociception. Extensive characterization confirmed the platform's stability, physical attributes, and ability to encapsulate PAR2 inhibitor, AZ3451. The platform exhibited high drug loading capacity and sustained release profiles across various pHs. Cellular uptake studies demonstrated efficient endosomal targeting, with subsequent modulation of PAR2 signaling pathways. Preclinical studies in oral cancer pain models revealed a significant and prolonged reduction in nociception for over 24 hours, surpassing the efficacy of free drugs. Further diversification of the PAMAM-Chol platform explored its potential as a "Push" chemotherapy carrier and a "Pull" cfDNA scavenger against chemotherapy-induced neurological and neuropathic side effects. Evaluation in wild-type mice demonstrated the platform's effectiveness in mitigating chemobrain and chemotherapy-induced peripheral neuropathy, highlighting its translational potential for multimodal cancer therapy. We found that NPs loaded with chemotherapy significantly reduced the painful effects of chemotherapy-induced peripheral neuropathy and decreased recovery times. Collectively, this body of work underscores the potential of PAMAM-Chol as a versatile tool in drug delivery and endosome-localized pain therapeutics. It contributes to the evolving landscape of precision medicine through tailored therapeutic approaches for minimizing side effects and enhancing patient well-being. The innate therapeutic properties coupled with efficient and sustained drug delivery mechanisms position the PAMAM-Chol platform as a foundational element for the development and delivery of next-generation therapeutics.

• Biomedical engineering
• Dendrimers in medicine
• Nanomedicine
• Nanoparticles
• Drug delivery systems
• Anti-inflammatory agents
• Chemotherapy

This item is currently under embargo. It will be available starting 2029-04-25.

More About This Work

• DOI Copy DOI to clipboard

MEAM Blog @ Penn Engineering

Ho Jin Choi Successfully Defends Master’s Thesis

Ho Jin Choi has successfully defended his master’s thesis titled “Gaussian Process-Based Active Exploration Strategies in Vision and Touch” under the advisory of Nadia Figueroa , Shalini and Rajeev Misra Presidential Assistant Professor in MEAM. Choi’s research presents innovative methods for enhancing the capabilities of robots in perceiving and interacting with their surroundings, marking a significant contribution to the robotics field.

Choi’s journey at Penn was filled with enriching experiences and transformative moments. As an international student, he faced the initial challenge of adapting to a new academic environment. However, his time at Penn’s MEAM department provided ample opportunities to interact with leading researchers and gain exposure to diverse perspectives during seminars and MEAM Coffee time. These experiences fostered Choi’s growth as a robotics engineer and strengthened his connection to the MEAM community.

Reflecting on his time at Penn, Choi fondly recalls collaborating with his colleagues on his first publication, a process that required dedication and hard work. “It was challenging, but it felt amazing to work towards a common goal and showcase our contributions to the broader community,” says Choi. “The teamwork and dedication from everyone involved were truly inspiring.”

Choi extends his gratitude to his supervisor, Dr. Nadia Figueroa, and his lab members for their unwavering support throughout his master’s journey. Their guidance and encouragement played a crucial role in his success. “I also want to thank my family for standing by me through every decision and journey,” Choi adds. “Without them, none of this would have been possible.”

Ho Jin Choi was also recipient the Outstanding Researcher award recognizing Master’s students.