Daniel J. Sambor scite author profile

High transportation costs make energy and food expensive in remote communities worldwide, especially in high-latitude Arctic climates. Past attempts to grow food indoors in these remote areas have proven uneconomical due to the need for expensive imported diesel for heating and electricity. This study aims to determine whether solar photovoltaic (PV) electricity can be used affordably to power container farms integrated with a remote Arctic community microgrid. A mixed-integer linear optimization model (FEWMORE: Food–Energy–Water Microgrid Optimization with Renewable Energy) has been developed to minimize the capital and maintenance costs of installing solar photovoltaics (PV) plus electricity storage and the operational costs of purchasing electricity from the community microgrid to power a container farm. FEWMORE expands upon previous models by simulating demand-side management of container farm loads. Its results are compared with those of another model (HOMER) for a test case. FEWMORE determined that 17 kW of solar PV was optimal to power the farm loads, resulting in a total annual cost decline of ~14% compared with a container farm currently operating in the Yukon. Managing specific loads appropriately can reduce total costs by ~18%. Thus, even in an Arctic climate, where the solar PV system supplies only ~7% of total load during the winter and ~25% of the load during the entire year, investing in solar PV reduces costs.

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Novel wind resource assessment and demand flexibility analysis for community resilience: A remote microgrid case study

Her

Sambor

Whitney

et al. 2021

Renewable Energy

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Optimizing demand response of a modular water reuse system in a remote Arctic microgrid

Sambor

Bishop

Dotson

et al. 2022

Journal of Cleaner Production

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Applying the FEW nexus concept at the local scale

Huntington¹,

Schmidt²,

Loring³

et al. 2021

Preprint

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The food-energy-water (FEW) nexus describes interactions among domains that yield gains or tradeoffs when analyzed together rather than independently. In a project about renewable energy in rural Alaska communities, we applied this concept to examine the implications for sustainability and resilience. The FEW nexus provided a useful framework for identifying the cross-domain benefits of renewable energy, including gains in FEW security. However, other factors such as transportation and governance also play a major role in determining FEW security outcomes in rural Alaska. Here we show the implications of our findings for theory and practice. The precise configurations of and relationships among FEW nexus components vary by place and time, and the range of factors involved further complicates the ability to develop a functional, systematic FEW model. Instead, we suggest how the FEW nexus may be applied conceptually to identify and understand cross-domain interactions that contribute to long-term sustainability and resilience.

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Daniel J. Sambor

Applying the food–energy–water nexus concept at the local scale

Development of a Tool for Optimizing Solar and Battery Storage for Container Farming in a Remote Arctic Microgrid

Novel wind resource assessment and demand flexibility analysis for community resilience: A remote microgrid case study

Optimizing demand response of a modular water reuse system in a remote Arctic microgrid

Applying the FEW nexus concept at the local scale

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