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1. DWPT-Integrated Microscopic Traffic Flow for Distribution Grid Voltage Stability Analysis

   https://doi.org/10.1109/NAPS61145.2024.10741859  

   Newbolt, Travis; Mandal, Paras; Wang, Hongjie; Zane, Regan (October 2024, IEEE)

   This paper examines an application of a two-lane microscopic Traffic Flow (TF) simulation to comprehend the impact of the complex behavior of Dynamic Wireless Power Transfer (DWPT) charging systems onto electric power distribution grids. The proposed approach utilizes real-world data to determine a more accurate TF density at each time interval. The simulation is carried out considering all vehicles, whether electric vehicles (EVs) or non-electric, and they have a randomized lane changing behavior and fluctuating velocities following a leading car model. Three different scenarios are conducted for 5 mile, 10 mile, and 15 mile DWPT networks that are proportionally connected to an IEEE 33-bus distribution grid. Our findings indicate that EVs' average State-of-Charge (SOC) increases proportionally and significantly at each DWPT network length. Furthermore, the load demand generated from the DWPT network also increases proportionally with its length; and this increment in load demand causes adverse impacts on distribution grid voltage magnitudes exceeding operational standards that leads to equipment failure or blackout events. 

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2. Coordinated Electric Vehicle Charging with Reactive Power Support to Distribution Grids

   https://doi.org/10.1109/TII.2018.2829710  

   Wang, Jingyuan; Bharati, Guna Ratna; Paudyal, Sumit; Ceylan, Oguzhan; Bhattarai, Bishnu Prasad; Myers, Kurt S. (January 2019, IEEE Transactions on Industrial Informatics)

   We develop hierarchical coordination frameworks to optimally manage active and reactive power dispatch of number of spatially distributed electric vehicles (EVs) incorporating distribution grid level constraints. The frameworks consist of detailed mathematical models, which can benefit the operation of both entities involved, i.e., the grid operations and EV charging. The first model comprises of a comprehensive optimal power flow model at the distribution grid level, while the second model represents detailed optimal EV charging with reactive power support to the grid. We demonstrate benefits of coordinated dispatch of active and reactive power from EVs using a 33-node distribution feeder with large number of EVs (more than 5,000). Case studies demonstrate that, in constrained distribution grids, coordinated charging reduces the average cost of EV charging if the charging takes place at non-unity power factor mode compared to unity power factor. Similarly, the results also demonstrate that distribution grids can accommodate charging of increased number of EVs if EV charging takes place at non-unity power factor mode compared to unity power factor. 

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3. Design of a Level-3 electric vehicle charging station using a 1-MW solar system via the distributed maximum power point tracking technique

   https://doi.org/10.1093/ce/zkad084  

   Balal, Afshin; Giesselmann, Michael (February 2024, Clean Energy)

   Abstract Solar power is mostly influenced by solar irradiation, weather conditions, solar array mismatches and partial shading conditions. Therefore, before installing solar arrays, it is necessary to simulate and determine the possible power generated. Maximum power point tracking is needed in order to make sure that, at any time, the maximum power will be extracted from the photovoltaic system. However, maximum power point tracking is not a suitable solution for mismatches and partial shading conditions. To overcome the drawbacks of maximum power point tracking due to mismatches and shadows, distributed maximum power point tracking is utilized in this paper. The solar farm can be distributed in different ways, including one DC–DC converter per group of modules or per module. In this paper, distributed maximum power point tracking per module is implemented, which has the highest efficiency. This technology is applied to electric vehicles (EVs) that can be charged with a Level 3 charging station in <1 hour. However, the problem is that charging an EV in <1 hour puts a lot of stress on the power grid, and there is not always enough peak power reserve in the existing power grid to charge EVs at that rate. Therefore, a Level 3 (fast DC) EV charging station using a solar farm by implementing distributed maximum power point tracking is utilized to address this issue. Finally, the simulation result is reported using MATLAB®, LTSPICE and the System Advisor Model. Simulation results show that the proposed 1-MW solar system will provide 5 MWh of power each day, which is enough to fully charge ~120 EVs each day. Additionally, the use of the proposed photovoltaic system benefits the environment by removing a huge amount of greenhouse gases and hazardous pollutants. For example, instead of supplying EVs with power from coal-fired power plants, 1989 pounds of CO2 will be eliminated from the air per hour. 

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4. Off the grid and on the fence: Unpacking electric vehicle adoption barriers in isolated microgrids

   https://doi.org/10.1016/j.erss.2025.104281  

   Schmidt, Jennifer I; Wilber, Michelle M; Schwoerer, Tobias; Bodony, Tim; Sanderson, Brooke; Albertson, Leif; Bergan, Matt (September 2025, Energy Research & Social Science)

   Reducing greenhouse gas emissions is an international impetus to transition from vehicles with internal combustion engines (ICE) to electric vehicles (EV). While this transition is happening rapidly in some regions of the world that are mainly urbanized, other predominantly rural and less developed regions are slower to adopt this technology. Rural Alaska serves as an example with its not-road-connected communities, high cost of electricity, extreme environmental conditions, and isolated power grids often powered by diesel. This study used co-production and mixed methods to identify barriers and perceived benefits towards EV adoption and explore EV adoption rates across the Arctic. We conducted community workshops in Bethel, Galena, and Kotzebue, Alaska, and 25 interviews with businesses and local governments. The top five impediments to EV adoption are the inability to maintain vehicles locally, cold weather performance, higher purchase prices compared to ICE vehicles, and the cost of electricity. The successful adoption of EVs in isolated microgrid communities in the Arctic requires investments in appropriate financial incentives, especially for low-income households, expansion of renewable power generation, and climate and culture-relevant proof-of-concept vehicles. Residents acknowledged that EVs generally operate much cleaner than vehicles with ICE, can have lower fuel and maintenance costs, and cause less air and noise pollution. We propose a framework to develop policies to facilitate the adoption of EVs in rural areas. Policy implications for overcoming the challenges related to the transition to EVs in remote rural parts of the globe are discussed. 

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5. Enhancing Distribution Grid Resilience to Power Outages Using Electric Vehicles in Residential Microgrids

   https://doi.org/10.1109/NAPS52732.2021.9654570  

   Simental, Orlando Quezada; Mandal, Paras; Galvan, Eric (November 2021, 2021 North American Power Symposium (NAPS))

   The transition to electric vehicles (EVs) is underway globally and EVs are expected to become more widely adopted in the coming years. One of the main characteristics of EVs is that they are not only seen as mean for transportation but also potentially as a flexible energy storage resource in vehicle-to-grid (V2G) applications. This paper proposes a resilience analysis on the feasibility of using EVs for power restoration and supply of residential networked microgrids (MGs) experiencing a power outage due to extreme weather. In order to evaluate the effectiveness of utilizing EVs as a backup power supply during an outage, various case studies are presented considering different scenarios and resilience metrics. Test results demonstrate that EVs can satisfy the energy requirements of a residential household for more than 6 hours but, also provide power to the distribution grid through MG aggregation. 

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