Jul 21, 2026 09:00 AM - 10:30 AM(America/Santiago)
Venue : Session Room 209 Available Seats : 50
20260721T090020260721T1030America/SantiagoCS20: Mineral and Oil Resource Economics Session Room 20947th IAEE International Conference. Bridging Continents, Fueling Progress: Energy Development in a Global Contextcontact@iaee2026chile.org
Whose Frac Is It, Anyway? Using Sources of Productivity Gains to Explain Industrial Organization in Oilfield Services
Concurrent Session Oral PresentationOil Economy09:00 AM - 10:30 AM (America/Santiago) 2026/07/21 13:00:00 UTC - 2026/07/21 14:30:00 UTC
Hydraulic fracturing (fracking) has evolved in productivity-enhancing ways through experimentation, innovation, and diffusion of advances across the industry. This evolution has transformed global oil and natural gas markets, with massive increases in domestic production. Because this new technology received relatively little attention before 2000, the market for fracking services was initially quite limited. Firms that performed the frac jobs had to develop expertise, while operators had to learn how to best incorporate fracking into the process of developing oil and gas prospects. At first blush it might seem counter-intuitive that a seller might take actions to influence the path of productivity gains of buyers since operators may prefer to maintain operational control. But if buyers vary in their technical proficiency some buyers might choose to employ specialized contractors. We observe that all operators engage one or more specialists for hydraulic fracturing, which raises the question: to which side of the market did learning accrue fastest? Related to this question is the issue of market power: if service companies learn faster, did that have market power implications? In this paper we address these questions. We make three primary contributions. First, we provide evidence that sellers -- oilfield service companies -- actively disseminated knowledge in the form of both academic publications and patents. By contrast, buyers -- oil and gas developers -- contributed far less to sharing knowledge about hydraulic fracturing. Second, we link two different types of technological diffusion – patents and academic publications – to firms and assess how the market position of those firms change over time. Third, we provide empirical evidence that causally links technological diffusion and industry structure. Our results have important implications beyond the oil and gas industry, providing some insight into dynamics in industries experiencing rapid technical change.
What Makes Copper Markets Economically Sustainable?
Concurrent Session Oral PresentationCritical Minerals and Raw Materials09:00 AM - 10:30 AM (America/Santiago) 2026/07/21 13:00:00 UTC - 2026/07/21 14:30:00 UTC
This paper investigates whether copper markets can remain economically sustainable under the energy transition, when demand accelerates while supply is constrained by long investment lead times and geological depletion. Under what conditions can supply and demand remain compatible over the long run without triggering unsustainable price dynamics? To address this question, the paper develops a unified long-run framework combining (i) a world demand function in which baseline demand intensity evolves over time to reflect structural transformations in material needs and development dynamics; (ii) a primary supply block based on a price-dependent geological reserve and a depletion-constrained extraction function, capturing nonlinear tightening as cumulative extraction advances; and (iii) a secondary supply block where recycling is price-responsive but constrained by a state variable representing recycling maturity. The recycling state follows a stochastic Markov process to reflect regime shifts in end-of-life scrap mobilization. The framework is calibrated and parameterized on annual data. The simulations indicate that meeting ambitious energy-transition demand trajectories would require a sharp scale-up of supply, with cumulative copper extraction projected to roughly double between 2025 and 2050. While moderate increases in demand elasticity would improve sustainability outcomes at the margin by dampening price pressures, the strongest relief channel is supply-side scaling-up, notably through technological progress in the mining sector, which generate hump-shaped price paths over time in the model. End-of-life recycling provides only partial relief as it does not substitute for primary extraction at the relevant scale and horizon (in contrast with some simulations from the IEA). Overall, copper availability could be likely to bind by 2050, threatening transition feasibility if no technological progress is achieved in the mining sector.
Presenters Maylis Peyret Research Associate, Université Paris-Dauphine–PSL Co-Authors Frédéric Gonand Professor Of Economics, Université Paris-Dauphine–PSL
Hotelling’s Sweet Spot: Geological Constraints, Resource Economics, and the Emergence of Bell-Shaped Supply Trajectories
Concurrent Session Oral PresentationOil Economy09:00 AM - 10:30 AM (America/Santiago) 2026/07/21 13:00:00 UTC - 2026/07/21 14:30:00 UTC
This paper revisits the economics of non-renewable resources by reinterpreting the Hotelling framework in light of geological constraints. Although Hotelling (1931) recognized geological limits, much subsequent work has focused on intertemporal optimization while struggling to reconcile theory with empirically observed bell-shaped trajectories of discoveries and production, particularly in oil and gas (Hubbert, 1962; Slade and Thille, 2009). Extensions incorporating demand growth, technological change, reserve heterogeneity, or physical production constraints improve production paths (Holland, 2008; Okullo et al., 2015; Anderson et al., 2018), but leave discovery dynamics insufficiently explained (Laherrère, 2003). We restore geological constraints to the core of the Hotelling model through a framework of geological learning. We develop a Hotelling-type exploration–extraction model integrating two structural constraints. First, a pressure-decline mechanism limits production as a proportion of existing reserves (Okullo et al., 2015; Anderson et al., 2018). Second, we introduce geological "sweet spots," reflecting the uneven spatial concentration of recoverable resources (Uhler, 1976; USGS, 2012). Because their location is initially unknown, exploration generates endogenous learning: early discoveries are smaller on average, firms progressively identify high-productivity deposits, and discoveries decline once sweet spots are exhausted. This produces a bell-shaped discovery function rooted in geological structure rather than exogenous technological change. The model generates bell-shaped reserve additions and production, while equilibrium prices follow a U-shaped path consistent with constrained Hotelling dynamics (Pindyck, 1978). A calibrated simulation using a monthly panel of seven U.S. shale plays (2007–2016) exploits cross-play variation to control for common technological trends and identify geological learning effects. Rising well productivity is controlled for the progressive identification of sweet spots rather than generic technological progress (Livernois, 2009). Extending the framework to critical minerals suggests that geological heterogeneity alone can generate similar supply patterns, with implications for price formation and the energy transition.
Optimal strategy of energy assets management: a portfolio risk hedging perspective
Concurrent Session Oral PresentationOil Economy09:00 AM - 10:30 AM (America/Santiago) 2026/07/21 13:00:00 UTC - 2026/07/21 14:30:00 UTC
The pronounced volatility in global crude oil prices-exacerbated by systemic shocks such as the 2008 global financial crisis, the COVID-19 pandemic, and the Russia-Ukraine conflict-has intensified the demand for robust hedging strategies. This study investigates the hedging potential of a diverse suite of candidate assets, comprising coal, natural gas, gold, the U.S. dollar, green bonds, Bitcoin, and equity indices. Utilizing a comprehensive empirical framework, we evaluate hedging performance through three primary lenses: the hedging effectiveness index, economic utility gains, and an event study analysis. Our initial findings indicate that the S&P 500 equity index exhibits superior efficacy in mitigating crude oil price risk. However, when transaction costs are integrated into the performance metrics, the S&P 500's advantage is notably diminished, suggesting that raw hedging effectiveness does not always translate to practical cost-efficiency. Furthermore, portfolio diversification analysis demonstrates that a multi-asset approach-integrating selected hedging instruments with crude oil-yields superior risk-adjusted returns compared to single-asset strategies. To ensure the robustness of our results across varying market regimes, the empirical framework is extended to specifically incorporate the extreme market conditions of the COVID-19 era and the Russia-Ukraine conflict. Subsequent comparative analysis of alternative equity benchmarks reveals that the MSCI All Country World Index (ACWI) provides greater hedging effectiveness than the S&P 500 during these periods of heightened geopolitical and economic stress. Collectively, these findings provide critical insights for financial practitioners and risk managers, highlighting the necessity of accounting for transaction costs and global diversification when navigating energy market volatility.
Mining, Critical Minerals, and Climate Policy Feedback: Insights from Chile’s Energy Transition
Concurrent Session Oral PresentationCritical Minerals and Raw Materials09:00 AM - 10:30 AM (America/Santiago) 2026/07/21 13:00:00 UTC - 2026/07/21 14:30:00 UTC
Recent literature on climate policy feedback highlights how domestic green industries-such as solar, wind, and battery manufacturing-can evolve into influential political constituencies that advocate for deeper decarbonization. However, far less is known about whether extractive industries, particularly those supplying critical minerals for the global energy transition, can generate similar feedback effects. This study adopts a qualitative, theory-guided case study design to examine whether and how extractive industries can generate policy feedback effects that influence the trajectory of climate policy. The conceptual framework informs the selection of empirical evidence, the coding of policy instruments and industry responses, and the interpretation of causal mechanisms. Rather than testing a single causal hypothesis through large-N statistical analysis, this research seeks to provide an analytically rich account of how resource, interpretive, and organizational effects unfold in practice. The core of the research strategy is a within-case analysis of Chile's mining sector as a critical instance of a resource-dependent economy supplying key critical minerals for the global energy transition. Drawing on policy feedback theory, institutional analysis, and international comparisons (Canada, Australia, and the Nordics), the study analyzes emerging mechanisms in Chile-including green certification schemes, corporate decarbonization commitments, and the recent Mining Decarbonization Agreement-that may transform mining firms into supporters of more ambitious climate regulation. Chile provides a particularly suitable context because of its combination of high mining dependence, ambitious climate and energy transition goals, and increasing international pressures for low-carbon mineral production The paper identifies conditions under which extractive industries create positive, neutral, or negative feedback loops for climate policy. The findings contribute to understanding climate governance in resource-dependent economies and offer implications for policymakers seeking to align mining sectors with national and global decarbonization objectives.