MS in Accounting
Northeastern University in Boston offers a robust MS in Accounting pro...
MS in Applied Physics and Engineering
Boston
INTAKE: Jan & Sept
Program Overview
The MS in Applied Physics and Engineering program at Northeastern University provides a strong foundation in both the theoretical aspects of physics and the practical applications in engineering. Students are prepared for careers in research, technology, and industry by gaining proficiency in advanced physics concepts, engineering principles, and computational methods. The program is ideal for individuals who wish to deepen their understanding of the physical world and use this knowledge to develop solutions in areas such as renewable energy, semiconductor devices, and biomedical engineering.
Curriculum: The curriculum of the MS in Applied Physics and Engineering is designed to blend fundamental physics with engineering applications. Core courses include topics such as classical mechanics, quantum mechanics, thermodynamics, and solid-state physics. Alongside these foundational courses, students can choose specialized electives based on their career interests in areas like nanotechnology, materials science, photonics, and renewable energy. Students are also required to complete a capstone project or thesis that allows them to apply their learned skills to solve real-world engineering problems, providing hands-on experience in their chosen field of study.
Research Focus: Northeastern University emphasizes research within the MS in Applied Physics and Engineering program, providing students with opportunities to engage in cutting-edge projects. Research topics are highly interdisciplinary and may include quantum materials, optoelectronics, photonic devices, nanomaterials, and sustainable energy solutions. Students collaborate with faculty members on innovative research, often working alongside industry partners and research labs to address pressing global challenges, including the development of next-generation electronics and energy-efficient technologies.
Industry Engagement: Northeastern University’s commitment to experiential learning is evident in the MS in Applied Physics and Engineering program. Through the university’s renowned co-op program, students have the opportunity to gain hands-on industry experience by working with top companies in fields like technology, telecommunications, energy, and manufacturing. This co-op model ensures that students are well-prepared to apply their academic knowledge to practical engineering challenges and gain valuable insights into the day-to-day operations of industry leaders. The program’s close ties with local and global industries also provide students with a platform to build their professional networks and gain access to job opportunities upon graduation.
Global Perspective: The MS in Applied Physics and Engineering program at Northeastern University takes a global approach to problem-solving by encouraging students to engage in international collaborations and research. With a diverse student body and faculty, the program fosters an environment of cross-cultural exchange and global perspectives. The university’s strong ties to global research institutions and industries allow students to participate in collaborative projects that address worldwide issues such as energy sustainability, climate change, and the development of advanced materials. Students are encouraged to think beyond borders and apply their learning to create solutions that have a global impact.
Location
Boston
Score
IELTS 6.5
Tuition Fee
USD 59616
Postgraduate Entry Requirements
Academic Qualifications: Applicants for postgraduate programs typically require a minimum academic achievement of 70% or above in their bachelor's degree.
English Language Proficiency:
- IELTS: Overall band score of 6.5 with a minimum of 6.0 in each component.
- TOEFL: Overall score of 79 or higher.
- PTE: Overall score of 53 or higher.
- DET (Duolingo English Test): Minimum score of 105.
Northeastern University in Boston offers a range of scholarship opportunities for international students to help alleviate the financial burden of studying in the United States. These scholarships are designed to support academically talented students from around the world, promoting diversity and fostering an inclusive campus environment.
Merit-Based Scholarships: Northeastern University provides merit-based scholarships to international students based on academic excellence and achievements. These scholarships are awarded during the admissions process and are highly competitive. The amount and criteria for these scholarships may vary, but they aim to recognize students who demonstrate exceptional academic performance, leadership potential, and a strong their chosen field of study.
Northeastern International Scholars Program: This prestigious program offers scholarships to outstanding international students who exhibit leadership, academic excellence, and a desire to contribute to the global community. The Northeastern International Scholars Program provides both financial support and opportunities for personal growth through networking events, leadership training, and involvement in community service initiatives.
Need-Based Financial Aid: Although Northeastern University does not offer need-based financial aid to international students, there are still many merit-based scholarships available that can significantly reduce tuition costs. However, international students are encouraged to seek external scholarships or funding from their home country to help cover the remaining costs.
External Scholarships and Funding: In addition to institutional scholarships, international students at Northeastern University can explore a variety of external scholarship opportunities from governments, foundations, and organizations in their home countries. Many international students receive funding from these sources to support their education at Northeastern.
Graduates of the MS in Applied Physics and Engineering program from Northeastern University are equipped with a versatile set of skills that open up numerous career opportunities in a variety of high-tech and engineering fields. By combining theoretical physics with practical engineering applications, graduates are well-prepared for roles in industries such as electronics, renewable energy, aerospace, telecommunications, nanotechnology, and materials science.
Research and Development (R&D) Engineer: Graduates can pursue R&D roles in both academia and industry, working on cutting-edge projects in fields such as nanotechnology, photonics, and energy systems. They contribute to the design and development of new technologies and innovations, such as more efficient semiconductors, advanced materials, or renewable energy solutions.
Materials Scientist/Engineer: With a deep understanding of solid-state physics and materials science, graduates can become materials scientists, applying their knowledge to create and optimize materials for a wide range of applications. They might work on designing new materials for use in electronics, batteries, or aerospace components.
Photonics Engineer: Graduates with an interest in light-based technologies can work as photonics engineers, developing and optimizing optical systems and devices. This could involve designing lasers, optical sensors, or fiber-optic communication systems used in telecommunications, healthcare, and defense.
Quantum Engineer: The MS in Applied Physics and Engineering program equips students with knowledge of quantum mechanics, making them suitable for roles in quantum computing, quantum cryptography, and quantum communication. Quantum engineers work on building and improving quantum systems for applications in computing, security, and scientific research.
Electronics Engineer: Graduates can also pursue careers in electronics engineering, where they apply principles of applied physics to design and test electronic devices and circuits. Their work may involve developing next-generation semiconductors, sensors, or microelectronics used in consumer electronics, automotive technology, or telecommunications.
Renewable Energy Engineer: With a focus on sustainability, graduates can enter the growing field of renewable energy engineering. They may work on designing and improving solar panels, wind turbines, energy storage systems, and other technologies aimed at reducing reliance on fossil fuels and improving energy efficiency.
Aerospace Engineer: Graduates can also work in aerospace engineering, where they apply principles of physics and engineering to the design, testing, and production of aircraft and spacecraft. This might involve working on propulsion systems, avionics, or materials for lightweight, durable structures.
Nanotechnology Engineer: With their expertise in nanomaterials and nanotechnology, graduates are well-suited for roles in industries that develop nanoscale devices and systems. They can work on applications in medicine, electronics, and environmental technology, such as drug delivery systems, nanosensors, or energy-efficient nanomaterials.
Computational Physicist: Graduates with strong computational skills may pursue careers as computational physicists, using simulations and mathematical models to solve complex problems in engineering and applied physics. These professionals often work in research institutions, high-tech companies, or government agencies.
Biomedical Engineer: Graduates with an interest in healthcare can apply their physics and engineering knowledge to biomedical engineering, where they may work on the development of medical devices, diagnostic tools, or biocompatible materials used in medical implants and treatments.
Systems Engineer: Graduates can also pursue careers as systems engineers, applying applied physics and engineering principles to design, analyze, and optimize complex systems. These roles are common in industries such as defense, telecommunications, and manufacturing, where the integration of hardware and software is critical.
Environmental Engineer: Graduates may also choose to work in environmental engineering, using their skills to develop technologies and systems that address environmental challenges. This could include work on pollution control, water treatment, or the development of sustainable energy solutions.
Academic or Research Scientist: For those interested in continuing their studies or contributing to scientific knowledge, graduates may pursue academic careers as professors or researchers in applied physics, engineering, or related fields. They may conduct studies on emerging technologies, advanced materials, or new applications of physics in engineering.
Product Development Engineer: Graduates can work in product development, where they apply engineering principles and physics knowledge to create new products or improve existing ones. These roles typically involve working closely with cross-functional teams to design, test, and launch products in various sectors, including consumer electronics, medical devices, or industrial equipment.
