Schools & Programs
The Aeronautics and Astronautics curriculum emphasizes the disciplines of aerodynamics, aerospace systems, astrodynammics and space applications, propulsion, structures and materials, dynamics and control, and further provides courses that integrate these disciplines into the design of flight vehicles to perform the required mission.
The field of aeronautical and astronautical engineering addresses the challenging problems encountered in the design and operation of many types of aircraft, missiles, and space vehicles and places a constant demand on research and development groups for an even greater understanding of basic physical phenomena.
Employers from around the world contact the School of Aeronautics and Astronautics with information regarding positions available within their organizations.
Agricultural Engineering prepares engineers with specialized expertise to design and analyze new and environmentally sound ways of utilizing natural resources.
Machine systems engineering prepares engineers with backgrounds in areas like mechanical design, hydraulics, instrumentation and control, and electronics and sensors to design and operate machines and systems for agricultural and biological products and processes.
Biological Engineering prepares graduates to apply basic scientific and engineering principles to the design, development, and operation surrounding the large-scale manufacturing of food and biologically based products. Such products are environmentally friendly and renewable, representing a future wave of consumer demand for better health and environment.
Biomedical Engineering applies principles and methods of engineering and life sciences to design solutions for human biology and medicine.
Undergraduate students take life-science courses in combination with engineering design courses, studying physical and chemical properties of human tissues in order to design more effective implants. Other areas and projects include cell and tissue research, as well as the design of new biomaterials for use in medical therapies.
The Weldon School of Biomedical Engineering will be housed in a state-of-the-art building designed to enhance both teaching and research. The $25-million, 91,000-square-foot facility (to be completed in spring 2006) will accommodate the rapid growth of biomedical engineering and its exponential increase in job opportunities.
Programs of focus include biomaterials, musculoskeletal biomechanics, tissue engineering, medical imaging, cardiovascular instrumentation, therapeutic and diagnostic devices, and biological signal processing.
Chemical Engineering remains a premier source of well-educated, well-prepared chemical engineers, educating students using innovative technologies and fostering an environment that inspires leading-edge research.
Chemical engineers work in a wide range of industries with worldwide impact. Applications include energy; pharmaceuticals and biological materials; the nutritional value of food; environmental protection and restoration; materials for computing, sensing, and communications; personal care, home care, and home health products; and system and data management.
Facilities construction includes a five-story addition to the current building, remodeling the existing facility, and equipping both with state-of-the-art technologies and instrumentation. The new facility will meet the current and anticipated learning and research requirements of ChE students and faculty.
Research here is currently being conducted with polymers and materials, nanoscale science and engineering, fluid mechanics, catalyst design and engineering, sensors, biotechnology, and many others.
Civil engineers design and construct the world's infrastructure: buildings and bridges; tunnels, dams, and levees; harbors and canals; water-supply and waste-disposal systems; airports, highways, and railroads; pipelines and power lines.
Instructional laboratories in structural behavior, hydraulics, surveying, and civil engineering materials are offered in the sophomore and junior years. Further study includes 30 credits of technical electives allowing students to tailor their studies to their sub-discipline of choice. Sub-disciplines include construction, environmental, geotechnical, hydraulics, materials, structures, surveying, and transportation.
Senior design projects consist of real-world applications in theoretical role play. Recent projects have included designing possible layouts for the proposed US-231 bypass that will run around the perimeter of campus to connect its north and south ends. Another project explored adding box seats to our basketball arena by raising the roof to make room. Students participate in these projects from site exploration, to budget management, to mock designs.
The Division of Construction Engineering and Management (CEM) offers a degree in Construction Engineering (BSCNE) which is tailored to prepare graduates for professional work in the construction industry. The Construction Engineering curriculum includes about 80 percent engineering courses and 20 percent management courses focused on the knowledge necessary for construction careers.
For over 18 years in a row BSCNE graduates have been hired at a 100-percent rate upon graduation by some of the 100 top U.S. construction firms
Many construction engineers move into senior management, attaining executive positions and even ownership in a construction firm. These professionals have a passion for building structures and collaborating with a wide range of people, as well as a desire to learn in a constantly changing world.
Two degree programs are offered by the school:
Electrical Engineering encompasses the development, design, research, and operation of electrical and electronic systems and components. Disciplines include VLSI and circuit design, communication and signal processing, computer engineering, automatic control, fields and optics, energy sources and systems, and microelectronics and nanotechnology.
Computer Engineeringis a specialization within electrical and computer engineering offering an in-depth education in both hardware and software aspects of modern computer systems.
Students develop a strong foundation in math, science, and core electrical/computer engineering fundamentals, plus problem-solving and design skills that prepare them for research and development positions in industry, management, sales, teaching, medical school, and law school.
At Birck Nanotechnology Center engineers and scientists conduct research in emerging fields where new materials and tiny structures are built atom by atom, or molecule by molecule.
The First-Year Engineering Program is a student-oriented, service program tasked with recruiting, advising, teaching, and retaining outstanding Purdue Engineering students. The first-year curriculum provides a solid academic foundation and overview of engineering fields and careers.
The Interdisciplinary Engineering Studies Program is for the undergraduate engineering student who want an engineering education but do not plan to practice engineering (eg. Pre-Medical Engineering Studies).
The Multidisciplinary Engineering Program is for students who want to practice engineering but whose career goals cannot be accommodated within a traditional engineering field. The MDE Program is a concentration that undergraduate students interested in bringing together multiple engineering disciplines at an advanced level to solve societal challenges.
The graduate programs serve students interested in studying the science of learning engineering. They focus on engineering education discovery, scholarship, and academic reform.
Environmental and Ecological engineers use the principles of systems engineering, biology, and chemistry to develop strategies to protect human and environmental health. Our unique name, Environmental and Ecological Engineering, was chosen to highlight our approach to managing complex problems with an integrated perspective that considers both environmental issues and ecological interactions. In the undergraduate curriculum there is an early focus on systems thinking and systems understanding with the inclusion of significant course requirements in ecology, sustainability, and industrial ecology. The EEE program strives for resilient design thinking that takes into account complexity and connectivity between systems.
Employment opportunities for EEE graduates are excellent. The U.S. Dept. of Labor projects substantial growth in jobs for the foreseeable future. Starting salaries are comparable to other Engineering fields and opportunities for advancement to positions of responsibility are excellent.
Among the 14 “Grand Challenges of Engineering” announced by the National Academy of Engineering six of the 14 are explicitly in the domain of Environmental and Ecological engineering. Environmental engineering has a clear impact on societies and quality of life. Students interested in engineering that can make a positive difference for people should consider Environmental and Ecological Engineering. Meet with an advisor or faculty member to craft an individualized plan of study to meet your career goals.
Research within Environmental and Ecological Engineering may be characterized as being multidisciplinary and focused on cutting edge issues. The EEE discovery mission is positioned to respond to society’s need to understand the world we live in, and to develop strategies for sustainably managing Earth’s limited resources and ecosystems so that they will be available for generations to come. Topics emphasized within the EEE research portfolio include: environmental fate of air, water, and soil contaminants; sustainable urban design; renewable energy and the water-energy nexus; water and wastewater treatment; sustainable industrial systems; water, air, and nutrient cycling; sustainability engineering education; bio-based materials and products; industrial ecology and industrial processes; air quality.
Industrial Engineering entails designing and controlling complex systems and procedures for using production resources (people, information, equipment, and materials). The applications of industrial engineering principles can be found in manufacturing, postal/package delivery services, airlines, space programs, hospitals, banks, amusement parks, etc.
Senior design projects consist of a real-world application of IE principles by teaming students with a local industry in Indiana. Teams have taken on full-scale projects like designing floor layouts for factories and hospitals, designing operations to improve system efficiency, reducing time and waste in processing, allocating resources to optimize system performance, and developing a safety plan for preventing work-related injuries.
Disciplines in the major include production, operation research, manufacturing, and human factors.
In everything we build—cars, planes, boats, computers, cell phones, bridges, skyscrapers, dental implants—the properties of the materials used determine the product's performance.
Materials Engineering's academic programs have been developed around broad and basic phenomena, applied to all major classes of artificial materials—ceramics, metals, glasses, polymers, and semiconductors. The undergraduate and graduate programs integrate our faculty strengths across the field's four cornerstones: structure, properties, processing, and performance.
Purdue's School of Materials Engineering is dedicated to meeting the materials needs of modern society through:
Learning—training the next generation of materials experts for every industrial sector;
Outreach—providing leadership within the materials profession;
Mechanical engineering involves designing machinery that either produces, transmits, or uses power.
The school's facilities include two major satellite research laboratories: The Ray W. Herrick Laboratories provide facilities for research in mechanical vibrations, noise control, acoustics, fluid mechanics, and heat transfer for energy utilization. The Zucrow Laboratories, named after their founder, started out in 1948 as one of the country's first liquid-rocket test facilities. Research in the laboratories, located next to the Purdue Airport, has expanded into combustion, propulsion, and fluid dynamics.
The School of Mechanical Engineering is organized into the following nine areas: combustion, energy utilization, and thermodynamics; design; fluid mechanics; heat transfer; mechanics; systems, measurement, and control; manufacturing and materials processing; noise and vibration control; and heating, ventilation, air conditioning, and refrigeration.
Nuclear engineering is firmly grounded in the understanding and application of modern physics. It has demonstrated vast potential for growth in power generation, medicine, industrial processes, plasmas, space technologies, and national defense.
Nuclear engineers at Purdue contribute to such advanced technologies as fission and fusion power generators, new medical technologies and procedures, improved food safety, advanced materials processing, advanced imaging, and the safe treatment and disposal of spent nuclear fuel.
Students experience the small-classroom feel because Nuclear Engineering has approximately 110 undergraduate students and 12 professors.
Indiana's first and only nuclear reactor has its home in Purdue University's Electrical Engineering Building. It headlines field trips for high-school juniors and seniors who participate in demonstrations and experiments.