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Materials Science and Engineering BSMSE

Major: Materials Science and Engineering
Degree Awarded: Bachelor of Science in Materials Science and Engineering (BSMSE)
Calendar Type: Quarter
Minimum Required Credits: 186.5
Co-op Options: Three Co-op (Five years); One Co-op (Four years)
Classification of Instructional Programs (CIP) code: 14.1801
Standard Occupational Classification (SOC) code: 17-2131

About the Program

Materials Science and Engineering (MSE) is concerned with the production, structure, characterization, properties and utilization of metals, ceramics, polymers, composites, electronic, optical, nano- and bio-compatible materials. Materials scientists and engineers play a key role in our increasingly complex technological society by extending the limited supply of materials, improving existing materials, and developing and designing new and superior materials with an awareness of their cost, reliability, safety, and societal/environmental implications.

Students majoring in materials science and engineering (MSE) receive a thorough grounding in the basic sciences and engineering of all materials. All students are required to take course sequences that include materials processing, thermodynamics and kinetics of materials, and their physical and mechanical behavior, plus laboratories designed to familiarize them with the instruments and advanced techniques used to process and characterize materials and evaluate their structure, properties and performance. A number of tracks allow upper-level students to focus their technical electives in areas of specialization, including:

Materials for Energy
Materials for Sustainability
Materials for Medical Technology
Manufacturing
A Custom Track.

In addition, several required senior level courses emphasize the role and importance of materials selection and specification in design.

During their senior year, students majoring in materials science and engineering (MSE) work on a capstone senior design project over the course of three terms, with guidance from a faculty advisor and graduate student mentor. Students, generally working in small groups, synthesize information and knowledge from their courses to arrive at solutions to real-world engineering problems.

Examples of recent senior design project topics include:

Fabrication of MXenes with Large Flakes
Polymer/Metal Additive Manufacturing Materials Development
Photoluminescent Nanocrystals as Photocatalysts
Touchspinning of Chitosan Nanofibers
Designing Compatibilizers for Upcycling Plastics
Design of High Entropy Alloys via Physics-Informed Machine Learning
Scaling-up a Topochemical Fluorination Reactor
Quantum Materials Properties Characterization Using Computational Models
Synthesis of MXenes from Novel MAX Phases
Near-Infrared Photodetector for Future Use in an Imaging Wand
Screening of MXenes for Photothermal Therapy
Hybrid Nanovesicles Made of Cell Membranes and Phosphoipids
Stereocomplexed Nanofiber Shish-Kebabs for Sustainable Polymer Nanocomposites
Solid Polymer Electrolytes (SPE) for Lithium Metal Batteries
Photoluminescent Fibers as Smart Textiles
Materials Discovery Through Machine Learning
Photoluminescent Nanocrystals for Photodetectors
Numerical Modeling of Selective Laser Melting via Finite Element Analysis
Synthesis of MXenes Through Molten Salt Etching of MAX Phases
Analysis of Electrospun Polyacrylonitrile Nanoyarn
MXene-Polymer Nanocomposites via Thiol-Michael "Click" Chemistry

Mission Statement

The Department of Materials Science and Engineering will provide our BS, MS and PhD graduates with the technical and theoretical knowledge, design capabilities, professionalism, and communications skills necessary for them to excel in leadership positions in academia, industry, and government at the national and international levels.

Vision

Materials science and engineering is a multi-disciplinary field that is at the forefront of all emerging technologies. Advances in the understanding of the process-structure-property-performance relationships of materials will be critical for future developments, including those in energy storage and power generation, biomaterials and nanomaterials. The Department of Materials Science and Engineering at Drexel University is recognized as a leader in these areas through its teaching and scholarly research.

Program Educational Objectives

The educational objectives of the Materials Science and Engineering BS degree program are:

Materials Science and Engineering program graduates possess the core technical competencies in their field necessary to successfully interface with other engineering disciplines in the workplace.
At least 30% of Materials Science and Engineering program graduates have progressed towards graduate education, to become leaders in industry, academia, etc.
Materials Science and Engineering program graduates are leaders in their chosen fields.
Materials Science and Engineering program graduates are engaged in lifelong learning.
Materials Science and Engineering program graduates possess written and verbal communication skills appropriate for professional materials engineers and/or scientists.

Student Outcomes

The department’s student outcomes reflect the skills and abilities that the curriculum is designed to provide to students by the time they graduate. These are:

an ability to apply, formulate, and solve complex engineering problems by applying principles of engineering, science, and mathematics.
an ability to apply engineering design to produce solutions that meet specified needs with consideration of public health, safety, welfare, as well as global, cultural, social, environmental, and economic factors.
an ability to communicate effectively with a range of audiences.
an ability to recognize ethical and professional responsibilities in engineering situations and make informed judgments, which must consider the impact of engineering solutions in global, economic, environmental, and societal contexts.
an ability to function effectively on a team whose members together provide leadership, create a collaborative and inclusive environment, establish goals, plan tasks, and meet objectives.
an ability to develop and conduct appropriate experimentation, analyze and interpret data, and use engineering judgment to draw conclusions.
an ability to acquire and apply new knowledge as needed, using appropriate learning strategies.

Additional Information

The Materials Science and Engineering program is accredited by the Engineering Accreditation Commission of ABET.

For additional information about this major, contact:

Sarit Kunz
Academic Program Coordinator
215.895.2328
skunz@coe.drexel.edu

Degree Requirements

General Education/Liberal Studies Requirements
CIVC 101	Introduction to Civic Engagement	1.0
COOP 101	Career Management and Professional Development ^*	1.0
ENGL 101	Composition and Rhetoric I: Inquiry and Exploratory Research	3.0
or ENGL 111	English Composition I
ENGL 102	Composition and Rhetoric II: Advanced Research and Evidence-Based Writing	3.0
or ENGL 112	English Composition II
ENGL 103	Composition and Rhetoric III: Themes and Genres	3.0
or ENGL 113	English Composition III
PHIL 315	Engineering Ethics	3.0
UNIV E101	The Drexel Experience	1.0
Technical Electives/Track Courses (Choose one track) ^**		9.0
Materials for Energy
CHE 431	Fundamentals of Solar Cells
CHE 432	Electrochemical Engineering
ECE 380	Fundamentals of Power and Energy
ECEP 371	Introduction to Nuclear Engineering
ECEP 380	Introduction to Renewable Energy
ECEP 402	Theory of Nuclear Reactors
ECEP 403	Nuclear Power Plant Design & Operation
ECEP 480	Solar Energy Engineering
EET 320	Renewable Energy Systems
MATE 482	Materials for Energy Storage
MEM 415	Fuel Cell Engines
MEM 445	Solar Energy Fundamentals
Materials for Sustainability
CHE 430	Introduction to Sustainable Engineering
CHE 431	Fundamentals of Solar Cells
ECEP 380	Introduction to Renewable Energy
ECEP 480	Solar Energy Engineering
ENVE 316	Fundamentals of Environmental Biotechnology
ENVE 410	Solid and Hazardous Waste
ENVE 471	Environmental Life Cycle Assessment
MATE 476	Recycling of Materials
MATE 483	Environmental Effects on Materials
Materials for Medical Technology
BIO 201	Human Physiology I
BIO 311	Biochemistry
BMES 441	Biomechanics I: Introduction to Biomechanics
BMES 460	Biomaterials I
BMES 461	Biomaterials II
BMES 471	Cellular and Molecular Foundations of Tissue Engineering
BMES 472	Developmental and Evolutionary Foundations of Tissue Engineering
BMES 488	Medical Device Development
CHE 360	BioProcess Principles
CHE 461	Principles of Colloid Science
CHEM 371	Chemistry of Biomolecules
CHEM 375	The Chemistry Behind Drugs: Fundamentals of Medicinal Chemistry
MEM 424	Biomechanics
MEM 478	Computer-Aided Tissue Engr
Manufacturing
CHE 452	Polymer Process Technology
CHEM 242	Organic Chemistry II
CHEM 465	Synthetic Polymer Chemistry
CHEM 466	Physical Chemistry of Polymers
CHEM 467	Polymer Chemistry III
MEM 361	Engineering Reliability
MEM 417	Introduction to Microfabrication
MEM 427	Finite Element Methods
MEM 428	Introduction to Composites I
MEM 429	Introduction to Composites II
MEM 435	Introduction to Computer-Aided Design and Manufacturing
MEM 436	Introduction to Computer-Aided Manufacturing
MEM 437	Manufacturing Process I
MEM 438	Manufacturing Process II
General Education Electives ^***		12.0
Business Elective (GE) ^****		4.0
Societal Impact Elective (GE) ^‡		4.0
Free Electives		6.0
Foundation Requirements
BIO 107	Cells, Genetics & Physiology	3.0
BIO 108	Cells, Genetics and Physiology Laboratory	1.0
CHE 350	Statistics and Design of Experiments	3.0
CHEC 353	Physical Chemistry and Applications III	4.0
Chemistry Requirements ^†		3.5-7.5
CHEM 111 & CHEM 101	General Chemistry I and General Chemistry I
OR
CHEM 101	General Chemistry I
CHEM 102	General Chemistry II	4.5
CHEM 241	Organic Chemistry I	4.0
Engineering (ENGR) Requirements
ENGR 111	Introduction to Engineering Design & Data Analysis	3.0
ENGR 113	First-Year Engineering Design	3.0
ENGR 131	Introductory Programming for Engineers	3.0
or ENGR 132	Programming for Engineers
ENGR 210	Introduction to Thermodynamics	3.0
ENGR 220	Fundamentals of Materials	4.0
ENGR 231	Linear Engineering Systems	3.0
ENGR 232	Dynamic Engineering Systems	3.0
Mathematics Requirements ^††		4.0-10.0
MATH 105 & MATH 121	Algebra, Functions, and Trigonometry and Calculus I
OR
MATH 116 & MATH 117	Calculus and Functions I and Calculus and Functions II
OR
MATH 121	Calculus I
MATH 122	Calculus II	4.0
MATH 200	Multivariate Calculus	4.0
Physics Requirements ^††		4.0-8.0
PHYS 100 & PHYS 101	Preparation for Engineering Studies and Fundamentals of Physics I
OR
PHYS 101	Fundamentals of Physics I
PHYS 102	Fundamentals of Physics II	4.0
PHYS 201	Fundamentals of Physics III	4.0
Professional Requirements
MATE 214	Introduction to Polymers	4.0
MATE 230	Fundamentals of Materials II	4.0
MATE 240	Thermodynamics of Materials	4.0
MATE 245	Kinetics of Materials	4.0
MATE 280	Advanced Materials Laboratory	4.0
MATE 315	Processing Polymers	4.5
MATE 345	Processing of Ceramics	4.5
MATE 351	Electronic and Photonic Properties of Materials	4.0
MATE 355	Structure and Characterization of Crystalline Materials	3.0
MATE 366 [WI]	Processing of Metallic Materials	4.5
MATE 370	Mechanical Behavior of Solids	3.0
MATE 375	Materials Selection for Industrial Applications	3.0
MATE 410	Case Studies in Materials	3.0
MATE 455	Biomedical Materials	3.0
MATE 460	Engineering Computational Laboratory	4.0
MATE 475	Materials Data Analysis	3.0
MATE 491 [WI]	Senior Project Design I	2.0
MATE 492	Senior Project Design II	3.0
MATE 493 [WI]	Senior Project Design III	3.0
Total Credits		186.5-200.5

*

Co-op cycles for Materials Science & Engineering are only Spring/Summer.

COOP 101 registration is determined by the co-op cycle assigned and may be scheduled in a different term. Select students may be eligible to take COOP 001 in place of COOP 101.

Specialization tracks allow upper-class students to focus on a specific area of materials science and engineering through selection of three technical elective courses (minimum 9.0 credits). This tailored specialization, combined with foundational materials knowledge and co-op experiences, gives students a customized education to prepare them for their future career and/or graduate school. Students choose from four pre-determined specialization tracks or create their own track. In addition to the specific courses listed for each pre-determined track, other courses may be accepted subject to approval by the MSE advisor. Additional pre-requisites required for Track courses should be used to satisfy students' "Free Elective" credits. The pre-determined tracks are:

Materials for Energy
Materials for Medical Technologies
Materials for Sustainability
Manufacturing

***

General Education Electives

****

Choose one of the approved Business Electives (GE): ECON 201, ACCT 110, OPM 200, ORGB 300 [WI] or approved by MSE advisor.

‡

Choose one of the approved Societal Impact Electives (GE): SOC 244, SOC 346, SCTS 202, SCTS 205 or approved by MSE advisor.

†

CHEM sequence is determined by the student's Chemistry Placement Exam score and the completion of a summer online preparatory course available based on that score.

††

MATH and PHYS sequences are determined by the student's Calculus Placement Exam score and the completion of any summer online preparatory courses available based on that score.

Writing-Intensive Course Requirements

In order to graduate, all students must pass three writing-intensive courses after their freshman year. Two writing-intensive courses must be in a student's major. The third can be in any discipline. Students are advised to take one writing-intensive class each year, beginning with the sophomore year, and to avoid “clustering” these courses near the end of their matriculation. Transfer students need to meet with an academic advisor to review the number of writing-intensive courses required to graduate.

A "WI" next to a course in this catalog may indicate that this course can fulfill a writing-intensive requirement. For the most up-to-date list of writing-intensive courses being offered, students should check the Writing Intensive Course List at the University Writing Program . Students scheduling their courses can also conduct a search for courses with the attribute "WI" to bring up a list of all writing-intensive courses available that term.

Sample Plan of Study

4 year, 1 co-op

First Year
Fall	Credits	Winter	Credits	Spring	Credits	Summer	Credits
CHEM 101^*	3.5	CHEM 102	4.5	COOP 101^***	1.0	VACATION
ENGL 101 or 111	3.0	CIVC 101	1.0	ENGL 102 or 112	3.0
ENGR 111	3.0	ENGR 131 or 132	3.0	ENGR 113	3.0
MATH 121^**	4.0	MATH 122	4.0	MATH 200	4.0
UNIV E101	1.0	PHYS 101^**	4.0	PHYS 102	4.0
				General Education Elective^†	3.0
	14.5		16.5		18		0
Second Year
Fall	Credits	Winter	Credits	Spring	Credits	Summer	Credits
BIO 107	3.0	ENGL 103 or 113	3.0	Business Elective (GE)^****	4.0	CHEM 241	4.0
BIO 108	1.0	ENGR 210	3.0	General Education Electives^†	6.0	PHIL 315	3.0
ENGR 220	4.0	ENGR 232	3.0	Technical Elective/Track Course^††	3.0	Free Elective	3.0
ENGR 231	3.0	MATE 230	4.0			Technical Elective/Track Course^††	3.0
PHYS 201	4.0	Free Elective	3.0
Societal Impact Elective (GE)^‡	4.0
	19		16		13		13
Third Year
Fall	Credits	Winter	Credits	Spring	Credits	Summer	Credits
MATE 214	4.0	MATE 245	4.0	COOP EXPERIENCE		COOP EXPERIENCE
MATE 240	4.0	MATE 280	4.0
MATE 355	3.0	MATE 315	4.5
MATE 370	3.0	MATE 351	4.0
	14		16.5		0		0
Fourth Year
Fall	Credits	Winter	Credits	Spring	Credits
CHE 350	3.0	MATE 345	4.5	CHEC 353	4.0
MATE 366	4.5	MATE 375	3.0	MATE 410	3.0
MATE 455	3.0	MATE 475	3.0	MATE 493	3.0
MATE 460	4.0	MATE 492	3.0	Technical Elective/Track Course^††	3.0
MATE 491	2.0	General Education Elective^†	3.0
	16.5		16.5		13
Total Credits 186.5

*

CHEM sequence is determined by the student's Chemistry Placement Exam score and the completion of a summer online preparatory course available based on that score.

MATH and PHYS sequences are determined by the student's Calculus Placement Exam score and the completion of any summer online preparatory courses available based on that score.

***

Co-op cycles may vary. Students are assigned a co-op cycle (fall/winter, spring/summer, summer-only) based on their co-op program (4-year, 5-year) and major.

COOP 101 registration is determined by the co-op cycle assigned and may be scheduled in a different term. Select students may be eligible to take COOP 001 in place of COOP 101.

****

Choose one of the approved Business Electives (GE): ECON 201, ACCT 110, OPM 200, ORGB 300 [WI] or approved by MSE advisor.

‡

Choose one of the approved Societal Impact Electives (GE): SOC 244, SOC 346, SCTS 202, SCTS 205 or approved by MSE advisor.

†

See degree requirements.

††

Materials for Energy
Materials for Medical Technologies
Materials for Sustainability
Manufacturing

5 year, 3 co-op

First Year
Fall	Credits	Winter	Credits	Spring	Credits	Summer	Credits
CHEM 101^*	3.5	CHEM 102	4.5	COOP 101^***	1.0	VACATION
ENGL 101 or 111	3.0	CIVC 101	1.0	ENGL 102 or 112	3.0
ENGR 111	3.0	ENGR 131 or 132	3.0	ENGR 113	3.0
MATH 121^**	4.0	MATH 122	4.0	MATH 200	4.0
UNIV E101	1.0	PHYS 101^**	4.0	PHYS 102	4.0
				General Education Elective^†	3.0
	14.5		16.5		18		0
Second Year
Fall	Credits	Winter	Credits	Spring	Credits	Summer	Credits
BIO 107	3.0	CHEM 241	4.0	COOP EXPERIENCE		COOP EXPERIENCE
BIO 108	1.0	ENGL 103 or 113	3.0
ENGR 220	4.0	ENGR 210	3.0
ENGR 231	3.0	ENGR 232	3.0
PHYS 201	4.0	MATE 230	4.0
Free Elective	3.0
	18		17		0		0
Third Year
Fall	Credits	Winter	Credits	Spring	Credits	Summer	Credits
MATE 214	4.0	MATE 245	4.0	COOP EXPERIENCE		COOP EXPERIENCE
MATE 240	4.0	MATE 280	4.0
MATE 355	3.0	MATE 315	4.5
MATE 370	3.0	Societal Impact Elective (GE)	4.0
Business Elective (GE)	4.0
	18		16.5		0		0
Fourth Year
Fall	Credits	Winter	Credits	Spring	Credits	Summer	Credits
CHEC 353	4.0	MATE 345	4.5	COOP EXPERIENCE		COOP EXPERIENCE
MATE 366	4.5	MATE 351	4.0
MATE 455	3.0	MATE 375	3.0
Free Elective	3.0	PHIL 315	3.0
	14.5		14.5		0		0
Fifth Year
Fall	Credits	Winter	Credits	Spring	Credits
CHE 350	3.0	MATE 475	3.0	MATE 410	3.0
MATE 460	4.0	MATE 492	3.0	MATE 493	3.0
MATE 491	2.0	General Education Elective^†	3.0	General Education Elective^†	3.0
General Education Elective^†	3.0	Technical Elective/Track Course^††	3.0	Technical Elective/Track Course^††	3.0
Technical Elective/Track Elective^††	3.0
	15		12		12
Total Credits 186.5

*

CHEM sequence is determined by the student's Chemistry Placement Exam score and the completion of a summer online preparatory course available based on that score.

MATH and PHYS sequences are determined by the student's Calculus Placement Exam score and the completion of any summer online preparatory courses available based on that score.

***

Co-op cycles may vary. Students are assigned a co-op cycle (fall/winter, spring/summer, summer-only) based on their co-op program (4-year, 5-year) and major.

COOP 101 registration is determined by the co-op cycle assigned and may be scheduled in a different term. Select students may be eligible to take COOP 001 in place of COOP 101.

****

Choose one of the approved Business Electives (GE): ECON 201, ACCT 110, OPM 200, ORGB 300 [WI] or approved by MSE advisor.

‡

Choose one of the approved Societal Impact Electives: SOC 244, SOC 346, SCTS 202, SCTS 205 or approved by MSE advisor.

†

See degree requirements.

††

Specialization tracks allow upper-class students to focus on a specific area of materials science and engineering through selection of three technical elective courses (minimum 9.0 credits). This tailored specialization combined with foundational materials knowledge and co-op experiences gives students a customized education to prepare them for their future career and/or graduate school. Students choose from four pre-determined specialization tracks or create their own track. In addition to the specific courses listed for each pre-determined track, other courses may be accepted subject to approval by the MSE advisor. The pre-determined tracks are:

Materials for Energy
Materials for Medical Technologies
Materials for Sustainability
Manufacturing and Materials Processing

Co-op/Career Opportunities

Examples of industries in which materials science and engineering graduates play major roles include: base metals industries; specialist alloys; advanced ceramics; petrochemical; biomaterials and implants; pharmaceuticals; consumer products; electronics and photonics; nanotechnology; power generation; energy conversion, storage and conservation (fuel cells, advanced batteries, supercapacitors and photovoltaics); environmental protection and remediation; information and telecommunications; and transportation (aerospace, automotive, bicycles, railways).

Typical job functions include design and development of new materials, materials selection for specific applications, manufacturing, performance and failure analysis, quality control and testing, research and development, technical management, sales and marketing, teaching, technical services, and technical writing.

Please visit the Drexel Steinbright Career Development Center for more detailed information on co-op and post-graduate opportunities.

Dual/Accelerated Degree

Dual Degree Bachelor’s Programs

With careful planning, students can complete two full degrees in the time usually required to complete one. For detailed information, students should contact their advisors.

Accelerated Degree Program

The Accelerated Degree Program within the College of Engineering provides opportunities for highly talented and motivated students to progress toward their educational goals essentially at their own pace. Primarily through advance placement, credit by examination, flexibility of scheduling, and independent study, this “fast-track” makes it possible to complete both the undergraduate curriculum and master's level graduate studies in the five years required by the standard curriculum.

Bachelor’s/Master’s Accelerated Degree Program

Exceptional students can also pursue a master of science (MS) degree in the same period as the bachelor of science (BS). The combined BS/MS degree in Materials Science and Engineering differs from the standard BS degree in that there are two six-month Co-op periods instead of three, and in the last two years, the necessary graduate courses are taken.

For more information about this program, please visit the Department's BS/MS Degree Program page.

Facilities

Nanobiomaterials and Cell Engineering Laboratory
This laboratory contains a fume hood with vacuum/gas dual manifold, vacuum pump and rotary evaporator for general organic/polymer synthesis; gel electrophoresis and electroblotting for protein characterization; bath sonicator, glass homogenizer and mini-extruder for nanoparticle preparation; centrifuge; ultrapure water conditioning system; precision balance; pH meter and shaker.

Ceramics Processing Laboratory
This laboratory contains a photo-resist spinner, impedance analyzer, Zeta potential meter, spectrafluorometer, piezoelectric d33 meter, wire-bonder, and laser displacement meter.

Layered Solids Laboratory
This laboratory contains a vacuum hot-press; a hot isostatic press (HIP) for materials consolidation and synthesis; laser scattering particle size analyzer; creep testers, Ar-filled glove-box, high-speed saw, and assorted high temperature furnaces; metallographic preparation facilities; high temperature closed-loop servo-hydraulic testing machines.

Mechanical Testing Laboratory
This laboratory contains mechanical and closed-loop servo-hydraulic testing machines, hardness testers, Charpy and Izod impact testers, equipment for fatigue testing, metallographic preparation facilities and a rolling mill with twin 6" diameter rolls.

Macromolecular Materials Laboratory
This laboratory contains a hybrid rheometer, inert environment glove box, size exclusion chromatography with multi-angle laser light scattering, HPLC and RI detector & MALS, centrifuge, rotovapor, and vacuum oven used for developing innovative synthetic platforms to generate functional soft materials with complex macromolecular architectures.

Mesoscale Materials Laboratory
This laboratory contains instrumentation for growth, characterization, device fabrication, and design and simulation of electronic, dielectric, ferroelectric and photonic materials. Resources include physical and chemical vapor deposition and thermal and plasma processing of thin films, including oxides and metals, and semiconductor nanowire growth. Facilities include pulsed laser deposition, atomic layer deposition, chemical vapor deposition, sublimation growth, and resistive thermal evaporation. Variable-temperature high-vacuum probe station and optical cryostats including high magnetic field, fixed and tunable-wavelength laser sources, several monochromators for luminescence and Raman scattering spectroscopy, scanning electron microscopy with electron beam lithography, and a scanning probe microscope.

Nanomaterials Laboratory
This laboratory contains instrumentation for synthesizing, testing and manipulation of nanomaterials carbon and two dimensional carbides under microscope, high-temperature autoclaves, Sievert’s apparatus; glove-boxes; high-temperature vacuum and other furnaces for the synthesis of nano-carbon coatings and nanotubes; tube furnaces for synthesis of carbides and nitrides; potentiostat/galvanostat for electrochemical testings; ultraviolet-visible (UV-VIS) spectrophotometry; Raman spectrometers; Differential scanning calorimeter (DSC) and thermogravimetric analyzer (TGA) up to 1500 °C with mass spectrometer, Zeta potential analyzer; attrition mill, bath and probe sonicators, centrifuges; electro-spinning system for producing nano-fibers.

Functional Inorganic Materials Synthesis Laboratory
This laboratory contains gas cabinets and CVD furnaces for the synthesis of inorganic and hybrid materials for energy and environmental applications, including photocatalytic mixed anion materials, oxides and nitrides.

Films and Heterostructures Laboratory
This laboratory contains an oxide molecular beam epitaxy (MBE) thin film deposition system; physical properties measurement system (PPMS) for electronic transport and magnetometry measurements from 2 – 400K, up to 9 T fields; 2 tube furnaces.

Powder Processing Laboratory
This laboratory contains vee blenders, ball-mills, sieve shaker + sieves for powder classification, several furnaces (including one with controlled atmosphere capability); and a 60-ton Baldwin cold press for powder compaction.

Soft Matter Research and Polymer Processing Laboratories
These laboratories contain computerized thermal analysis facilities including differential scanning calorimeters (DSC), dynamic mechanical analyzer (DMA) and thermo-gravimetric analyzer (TGA); tabletop tensile tester; strip biaxial tensile tester; vacuum evaporator; spin coater; centrifuge; optical microscope with hot stage; liquid crystal tester; microbalance; ultrasonic cleaner; laser holographic fabrication system; polymer injection molder and single screw extruder.

Natural Polymers and Photonics Laboratory
This laboratory contains a spectroscopic ellipsometer for film characterization; high purity liquid chromatography (HPLC) system; refractometer; electro-spinning and touch-spinning systems for producing nano-fibers.

X-ray Tomography Laboratory
This laboratory contains a high resolution X-ray micro-tomography instrument and a cluster of computers for 3D microstructure reconstruction; mechanical stage, a positioning stage and a cryostage for in-situ testing.

Materials Characterization Core (MCC)
The Department of Materials Science & Engineering relies on the Materials Characterization Core facilities within the University for materials characterization and micro- and nano-fabrication. These facilities contain a number of state-of-the-art materials characterization instruments, including high resolution and variable pressure field-emission scanning electron microscopes (SEMs) with Energy Dispersive Spectroscopy (EDS) for elemental analysis, Orientation Image Microscopy (OIM) for texture analysis, various in-situ and in-operando stages (cryo mat, heating, tensile, 3- and 4-point bending, and electrochemistry); two Transmission Electron Microscopes (TEM) with STEM capability and TEM sample preparation equipment; a dual-beam focused ion beam (FIB) system for nano-characterization and nano fabrication; a Nanoindenter; an X-ray Photoelectron Spectrometer (XPS)/Electron Spectroscopy for Chemical Analysis (ESCA) system; X-Ray Diffractometers (XRD); and an X-ray microscope (NanoCT) with an in-situ tensile/compression temperature controlled stage.

More details of these instruments, information on how to access them, and instrument usage rates can be found at Drexel University’s Materials Characterization Core webpage.

Materials Science and Engineering Faculty

Michel Barsoum, PhD (Massachusetts Institute of Technology). Distinguished Professor. Processing and characterization of novel ceramics and ternary compounds, especially the MAX and 2-D MXene phases.

Hao Cheng, PhD (Northwestern University). Associate Professor. Drug delivery, molecular self-assembly, cell-nanomaterial interactions, regenerative medicine and cell membrane engineering.

Yury Gogotsi, PhD (Kiev Polytechnic Institute) Director, A. J. Drexel Nanotechnology Institute. Distinguished University & Charles T. and Ruth M. Bach Professor. Nanomaterials; carbon nanotubes; nanodiamond; graphene; MXene; materials for energy storage, supercapacitors, and batteries.

Yong-Jie Hu, PhD (Penn State University). Assistant Professor. Computational design and evaluation of mechanical, thermodynamic, and electronic properties using first-principles calculations, molecular dynamic simulations, the CALPHAD approach, multiscale modeling, and machine learning approaches.

Richard Knight, PhD (Loughborough University) Associate Department Head and Undergraduate Advisor. Teaching Professor. Thermal plasma technology; thermal spray coatings and education; plasma chemistry and synthesis.

Christopher Y. Li, PhD (University of Akron) Graduate Advisor. Professor. Soft and hybrid materials for optical, energy, and bio applications; polymeric materials, nanocomposites, structure and properties.

Andrew Magenau, PhD (University of Southern Mississippi). Assistant Professor. Structurally complex materials exhibiting unique physical properties designed and fabricated using an assortment of methodologies involving directed self-assembly, externally applied stimuli, structure-function correlation, and applied engineering principles suited for technologies in regenerative medicine, biological interfacing, catalytic, electronic, and optical applications

Michele Marcolongo, PhD, PE (University of Pennsylvania). Professor Emerita. Orthopedic biomaterials; acellular regenerative medicine, biomimetic proteoglycans; hydrogels.

Steven May, PhD (Northwestern University) Department Head. Professor. Synthesis of complex oxide films, superlattices, and devices; magnetic, electronic, and quantum materials; x-ray and neutron scattering.

Ekaterina Pomerantseva, PhD (Moscow State University, Russia). Associate Professor. Solid state chemistry; electrochemical characterization, lithium-ion batteries, energy generation and storage; development and characterization of novel nanostructured materials, systems and architectures for batteries, supercapacitors and fuel cells.

Caroline L. Schauer, PhD (SUNY Stony Brook) Associate Dean, Faculty Affairs College of Engineering. Professor. Polysaccharide thin films and nanofibers.

Wei-Heng Shih, PhD (Ohio State University). Professor. Colloidal ceramics and sol-gel processing; piezoelectric biosensors, optoelectronics, and energy harvesting devices; nanocrystalline quantum dots for bioimaging, lighting, and solar cells.

Jonathan E. Spanier, PhD (Columbia University) Department Head, Mechanical Engineering and Mechanics. Professor. Light-matter interactions in electronic materials, including ferroelectric semiconductors, complex oxide thin film science; laser spectroscopy, including Raman scattering.

Jörn Venderbos, PhD (Leiden University). Assistant Professor. Theory of quantum materials: topological Insulators, topological semimetals, materials prediction and design, strongly correlated electron materials, complex electronic ordering phenomena, unconventional superconductors

Christopher Weyant, PhD (Northwestern University). Teaching Professor. Engineering education

Antonios Zavaliangos, PhD (Massachusetts Institute of Technology) A.W. Grosvenor Professor. Professor. Constitutive modeling; powder compaction and sintering; pharmaceutical tableting, X-ray tomography.

Emeritus Faculty

Roger D. Corneliussen, PhD (University of Chicago). Professor Emeritus. Fracture, blends and alloys, as well as compounding.

Roger D. Doherty, PhD (Oxford University). Professor Emeritus. Metallurgical processing; thermo-mechanical treatment.

Ihab L. Kamel, PhD (University of Maryland). Professor Emeritus. Nanotechnology, polymers, composites, biomedical applications, and materials-induced changes through plasma and high energy radiation.

Jack Keverian, PhD (Massachusetts Institute of Technology). Professor Emeritus. Rapid parts manufacturing, computer integrated manufacturing systems, strip production systems, technical and/or economic modeling, melting and casting systems, recycling systems.