Project acronym COBHAM
Project The role of consumer behavior and heterogeneity in the integrated assessment of energy and climate policies
Researcher (PI) Massimo Tavoni
Host Institution (HI) POLITECNICO DI MILANO
Call Details Starting Grant (StG), SH3, ERC-2013-StG
Summary The objective of this project is to quantify the role of consumers’ behaviour on the design and assessment of policies aimed at enhancing energy efficiency and conservation and at promoting climate change mitigation. The project brings together different disciplines –namely energy policy, environmental and ecological economics, behavioral public finance, experimental economics, and technology policy- in an integrated fashion. COBHAM is designed to go beyond the standard analysis of energy and climate policies in the presence of environmental externalities, by accounting for the heterogeneity in consumers’ preferences, the role of social interactions, and the presence of behavioral tendencies and biases. The project seeks to: i) carry out innovative research in the theoretical understanding of the interplay between behavioral tendencies and environmental externalities; ii) generate new empirical data and research on individual preferences by means of original surveys and controlled experiments; iii) enhance integrated assessment models (IAMs) of economy, energy and climate with an advanced representation of consumers’ behavior. In doing so, the project will be able to provide a richer characterization of energy demand and of greenhouse gas emission scenarios, to better estimate consumers’ responsiveness to energy and climate policies, and to provide input to the design of new policy instruments aimed at influencing energy and environmental sustainable behavior. COBHAM is of high public policy relevance given Europe’s legislation on energy efficiency and CO2 emissions, and can provide important insights also outside the sphere of energy and climate policymaking.
Summary
The objective of this project is to quantify the role of consumers’ behaviour on the design and assessment of policies aimed at enhancing energy efficiency and conservation and at promoting climate change mitigation. The project brings together different disciplines –namely energy policy, environmental and ecological economics, behavioral public finance, experimental economics, and technology policy- in an integrated fashion. COBHAM is designed to go beyond the standard analysis of energy and climate policies in the presence of environmental externalities, by accounting for the heterogeneity in consumers’ preferences, the role of social interactions, and the presence of behavioral tendencies and biases. The project seeks to: i) carry out innovative research in the theoretical understanding of the interplay between behavioral tendencies and environmental externalities; ii) generate new empirical data and research on individual preferences by means of original surveys and controlled experiments; iii) enhance integrated assessment models (IAMs) of economy, energy and climate with an advanced representation of consumers’ behavior. In doing so, the project will be able to provide a richer characterization of energy demand and of greenhouse gas emission scenarios, to better estimate consumers’ responsiveness to energy and climate policies, and to provide input to the design of new policy instruments aimed at influencing energy and environmental sustainable behavior. COBHAM is of high public policy relevance given Europe’s legislation on energy efficiency and CO2 emissions, and can provide important insights also outside the sphere of energy and climate policymaking.
Max ERC Funding
1 451 840 €
Duration
Start date: 2014-08-01, End date: 2019-07-31
Project acronym NEVAI
Project Neurovascular Interactions and Pathfinding in the Spinal Motor System
Researcher (PI) Dario Bonanomi
Host Institution (HI) OSPEDALE SAN RAFFAELE SRL
Call Details Starting Grant (StG), LS5, ERC-2013-StG
Summary "Neurons and blood vessels rely on common guidance signals to wire into elaborate neural and vascular networks that are closely juxtaposed and interdependent: vascular supply of oxygen and nutrients is essential to sustain the high metabolic rate of the nervous system, and conversely neural control of vascular tone is crucial for circulatory homeostasis. However, it remains unclear how the nervous and vascular systems establish an intimate physical and functional relationship. This proposal seeks to reveal the developmental mechanisms that link neuronal connectivity and vascularization of the nervous system, focusing on the interactions between vascular endothelial cells and spinal motor neurons that control locomotion, respiration and autonomic responses. Motor neuron diseases and a variety of other neurodegenerative conditions are precipitated by vascular abnormalities. Thus, understanding the molecular basis of neurovascular crosstalk may offer novel therapeutic opportunities.
My group will use mutagenesis-based forward genetics in reporter mice combined with gene profiling of motor neurons and endothelial cells to screen for novel regulators of neurovascular interactions and pathfinding. Candidate genes will be further characterized using in vivo mouse and chick models, in addition to in vitro studies to uncover the mechanisms of action. Through this multi-disciplinary approach, the proposal will address these fundamental questions: (i) Do neurovascular interactions instruct the assembly of neural and vascular networks? (ii) What signaling pathways connect region-specific vascularization of the CNS to the local metabolic and functional demand of neuronal tissues? (iii) What mechanisms account for specificity, spatiotemporal control and integration of guidance signaling? In addition, this research plan will generate comprehensive transcriptional/proteomic datasets and novel mouse mutants for future studies of neurovascular communication and patterning."
Summary
"Neurons and blood vessels rely on common guidance signals to wire into elaborate neural and vascular networks that are closely juxtaposed and interdependent: vascular supply of oxygen and nutrients is essential to sustain the high metabolic rate of the nervous system, and conversely neural control of vascular tone is crucial for circulatory homeostasis. However, it remains unclear how the nervous and vascular systems establish an intimate physical and functional relationship. This proposal seeks to reveal the developmental mechanisms that link neuronal connectivity and vascularization of the nervous system, focusing on the interactions between vascular endothelial cells and spinal motor neurons that control locomotion, respiration and autonomic responses. Motor neuron diseases and a variety of other neurodegenerative conditions are precipitated by vascular abnormalities. Thus, understanding the molecular basis of neurovascular crosstalk may offer novel therapeutic opportunities.
My group will use mutagenesis-based forward genetics in reporter mice combined with gene profiling of motor neurons and endothelial cells to screen for novel regulators of neurovascular interactions and pathfinding. Candidate genes will be further characterized using in vivo mouse and chick models, in addition to in vitro studies to uncover the mechanisms of action. Through this multi-disciplinary approach, the proposal will address these fundamental questions: (i) Do neurovascular interactions instruct the assembly of neural and vascular networks? (ii) What signaling pathways connect region-specific vascularization of the CNS to the local metabolic and functional demand of neuronal tissues? (iii) What mechanisms account for specificity, spatiotemporal control and integration of guidance signaling? In addition, this research plan will generate comprehensive transcriptional/proteomic datasets and novel mouse mutants for future studies of neurovascular communication and patterning."
Max ERC Funding
1 653 000 €
Duration
Start date: 2015-01-01, End date: 2019-12-31
Project acronym RISICO
Project RISk and uncertainty in developing and Implementing Climate change pOlicies
Researcher (PI) Valentina Bosetti
Host Institution (HI) UNIVERSITA COMMERCIALE LUIGI BOCCONI
Call Details Starting Grant (StG), SH3, ERC-2013-StG
Summary "Uncertainty is pervasive in all aspects of climate change. Although this is beyond dispute, the vast majority of research assessing climate ignores uncertainty, in large part because of the technical complexities involved. The present project aims at advancing substantially the way we conceptualize, model and frame the climate change policy making process, focusing on the central role of uncertainty.
The first step is that of applying state of the art techniques from operation research (stochastic dynamic and approximate dynamic programming) to the realm of integrated assessment models (the conventional tool used to perform climate change analysis). These techniques enable us to capture a wide range of stochastic phenomena in the decision process. However, to really move forward the research edge one needs to shift the focus on to the way we, as individuals, perceive these uncertain phenomena.
Indeed, the literature on decision making under uncertainty spans way beyond economics, statistics and operations research: Notably psychology and philosophy. These disciplines have had a major role in extending what we know about the process of decision making under uncertainty, and this project aims at reconciling this strand of literature with that on climate change policy design and assessment. The three main research questions are:
1) What are key risk and uncertainty perception issues and “biases” when we face climate change and under what instances should they be included in normative analyses of climate change?
2) How can we map these “alternative” representations of uncertainty and risk perception into integrated assessment models and how will these affect the normative predicaments of these models ?
3) How can we communicate and frame uncertainty itself, as well as results of stochastic analyses, in a way that help us reducing those biases that have no normative role, but arise from our limited attentional and information processing capacity?"
Summary
"Uncertainty is pervasive in all aspects of climate change. Although this is beyond dispute, the vast majority of research assessing climate ignores uncertainty, in large part because of the technical complexities involved. The present project aims at advancing substantially the way we conceptualize, model and frame the climate change policy making process, focusing on the central role of uncertainty.
The first step is that of applying state of the art techniques from operation research (stochastic dynamic and approximate dynamic programming) to the realm of integrated assessment models (the conventional tool used to perform climate change analysis). These techniques enable us to capture a wide range of stochastic phenomena in the decision process. However, to really move forward the research edge one needs to shift the focus on to the way we, as individuals, perceive these uncertain phenomena.
Indeed, the literature on decision making under uncertainty spans way beyond economics, statistics and operations research: Notably psychology and philosophy. These disciplines have had a major role in extending what we know about the process of decision making under uncertainty, and this project aims at reconciling this strand of literature with that on climate change policy design and assessment. The three main research questions are:
1) What are key risk and uncertainty perception issues and “biases” when we face climate change and under what instances should they be included in normative analyses of climate change?
2) How can we map these “alternative” representations of uncertainty and risk perception into integrated assessment models and how will these affect the normative predicaments of these models ?
3) How can we communicate and frame uncertainty itself, as well as results of stochastic analyses, in a way that help us reducing those biases that have no normative role, but arise from our limited attentional and information processing capacity?"
Max ERC Funding
1 146 002 €
Duration
Start date: 2014-06-01, End date: 2019-05-31
