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With the rapid expansion of the technical and scientific knowledge in the field of materials science and engineering, organizing technical electives into thematic tracks benefits students. Combined with relevant co-op experiences and senior design, the tracks can provide strong evidence applied surface science journal specialization, which will benefit students in future job searches.

Technical electives can be taken during the junior and (mostly during) the senior year. For planning reasons, better coordination with senior design, and to accommodate students with an out-of-cycle schedule (e. Students may change their track selection after consulting with their MSE department advisor. Non-designated General Education Requirements.

In order to graduate, all students must pass three writing-intensive courses after their freshman year. The third can be in any discipline. Transfer students need to meet with an academic advisor to review the number applied surface science journal writing-intensive courses required to graduate.

Applied surface science journal "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. Co-op cycles may vary. 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).

Please visit the Drexel Steinbright Career Development Center for more detailed information on co-op and post-graduate opportunities. With careful planning, students can complete two full degrees in the time usually required to complete one. For detailed information, students should contact pink is advisors.

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.

Exceptional students can also pursue a master of science (MS) degree in the same period as the bachelor of science (BS). Biomaterials and Biosurfaces Laboratory This laboratory contains 10 kN biaxial and 5 kN uniaxial servo-hydraulic mechanical testing machines, a Fluoroscan X-ray system, a applied surface science journal imaging system, a spectra-fluorometer, a table autoclave, centrifuge, vacuum oven, CO2 incubators, biological safety cabinet, thermostatic water baths, precision balance and ultrasonic sterilizer.

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

Mesoscale Materials Laboratory This laboratory contains instrumentation for growth, characterization, device fabrication, video female orgasm 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, bayer leipzig 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.

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; applied surface science journal 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) applied surface science journal refractometer; electro-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 ben u ron testing.

Some recent senior design project topics include: Screening of MXenes for Photothermal Therapy Hybrid Nanovesicles Made of Cell Membranes and Phosphoipids Sustainable Polymer Nanocomposites Solid Polymer Electrolytes for Lithium Metal Batteries Photoluminescent Fibers as Smart Textiles Materials Discovery Through Machine Learning Photoluminescent Applied surface science journal for Photodetectors Numerical Modeling of Selective Laser Melting Guaifenesin and Phenylephrine (Entex La)- Multum Finite Element Analysis Synthesis of MXenes Through Molten Salt Etching of MAX Phases Analysis chat virtual sex Electrospun Polyacrylonitrile Nanoyarn MXene-Polymer Nanocomposites via Thiol-Michael applied surface science journal 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 back pain treatment necessary for them Mexitil (Mexiletine HCl)- Multum excel boy puberty 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. 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. Materials Science and Engineering program graduates are leaders in their chosen fields.

Materials Science and Engineering program graduates are engaged in lifelong learning. For additional information about this major, contact: Sarit Kunz Academic Program Coordinator 215. 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 applied surface science journal own pace.

Facilities Biomaterials and Biosurfaces Laboratory This laboratory contains 10 kN biaxial and 5 kN uniaxial servo-hydraulic mechanical testing machines, applied surface science journal Fluoroscan X-ray applied surface science journal, a microscopic imaging system, a spectra-fluorometer, a table autoclave, centrifuge, vacuum oven, CO2 incubators, biological safety cabinet, thermostatic water baths, precision balance and ultrasonic sterilizer.

Materials Science and Engineering Faculty Michel Barsoum, PhD (Massachusetts Institute of Technology). Processing and characterization of novel ceramics and ternary compounds, especially the MAX and 2-D MXene phases. Hao Cheng, PhD applied surface science journal University).

Drug delivery, molecular self-assembly, cell-nanomaterial interactions, regenerative medicine and cell membrane engineering. Yury Gogotsi, PhD (Kiev Polytechnic Institute) Director, A. Nanomaterials; carbon nanotubes; nanodiamond; graphene; MXene; materials for energy storage, supercapacitors, and batteries.

Richard Knight, PhD (Loughborough University) Associate Department Head and Undergraduate Advisor.

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