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1. Optimal Transition of Ammonia Supply Chain Networks via Stochastic Programming

   https://doi.org/10.69997/sct.141495  

   Mitrai, Ilias; Palys, Matthew J; Daoutidis, Prodromos (July 2024, PSE Press)

   This paper considers the optimal incorporation of renewable ammonia production facilities into existing supply chain networks which import ammonia from conventional producers while accounting for uncertainty in this conventional ammonia price. We model the supply chain transition problem as a two-stage stochastic optimization problem which is formulated as a Mixed Integer Linear Programming problem. We apply the proposed approach to a case study on Minnesota's ammonia supply chain. We find that accounting for conventional price uncertainty leads to earlier incorporation of in-state renewable production sites in the supply chain network and a reduction in the quantity and cost of conventional ammonia imported over the supply chain transition horizon. These results show that local renewable ammonia production can act as a hedge against the volatility of the conventional ammonia market. 

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2. Material availability assessment using system dynamics: The case of tellurium

   https://doi.org/10.1002/pip.3760  

   Hanna, Francis; Nain, Preeti; Anctil, Annick (December 2023, Progress in Photovoltaics: Research and Applications)

   Abstract With the increased deployment of solar photovoltaic (PV), the cadmium telluride (CdTe) PV market is expected to grow substantially. CdTe PV production is crucial for the clean energy transition but problematic because of the material availability challenges. CdTe PV relies on tellurium, a scarce metal mainly produced as a byproduct of copper. Several studies investigated the availability of tellurium for CdTe PV. However, previous models are static and do not reflect the interconnection between tellurium supply, demand, and price. Despite the efforts, previous studies have inconsistent results and do not provide a clear understanding on the availability of tellurium for CdTe PV applications. This study uses system dynamics modeling to assess tellurium availability between 2023 and 2050. The model considers different scenarios for CdTe PV demand growth and PV material intensity reduction. The model also considers tellurium supply variables such as Te‐rich ores, tellurium yield from anode slimes, and growth in copper mining. The historical data (2000–2020) analysis shows a negative correlation between the tellurium price and the annual tellurium surplus. All the considered demand scenarios exhibit a tellurium supply gap where annual material production falls below demand. Tellurium availability and price could delay the growth of CdTe PV production, and maintaining the current CdTe PV market share of ~4% will be challenging. The low‐demand scenario, which is based on a constant CdTe PV market share, results in a supply gap starting in 2029 and a supply gap peak of 508 metric tons in 2036. Our work shows that having more manufacturing capacity is insufficient if tellurium is unavailable. More importantly, this work shows that fast growth in CdTe PV production can diminish the advantages of dematerialization. The estimated cumulative CdTe PV production by 2050 ranges between 929 and 2250 GWp. The findings also suggest that recycling retired solar panels can contribute to 17% of the total tellurium demand and 34% of the CdTe PV tellurium demand. Sensitivity analysis shows that expanding existing Te‐rich ores does not alleviate tellurium scarcity. Alternatively, improving tellurium yield from copper electrorefining is a more efficient mitigation approach. The system dynamic approach outlined in this study provides a better perspective on the status of various critical metal supply chains, ultimately leading to sustainable materials management and increasing CdTe production. 

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3. Distribution-level markets under high renewable energy penetration

   https://doi.org/10.1145/3538637.3538846  

   Ju, Peizhong; Lin, Xiaojun; Huang, Jianwei (June 2022, Thirteenth ACM International Conference on Future Energy Systems (ACM e-Energy 2022))

   We study the market structure for emerging distribution-level energy markets with high renewable energy penetration. Renewable generation is known to be uncertain and has a close-to-zero marginal cost. In this paper, we use solar energy as an example of such zero-marginal-cost resources for our focused study. We first show that, under high penetration of solar generation, the classical real-time market mechanism can either exhibit significant price-volatility (when each firm is not allowed to vary the supply quantity), or induce price-fixing (when each firm is allowed to vary the supply quantity), the latter of which leads to extreme unfairness of surplus division. To overcome these issues, we propose a new rental-market mechanism that trades the usage-right of solar panels instead of real-time solar energy. We show that the rental market produces a stable and unique price (therefore eliminating price-volatility), maintains positive surplus for both consumers and firms (therefore eliminating price-fixing), and achieves the same social welfare as the traditional real-time market. A key insight is that rental markets turn uncertainty of renewable generation from a detrimental factor (that leads to price-volatility in real-time markets) to a beneficial factor (that increases demand elasticity and contributes to the desirable rental-market outcomes). 

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4. A Demand-Responsive Green Ammonia Plant and its Impact on the Electricity Distribution System

   https://doi.org/10.1109/PESGM48719.2022.9917204  

   Edmonds, Lawryn; Liu, Xuebo; Wu, Hongyu (July 2022, 2022 IEEE Power & Energy Society General Meeting (PESGM))

   Most large-scale ammonia production typically relies on natural gas or coal, which causes harmful carbon pollution to enter the atmosphere. The viability of a small-scale “green” ammonia plant is investigated where renewable electricity is used to provide hydrogen and nitrogen via electrolysis and air liquefaction, respectively, to a Haber-Bosch system to synthesize ammonia. A green ammonia plant can serve as a demandresponsive load to the electricity distribution system and provide long-term energy storage through chemical energy storage in ammonia. A coordinated operational model of an electricity distribution system and an electricity-run ammonia plant is proposed in this paper. Case studies are performed on a modified PG&E 69-node electricity distribution system coupled with a small-scale ammonia plant. Results indicate the ammonia plant can adequately serve as a demand response resource and positively impact the distribution locational marginal price (DLMP). 

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5. Design and operation of modular biorefinery supply chain under uncertainty using generalized Benders decomposition

   https://doi.org/10.1002/aic.18458  

   Luo, Yuqing; Ierapetritou, Marianthi (April 2024, AIChE Journal)

   Abstract Biomass supply chain performance is heavily affected by uncertainties stemming from supply, demand, or unexpected disruptions. Unlike petrochemical plants that use crude oil, biorefineries often have to deal with the uneven spatial‐temporal distribution of feedstock supply. The modular production strategy provides more flexibility in chemical manufacturing by allowing fast capacity expansion and unit movement. However, modeling and optimizing modular biomass supply chain under uncertainties becomes challenging due to high dimensionality and the existence of discrete decisions. This work optimizes the multiperiod biomass supply chain using the rolling horizon planning and two‐stage stochastic programming framework. We then applied generalized Benders decomposition to reduce the computational complexity of the stochastic mixed integer nonlinear programming supply chain optimization. Furthermore, the solution of the stochastic programming could be used to quantitatively describe the life‐cycle assessment uncertainties of the biomass supply chain performance, demonstrating seasonality and random variability. 

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