Your search keyword '"Erin Webb"' showing total 4 results

1. Beyond Pristine Metal–Organic Frameworks: Preparation of Hollow MOFs and Their Composites for Catalysis, Sensing, and Adsorption Removal Applications

Author

Xiaoqian Zha, Xianhui Zhao, Erin Webb, Shifa Ullah Khan, and Yang Wang

Subjects

hollow metal–organic framework, catalysis, sensing, adsorption, Organic chemistry, QD241-441

Abstract

Metal–organic frameworks (MOFs) have been broadly applied to numerous domains with a substantial surface area, tunable pore size, and multiple unsaturated metal sites. Recently, hollow MOFs have greatly attracted the scientific community due to their internal cavities and gradient pore structures. Hollow MOFs have a higher tunability, faster mass-transfer rates, and more accessible active sites when compared to traditional, solid MOFs. Hollow MOFs are also considered to be candidates for some functional material carriers. For example, composite materials such as hollow MOFs and metal nanoparticles, metal oxides, and enzymes have been prepared. These composite materials integrate the characteristics of hollow MOFs with functional materials and are broadly used in many aspects. This review describes the preparation strategies of hollow MOFs and their composites as well as their applications in organic catalysis, electrochemical sensing, and adsorption separation. Finally, we hope that this review provides meaningful knowledge about hollow-MOF composites and their derivatives and offers many valuable references to develop hollow-MOF-based applied materials.

Published

2022

2. Development of the IBSAL-SimMOpt Method for the Optimization of Quality in a Corn Stover Supply Chain

Author

Hernan Chavez, Krystel K. Castillo-Villar, and Erin Webb

Subjects

renewable energy, bioenergy, biofuels, biomass, supply chain network design, logistics, discrete-event simulation, optimization, simulation-based optimization, Technology

Abstract

Variability on the physical characteristics of feedstock has a relevant effect on the reactor’s reliability and operating cost. Most of the models developed to optimize biomass supply chains have failed to quantify the effect of biomass quality and preprocessing operations required to meet biomass specifications on overall cost and performance. The Integrated Biomass Supply Analysis and Logistics (IBSAL) model estimates the harvesting, collection, transportation, and storage cost while considering the stochastic behavior of the field-to-biorefinery supply chain. This paper proposes an IBSAL-SimMOpt (Simulation-based Multi-Objective Optimization) method for optimizing the biomass quality and costs associated with the efforts needed to meet conversion technology specifications. The method is developed in two phases. For the first phase, a SimMOpt tool that interacts with the extended IBSAL is developed. For the second phase, the baseline IBSAL model is extended so that the cost for meeting and/or penalization for failing in meeting specifications are considered. The IBSAL-SimMOpt method is designed to optimize quality characteristics of biomass, cost related to activities intended to improve the quality of feedstock, and the penalization cost. A case study based on 1916 farms in Ontario, Canada is considered for testing the proposed method. Analysis of the results demonstrates that this method is able to find a high-quality set of non-dominated solutions.

Published

2017

3. Quantifying the Impact of Feedstock Quality on the Design of Bioenergy Supply Chain Networks

Author

Krystel K. Castillo-Villar, Hertwin Minor-Popocatl, and Erin Webb

Subjects

quality costing, optimization, logging residues, bioenergy, bioethanol, supply chain network design, logistics, biomass, Technology

Abstract

Logging residues, which refer to the unused portions of trees cut during logging, are important sources of biomass for the emerging biofuel industry and are critical feedstocks for the first-type biofuel facilities (e.g., corn-ethanol facilities). Logging residues are under-utilized sources of biomass for energetic purposes. To support the scaling-up of the bioenergy industry, it is essential to design cost-effective biofuel supply chains that not only minimize costs, but also consider the biomass quality characteristics. The biomass quality is heavily dependent upon the moisture and the ash contents. Ignoring the biomass quality characteristics and its intrinsic costs may yield substantial economic losses that will only be discovered after operations at a biorefinery have begun. This paper proposes a novel bioenergy supply chain network design model that minimizes operational costs and includes the biomass quality-related costs. The proposed model is unique in the sense that it supports decisions where quality is not unrealistically assumed to be perfect. The effectiveness of the proposed methodology is proven by assessing a case study in the state of Tennessee, USA. The results demonstrate that the ash and moisture contents of logging residues affect the performance of the supply chain (in monetary terms). Higher-than-target moisture and ash contents incur in additional quality-related costs. The quality-related costs in the optimal solution (with final ash content of 1% and final moisture of 50%) account for 27% of overall supply chain cost. Based on the numeral experimentation, the total supply chain cost increased 7%, on average, for each additional percent in the final ash content.

Published

2016

4. Development of the IBSAL-SimMOpt Method for the Optimization of Quality in a Corn Stover Supply Chain

Author

Erin Webb, Hernan Chavez, and Krystel K. Castillo-Villar

Subjects

renewable energy, bioenergy, biofuels, biomass, supply chain network design, logistics, discrete-event simulation, optimization, simulation-based optimization, Engineering, Control and Optimization, 020209 energy, Supply chain, media_common.quotation_subject, Energy Engineering and Power Technology, Biomass, 02 engineering and technology, 010501 environmental sciences, lcsh:Technology, 01 natural sciences, Simulation-based optimization, 0202 electrical engineering, electronic engineering, information engineering, Quality (business), Electrical and Electronic Engineering, Discrete event simulation, Process engineering, Engineering (miscellaneous), Operating cost, Reliability (statistics), 0105 earth and related environmental sciences, media_common, Waste management, lcsh:T, Renewable Energy, Sustainability and the Environment, business.industry, Renewable energy, business, Energy (miscellaneous)

Abstract

Variability on the physical characteristics of feedstock has a relevant effect on the reactor’s reliability and operating cost. Most of the models developed to optimize biomass supply chains have failed to quantify the effect of biomass quality and preprocessing operations required to meet biomass specifications on overall cost and performance. The Integrated Biomass Supply Analysis and Logistics (IBSAL) model estimates the harvesting, collection, transportation, and storage cost while considering the stochastic behavior of the field-to-biorefinery supply chain. This paper proposes an IBSAL-SimMOpt (Simulation-based Multi-Objective Optimization) method for optimizing the biomass quality and costs associated with the efforts needed to meet conversion technology specifications. The method is developed in two phases. For the first phase, a SimMOpt tool that interacts with the extended IBSAL is developed. For the second phase, the baseline IBSAL model is extended so that the cost for meeting and/or penalization for failing in meeting specifications are considered. The IBSAL-SimMOpt method is designed to optimize quality characteristics of biomass, cost related to activities intended to improve the quality of feedstock, and the penalization cost. A case study based on 1916 farms in Ontario, Canada is considered for testing the proposed method. Analysis of the results demonstrates that this method is able to find a high-quality set of non-dominated solutions.

Published

2017