Sort by
Refine Your Search
-
Category
-
Employer
- Uppsala universitet
- Swedish University of Agricultural Sciences
- Umeå University
- Chalmers tekniska högskola
- KTH Royal Institute of Technology
- Linköping University
- Linneuniversitetet
- Lulea University of Technology
- Luleå University of Tehnology
- Lunds universitet
- Sveriges Lantbruksuniversitet
- 1 more »
- « less
-
Field
-
observations of ice initiation from solid aerosol material, informing the design of microphysical schemes of models of clouds and climate at Lund. A new climate model is being developed to represent cloud
-
and data-based models for describing complex materials and (re)active molecules with a focus on their interfaces. Development and implementation of new methodologies and algorithms for simulating
-
. The research focuses on the development of next-generation thermoelectric materials through advanced nanoscale engineering. The project aims to significantly enhance thermoelectric performance by
-
the Division of Scientific Computing and the Division of Materials Theory in the Department of Physics and Astronomy. The Department of Information Technology holds a leading position in both research and
-
for efficient last-mile deliveries with a focus on climate and flexibility. Using advanced modeling and data analysis, you’ll create solutions that make final deliveries smarter and more sustainable. Your work
-
demand. We hope that you will help us to build the sustainable companies and societies of the future. In line with the green transition and the striving for a sustainable supply of critical raw materials
-
quantum physics/chemistry, inorganic and materials chemistry, solid state chemistry or physics. · Good laboratory skills and interest in experimental research. · Programming skills for modeling and data
-
consists of three pillars: material characterization (mineralogical and particle analyses), unit operations (such as comminution and separation processes) as well as system engineering approaches (modeling
-
challenging chemical bonds (N–H, O–H, and C–H) under mild conditions. The project combines plasmonic materials, photoelectrochemistry, and ultrafast laser spectroscopy to investigate and control charge transfer
-
both experimental development and theoretical modelling. Therefore, it requires the candidate to have a solid background in physics, electronics, and mathematics, along with strong practical experimental