Outstanding Academic Fellows Programme 2014-2018
Fellows in the Outstanding Academic Fellows Programme 2014-2018 together with Rector Gunnar Bovim and Pro-Rector for Research Kari Melby. Five of the fellows were not present when the picture was taken.
The programme period for the first group with 22 fellows runs from June 2014 to June 2018. The fellows describe their research on this page.
My research focuses on deep brain stimulation (DBS), an innovative treatment strategy for certain drug-resistant brain diseases. I intend to study neuronal activity recorded by this procedure, with emphasis on exploring basic neural network function and investigating the effect of DBS as a clinical intervention.
My research interests cover heat and mass transfer issues and their application in the development of more efficient processes, combined with multiphase and multicomponent separation issues in the oil and gas industry.
I am a researcher in mathematics, specialising in nonlinear partial differential equations and non-local (free-boundary) problems. A problem currently under investigation involves the incompressible Euler equations for liquids which describe the motion of water under a freely moving surface. Relevant questions include the existence, uniqueness and stability of solutions under different mathematical (and physical) assumptions.
My research has provided further understanding into one of the fundamental questions of life – why do some people live longer and healthier lives than others? My main focus has been on finding explanations to variations in mental and physical health, chronic diseases and mortality both within and between countries in several regions of the world.
I am researching into how magnetism can be controlled in complex oxide materials. In particular, I am investigating the possibility of tailoring the ferro- and antiferromagnetic domain state by means of thin film epitaxy and nanopatterning. I am currently exploring the use of domain-engineered nanomagnets in novel ultra-low energy magnetic logic.
I work in the fields of nanoscale testing and multiscale simulation. I am currently heading nanomechanical testing activities at the NTNU Nanomechanical Lab. My main focus is directed towards nano-enabled petroleum engineering and nanotechnology for energy applications.
My aim is to establish a clinical-oriented basic research path for the development of new therapeutic strategies for heart failure based on a better understanding of the underlying cellular and molecular mechanisms of the disease.
My research involves the interaction of pollution with species-specific ecology and natural stressors, and its effects on hormones, behaviour and reproduction, focusing mostly in birds. I currently work on exposure to, and the effects of, emerging flame retardants such as novel flame retardants and perfluorinated chemicals in birds of prey.
My research focuses on molecular interactions between viruses and their hosts. In particular, our group applies basic research and biobanks to study the mechanisms and characteristics of the innate immune response to respiratory viruses that trigger inflammation and disease in children.
My research interests are in the field of process systems engineering, with a strong focus on modelling, numerical optimization and control. By linking methods from optimization and control theory, my goal is to systematically develop practically applicable solutions for operating complex process systems in a safe, reliable, and economical way.
Research in my group focuses on modern quantum condensed matter physics, including magnetisation dynamics, Bose-Einstein condensation and related quantum phase transitions, emergent Dirac-fermions in graphene and topological insulators, and the interplay between superconductivity and ferromagnetism.
My research focuses on the structure and meaning of sentences, drawing on evidence from English, Norwegian and other languages. My current emphasis is on multilingualism and what data obtained from multilingual speakers can tell us about the architecture of grammar. I am also interested in how our capacity for language interfaces with general cognition.
There are two main aspects to my research. The first focuses on valuable natural resources and natural resource management in the context of armed conflict. The second addresses vulnerability to the effects of climate change with an emphasis on climate-related natural hazards occurring in Norway.
Cardiovascular disease is the main cause of death in the world today. My research is targeted towards the development of novel ultrasound imaging techniques for the improved diagnosis of cardiovascular disease. Using ultrasound imaging, we aim to obtain new knowledge of disease development and to develop more efficient and certain clinical diagnoses of cardiovascular disease for future application.
I study cancer cells and their abnormal metabolism. Cancer is associated with uncontrolled cell division. Most cancer cells depend on «metabolic reprogramming» to meet the metabolic requirements of a high rate of division. This reprogramming represents a therapeutic opportunity. In my project, I study the efficacy of cancer-specific metabolic inhibitors, and try to understand why some cancer cells respond to these drugs whereas others show resistance.
I am studying how living organisms adapt to environments that are not just variable but also unpredictable. Since the environment can vary in many ways, both in time and space, different adaptations can be used in different environments. My aim is to understand which strategies should be used in which environments and how combinations of adaptations can make animals even better suited to handle unpredictable environments.
My research involves the defect chemistry of oxides as applied in energy and information technology. Defects in functional oxides can reduce or enhance device performance, depending on how they influence crystal and electronic structure. I am currently applying the principles of solid state chemistry and Density Functional Theory (DFT) simulations to investigate how defects can be exploited to enhance and tailor the functional properties of oxide materials.
I am the project-leader of «Generation 100». This is the first randomized, controlled clinical study where the primary objective is to observe the effects of long term exercise training on morbidity and mortality in elderly. In light of the ageing population, our data will hopefully contribute to a better understanding of ageing, and serve as an example of how to implement large health initiatives in the future.
I am studying the history of business and politics and have a special interest in the development of international business during the 20th century. I am currently working on the project called «The hidden companies of the global economy: the development of international commodity traders, 1945-2015».
My research involves the development and application of computational models to predict how changes in gene regulation can influence development and cause disease. My focus is on small regulatory RNAs (microRNAs) and in determining their interactions with other regulatory mechanisms and the effects of genetic variation on microRNA-mediated gene regulation.
How was political criticism voiced under the most successful dictator in the history of the world, the emperor Augustus? I investigate literature that appears not to endorse authorities of norms and power in Antiquity. The main focus is on poetry in the Golden Age of Roman literature, especially Ovid, but also on the roots of this poetry in Greek literature, especially Sappho. In general, I am interested in how the Western tradition is continuously influenced by the ancient legacy.
I am a researcher in epidemiology and a consultant in diabetes and endocrinology. I am currently performing epidemiological research as part of the HUNT Study. My main research interests include diabetes and endocrinology, pregnancy complications and cardiovascular diseases.