Sort by
Refine Your Search
-
Listed
-
Employer
-
Field
-
challenges within energy, environment, health, and sustainability. We succeed because we build bridges between disciplines and transcend traditional boundaries. Our interdisciplinary mindset is not only a
-
University (http://bio.au.dk/en) and work in the Section for Microbiology at this department. The section employs 12 permanent scientific staff and ~20 PhD students and postdocs. Research at the section covers
-
students. The department is responsible for two educations: Molecular Biology and Molecular Medicine with a yearly uptake of 160 students in total. Please refer to http://mbg.au.dk/ for further information
-
communication skills orally and in writing are mandatory. Who we are All post doc fellows will be part of Center for Ice-Free Arctic Research (CIFAR). You can find more about the center here: https://bio.au.dk
-
with a yearly uptake of 160 students in total. Please refer to http://mbg.au.dk/ for further information about The Department of Molecular Biology and Genetics and to https://nat.au.dk/ and http
-
. In this role, you will help build a systems-level understanding of human biology by developing computational approaches to model the dynamic regulatory programs of cells and tissues. By combining
-
to contribute to the advance of the quantum computing both through your contributions to the research in the NQCP photonics team and through developing novel methods to build a quantum workforce with the NQCP
-
of the mission of NQCP. We want to make Denmark a world leader in quantum research, and we hope to attract people from all over the world. Life in Denmark is supported with strong social services (free universal
-
. At the department, we contribute to solving some of society’s greatest challenges within energy, environment, health, and sustainability. We succeed because we build bridges between disciplines and transcend
-
metabolic rewiring. This research builds on our recent multi-omics study (Nature Communications, 2024) demonstrating that maternal lung inflammation at low levels leads to fetal metabolic adaptation without