TUS Campuses

The Faculty of Chemical Technology and Engineering Campus is a key site for programs in chemistry and process engineering, housed in modern laboratories that support research in sustainable materials and industrial processes. This location focuses on advancing chemical sciences for industrial applications, with a commitment to environmental protection and innovation.

• Chemical Technology: Core courses include organic and inorganic synthesis, catalysis, and polymer science, where students synthesize compounds and study reaction kinetics. Emphasis is on green chemistry principles to develop eco-friendly production methods for pharmaceuticals and fine chemicals.
• Process Engineering: This program teaches the design and optimization of chemical plants, covering heat and mass transfer, reactor design, and process control. Hands-on training uses pilot plants to simulate industrial operations, focusing on energy efficiency and waste minimization.
• Biochemical Engineering: Integrating biology and chemistry, courses explore fermentation processes, enzyme technology, and biofuels production. Students conduct experiments in bioreactors and analyze metabolic pathways for applications in biotechnology and food industries.
• Materials Engineering: Focused on advanced materials like composites, nanomaterials, and biomaterials, the curriculum includes characterization techniques, mechanical testing, and surface engineering. Projects involve developing corrosion-resistant coatings for marine environments.
• Environmental Protection in Chemical Industry: Programs address pollution prevention, wastewater treatment, and air quality control, teaching remediation technologies and life-cycle assessment to ensure sustainable industrial practices.

The campus boasts advanced analytical equipment, such as NMR spectrometers and chromatography systems, enabling cutting-edge research in nanotechnology and renewable resources. Collaborations with chemical industries provide practical training and job placements. The curriculum incorporates computational modeling with software like Aspen Plus for process simulation, preparing students for roles in R&D, production, and consulting. Elective courses in industrial safety and economics broaden perspectives. Through seminars and international workshops, students engage with global challenges like circular economy and carbon capture. This campus plays a pivotal role in fostering chemical innovation, supporting regional industries in petrochemicals and agriculture, and contributing to sustainable development goals with a rigorous, research-oriented approach.

The Faculty of Maritime Technology Campus specializes in nautical and maritime engineering programs, leveraging Szczecin's strategic location near the Baltic Sea and its historical shipbuilding heritage. This campus is dedicated to training professionals for the maritime industry, emphasizing safety, efficiency, and sustainability in sea transport and offshore operations.

• Naval Architecture and Marine Engineering: Students learn ship design, hydrodynamics, and structural integrity of vessels, using software for modeling hull forms and propulsion systems. Courses include stability analysis, resistance prediction, and the integration of green technologies like hybrid propulsion to reduce emissions.
• Mechatronics in Maritime Applications: This program combines mechanical, electrical, and computer engineering for maritime automation, covering robotics for underwater exploration, sensor technologies, and control systems for ship navigation. Practical sessions involve simulating vessel maneuvers and designing automated cargo handling systems.
• Transport Engineering with Maritime Focus: Emphasizing logistics, port management, and supply chain optimization, courses address multimodal transport, including sea routes, with topics on international trade regulations, risk assessment, and sustainable port development.
• Offshore Engineering: Focused on oil, gas, and renewable energy platforms, the curriculum includes wind farm design, subsea engineering, and structural dynamics in harsh marine environments. Students participate in projects modeling wave loads and fatigue analysis for offshore structures.
• Maritime Safety and Security: Programs cover risk management, emergency response, and cybersecurity in shipping, teaching compliance with IMO standards, accident investigation, and the use of AI for predictive maintenance on vessels.

The campus features specialized facilities like hydrodynamic labs, ship simulators, and collaboration with local shipyards, providing internships and research in arctic navigation and autonomous ships. Interdisciplinary electives in environmental maritime law and economics prepare students for regulatory and business aspects of the industry. With a strong emphasis on international standards, graduates are equipped for careers in global shipping companies, naval forces, and offshore energy sectors. The curriculum fosters innovation through thesis projects on topics like LNG carriers and eco-friendly hull coatings, contributing to Poland's maritime economy and EU blue growth strategies. Student organizations and conferences enhance networking and practical exposure, ensuring a holistic education in this vital field.

The Main Campus of the Technical University of Szczecin, now known as the West Pomeranian University of Technology, offers a comprehensive range of engineering and technical programs designed to equip students with cutting-edge knowledge and practical skills. This campus serves as the central hub for most undergraduate and graduate studies, focusing on disciplines that drive innovation in technology and industry.

• Mechanical Engineering: Students delve into the design, analysis, and manufacturing of mechanical systems, covering topics such as thermodynamics, fluid mechanics, materials science, and computer-aided design (CAD). The program emphasizes hands-on projects, including the development of prototypes using advanced simulation software and laboratory experiments to understand machine dynamics and energy systems.
• Civil Engineering: This course explores the planning, construction, and maintenance of infrastructure, including structural analysis, geotechnics, hydrology, and sustainable building practices. Courses integrate environmental considerations, teaching students to create resilient structures that withstand natural disasters while minimizing ecological impact.
• Electrical Engineering: Focused on power systems, electronics, and control technologies, the curriculum includes circuit theory, electromagnetics, digital signal processing, and renewable energy sources. Practical training involves working with microcontrollers, automation systems, and smart grid technologies to prepare for careers in energy and telecommunications.
• Computer Science and Information Technology: Programs cover algorithms, programming languages (such as Python, Java, and C++), artificial intelligence, cybersecurity, and software engineering. Students engage in real-world applications like developing mobile apps, machine learning models, and database systems, fostering skills in data analysis and cloud computing.
• Chemical Engineering: This field addresses process design, reaction engineering, and biochemical processes, with emphasis on sustainable chemical production, nanotechnology, and environmental engineering. Laboratory work includes synthesizing materials and optimizing industrial processes for efficiency and safety.
• Environmental Engineering: Courses tackle pollution control, waste management, and water resource engineering, integrating biology, chemistry, and engineering principles to develop solutions for climate change and urban sustainability.
• Biotechnology: Combining biology with engineering, this program explores genetic engineering, bioprocesses, and medical biotechnology, preparing students for advancements in pharmaceuticals, agriculture, and food technology.

Additionally, the campus offers interdisciplinary programs in management and economics tailored for technical professionals, including courses on project management, innovation, and entrepreneurship. These programs often include international exchanges and industry partnerships, ensuring graduates are competitive in global markets. Research opportunities abound, with state-of-the-art labs supporting theses on topics like robotics, renewable materials, and smart cities. The curriculum is regularly updated to align with EU standards and industry needs, promoting a blend of theoretical foundations and practical expertise. Extracurricular activities, such as engineering clubs and hackathons, further enhance learning. Overall, the Main Campus provides a robust educational environment that nurtures future leaders in technology and science, contributing to regional and national development through applied research and innovation initiatives.