Are you interested in working in a dynamic team consisting of academic and industrial partners, and contributing to the ongoing energy transition by doing research with a high level of scientific.
Job description
Electrical power systems continuously change their conventional structure which considers dispatchable synchronous generators and unpredictable load demand. The increasing share of power inverter-based resources (IBRs, such as PV, wind power, BESS), and complex demand resources (EVs, H2, datacentres, heat pumps, other converter-interfaced loads) orients system operators’ interests to the dynamic security of the power system. The Continental Europe Synchronous Area (CESA) is a large synchronous electrical grid, historically considered resilient to frequency disturbances. System splits are quite severe events in which the system faces major challenges to avoid a black-out in either of the islands, as could be seen during several recent events in the past several years. As the renewable trends are only expected to continue, it is necessary to investigate possible severe frequency excursions in low-inertia situations to minimize the risk of cascading faults, frequency and voltage instabilities, and potential blackouts. Developing novel and advanced emergency load control and shedding algorithms, by also utilizing grid-forming inverters able to operate rapidly and effectively in low-inertia power systems and scenarios, can contribute to arresting the frequency deviation, and consequently ensuring that the system preserves the integrity and stability.
The Postdoc position is in line with an ongoing PhD position and will facilitate and extend this work. The ongoing research work includes extensive studies to evaluate the impact of evolving generation and demand on frequency stability. It also includes renewable energy sources such as wind, solar, and BESS, as well as electric vehicles (EVs), heat pumps, datacentres, and other converter-integrated loads. The utilization of grid-forming and grid-following converters in low-inertia systems, and the impact on frequency stability should be evaluated for a variety of operating scenarios of interest, particularly focusing on large system events that may cause system disintegration. The model development and simulations must be conducted in RTDS environment by utlizing Hardware-in-the-loop testing and applying modern IEDs supplied with under- and over-frequency protection, UFLS, under- and overvoltage protection. Developing, new System Integrity Protection Schemes (SIPS), by utilizing synchrophasors is also required. The proof-of-concept includes RTDS-based simulation platform that can be adapted to a real world situation. Hence, for this position, solid knowledge of RTDS simulation is required.
The project is financed by industry and it is in the scope of the Power System Protection Centre.
About the department
The research in the Department of Electrical Sustainable Energy is inspired by the technical, scientific, and societal challenges originating from the transition towards a more sustainable society and focuses on three areas:
The Electrical Sustainable Energy Department provides expertise in these areas throughout the entire energy system chain. The department owns a large ESP Laboratory assembling High Voltage testing, DC Grids testing environment, and large RTDS that is actively used for real-time simulation of future electrical power systems, AC and DC protection and wide-area monitoring and protection.
The Intelligent Electrical Power Grid (IEPG) group, headed by Professor Peter Palensky, works on the future of our power system. The goal is to generate, transmit and use electrical energy in a highly reliable, efficient, stable, clean, affordable, and safe way. IEPG integrates new power technologies and smart controls, which interact with other systems and allow for more distributed and variable generation.
Job requirements
An MSc degree in Electrical Power Engineering. A strong emphasis on electrical power systems dealing with System Integrity Protection Schemes, wide area monitoring applications related to system protection, frequency and voltage stability. Comprehensive knowledge in
TU Delft (Delft University of Technology)
Delft University of Technology is built on strong foundations. As creators of the world-famous Dutch waterworks and pioneers in biotech, TU Delft is a top international university combining science, engineering and design. It delivers world class results in education, research and innovation to address challenges in the areas of energy, climate, mobility, health and digital society. For generations, our engineers have proven to be entrepreneurial problem-solvers, both in business and in a social context.
At TU Delft we embrace diversity as one of our core values and we actively engage to be a university where you feel at home and can flourish. We value different perspectives and qualities. We believe this makes our work more innovative, the TU Delft community more vibrant and the world more just. Together, we imagine, invent and create solutions using technology to have a positive impact on a global scale. That is why we invite you to apply. Your application will receive fair consideration.
Challenge. Change. Impact!
Faculty of Electrical Engineering, Mathematics and Computer Science
The Faculty of Electrical Engineering, Mathematics and Computer Science (EEMCS) brings together three scientific disciplines. Combined, they reinforce each other and are the driving force behind the technology we all use in our daily lives. Technology such as the electricity grid, which our faculty is helping to make completely sustainable and future-proof. At the same time, we are developing the chips and sensors of the future, whilst also setting the foundations for the software technologies to run on this new generation of equipment – which of course includes AI. Meanwhile we are pushing the limits of applied mathematics, for example mapping out disease processes using single cell data, and using mathematics to simulate gigantic ash plumes after a volcanic eruption. In other words: there is plenty of room at the faculty for ground-breaking research. We educate innovative engineers and have excellent labs and facilities that underline our strong international position. In total, more than 1000 employees and 4,000 students work and study in this innovative environment.
Conditions of employment
Will you need to relocate to the Netherlands for this job? TU Delft is committed to make your move as smooth as possible! The HR unit, Coming to Delft Service, offers information on their website to help you prepare your relocation. In addition, Coming to Delft Service organises events to help you settle in the Netherlands, and expand your (social) network in Delft. A Dual Career Programme is available, to support your accompanying partner with their job search in the Netherlands. .
Application procedure
Are you interested in this vacancy? Please apply no later than 28 May 2026 via the application button and upload the following documents:
The candidates will be screened as the applications arrive and the promissing candidates will be shortlisted and contacted before the closing of this post.
If you are interested, do not wait to apply, we are happy to schedule an interview while the response period is running.
Please note:
| Complexity Level | |||||
|---|---|---|---|---|---|
Competences | 1 | 2 | 3 | 4 | 5 |
| A.6. Application & Product Design | |||||
| A.9. Innovating | |||||
| B.3. Testing | |||||
| B.6. ICT Systems Engineering | |||||
| D.7. Data Science and Analytics | |||||
