Salinity of deep groundwater in California: Water quantity, quality, and protection

Kang, Mary; Jackson, Robert B.

doi:10.1073/pnas.1600400113

Cited by 74 publications

(55 citation statements)

References 38 publications

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“…The century-and-a-half-long history of oil and gas development in Pennsylvania and other US states, such as Texas and California, has resulted in millions of abandoned wells, and in many cases, poorly documented or missing well records (3,(9)(10)(11). As a result, there is a lack of data to characterize abandoned oil and gas wells and the possible relationship between methane emissions and well attributes.…”

mentioning

confidence: 99%

Identification and characterization of high methane-emitting abandoned oil and gas wells

Kang

Christian

Celia

et al. 2016

Proc. Natl. Acad. Sci. U.S.A.

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152

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Recent measurements of methane emissions from abandoned oil/gas wells show that these wells can be a substantial source of methane to the atmosphere, particularly from a small proportion of high-emitting wells. However, identifying high emitters remains a challenge. We couple 163 well measurements of methane flow rates; ethane, propane, andn-butane concentrations; isotopes of methane; and noble gas concentrations from 88 wells in Pennsylvania with synthesized data from historical documents, field investigations, and state databases. Using our databases, we (i) improve estimates of the number of abandoned wells in Pennsylvania; (ii) characterize key attributes that accompany high emitters, including depth, type, plugging status, and coal area designation; and (iii) estimate attribute-specific and overall methane emissions from abandoned wells. High emitters are best predicted as unplugged gas wells and plugged/vented gas wells in coal areas and appear to be unrelated to the presence of underground natural gas storage areas or unconventional oil/gas production. Repeat measurements over 2 years show that flow rates of high emitters are sustained through time. Our attribute-based methane emission data and our comprehensive estimate of 470,000–750,000 abandoned wells in Pennsylvania result in estimated state-wide emissions of 0.04–0.07 Mt (1012g) CH4per year. This estimate represents 5–8% of annual anthropogenic methane emissions in Pennsylvania. Our methodology combining new field measurements with data mining of previously unavailable well attributes and numbers of wells can be used to improve methane emission estimates and prioritize cost-effective mitigation strategies for Pennsylvania and beyond.

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confidence: 99%

Identification and characterization of high methane-emitting abandoned oil and gas wells

Kang

Christian

Celia

et al. 2016

Proc. Natl. Acad. Sci. U.S.A.

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152

151

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“…SETS approaches have also been recently applied (or proposed) for reducing the impacts of drought in California. Technologically oriented options being implemented or explored include desalination (such as the 50 million gallons per day Carlsbad Desal Plant near San Diego), groundwater drilling, and wastewater recycling (Cooley et al, ; Gorman, ; Howard & Millsap, ; Kang & Jackson, ; McKenzie, ; San Diego County Water Authority, ; Underwood, ). Ecologically based solutions include the use of more native vegetation in landscaping and the implementation of fog harvesting systems inspired by nature (California Water Service, ; FogNet, ; Goldstein, ; Knickmeyer, ; Weiss‐penzias et al, ).…”

Section: Using a Sets Lens To Move Beyond Technologically Focused Resmentioning

confidence: 99%

Interdependent Infrastructure as Linked Social, Ecological, and Technological Systems (SETSs) to Address Lock‐in and Enhance Resilience

et al. 2018

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Traditional infrastructure adaptation to extreme weather events (and now climate change) has typically been techno‐centric and heavily grounded in robustness—the capacity to prevent or minimize disruptions via a risk‐based approach that emphasizes control, armoring, and strengthening (e.g., raising the height of levees). However, climate and nonclimate challenges facing infrastructure are not purely technological. Ecological and social systems also warrant consideration to manage issues of overconfidence, inflexibility, interdependence, and resource utilization—among others. As a result, techno‐centric adaptation strategies can result in unwanted tradeoffs, unintended consequences, and underaddressed vulnerabilities. Techno‐centric strategies that lock‐in today's infrastructure systems to vulnerable future design, management, and regulatory practices may be particularly problematic by exacerbating these ecological and social issues rather than ameliorating them. Given these challenges, we develop a conceptual model and infrastructure adaptation case studies to argue the following: (1) infrastructure systems are not simply technological and should be understood as complex and interconnected social, ecological, and technological systems (SETSs); (2) infrastructure challenges, like lock‐in, stem from SETS interactions that are often overlooked and underappreciated; (3) framing infrastructure with a SETS lens can help identify and prevent maladaptive issues like lock‐in; and (4) a SETS lens can also highlight effective infrastructure adaptation strategies that may not traditionally be considered. Ultimately, we find that treating infrastructure as SETS shows promise for increasing the adaptive capacity of infrastructure systems by highlighting how lock‐in and vulnerabilities evolve and how multidisciplinary strategies can be deployed to address these challenges by broadening the options for adaptation.

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“…Algae Growth = +0.050 −3.000E-003 × A +3.000E-003 × B −0.020 × C + 3.750E-003 × AB −3.750E-003 × AC +3.750E-003 × BC −9.545E-003 × A 2 −9.545E-003 × B 2 +0.015 × C 2 Final equation in terms of actual factors: Microalgae Growth = +0.090273 +3.51818E-004 × COD +2.61818E-003 × TDS −0.81818 × Microalgae Absorbance +3.75000E-006 × COD × TDS −3.75000E-004 × COD × Microalgae Absorbance + 3.75000E-003 × TDS × Microalgae Absorbance −9.54545E-007 × COD 2 −9.54545E-005 × TDS 2 +1.54545 × Microalgae Absorbance 2 The results obtained in this work are similar to some of the previous observations using process optimization techniques [49]. In this study, we noticed the interaction and quadratic effects to be significant as reported in other studies focusing on microbial fuel cells [42,[50][51][52][53][54].…”

Section: Microalgae Growth Final Equation In Terms Of Coded Factorsmentioning

confidence: 99%

Resource recovery from low strength wastewater in a bioelectrochemical desalination process

Stuart-Dahl

Martinez‐Guerra

Kokabian

et al. 2019

Engineering in Life Sciences

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In this research, low strength synthetic wastewaters with chemical oxygen demand less than 300 mg L−1 were treated at different concentrations in a bioelectrochemical desalination process. A process optimization model was utilized to study the performance of the photosynthetic bioelectrochemical desalination process. The variables include substrate (chemical oxygen demand) concentration, total dissolved solids, and microalgae biomass concentration in the cathode chamber. Relationships between the chemical oxygen demand concentration, microalgae, and salt concentrations were evaluated. Power densities and potential energy benefits from microalgal biomass growth were discussed. The results from this study demonstrated the reliability and reproducibility of the photosynthetic microbial desalination process performance followed by a response surface methodology optimization. This study also confirms the suitability of bioelectrochemical desalination process for treating low substrate wastewaters such as agricultural wastewaters, anaerobic digester effluents, and septic tank effluents for net energy production and water desalination.

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Salinity of deep groundwater in California: Water quantity, quality, and protection

Cited by 74 publications

References 38 publications

Identification and characterization of high methane-emitting abandoned oil and gas wells

Identification and characterization of high methane-emitting abandoned oil and gas wells

Interdependent Infrastructure as Linked Social, Ecological, and Technological Systems (SETSs) to Address Lock‐in and Enhance Resilience

Resource recovery from low strength wastewater in a bioelectrochemical desalination process

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