Development of a Lithium-mediated Nitrogen Reduction Process - read free eBook in online reader or directly download on the web page. Select files or add your book in reader. Download and read online ebook Development of a Lithium-mediated Nitrogen Reduction Process write by Nikifar Lazouski. This book was released on 2021. Development of a Lithium-mediated Nitrogen Reduction Process available in PDF, EPUB and Kindle. Ammonia is an important industrial chemical that is used predominantly for producing nitrogen-containing fertilizers as well as nitric acid, polymers, and pharmaceuticals. It is also being considered as an energy-dense, carbon-free energy carrier. Today, ammonia (NH3) is produced via the Haber-Bosch process, in which air, water, and fossil fuels are used to make nitrogen and hydrogen, which are then reacted at elevated temperatures and pressures to produce NH3. The use of fossil fuels as a hydrogen and energy source leads to significant CO2 emissions. In addition, the process is very centralized and capitally intensive, which makes expanding ammonia production capacity, particularly in a distributed manner, difficult. Electrochemical methods for producing ammonia from air, water, and renewable electricity have been proposed as possible solutions to these issues.
Electrochemical Ammonia Synthesis
Electrochemical Ammonia Synthesis - read free eBook in online reader or directly download on the web page. Select files or add your book in reader. Download and read online ebook Electrochemical Ammonia Synthesis write by John Anthony Schwalbe. This book was released on 2019. Electrochemical Ammonia Synthesis available in PDF, EPUB and Kindle. Due to the development of the Haber-Bosch process, humanity accounts for over half of the nitrogen fixation that occurs on Earth, the other half being microbial activity and lightning. This leads to a large footprint in terms of runoff, energy usage, and plant growth. Due to its use of methane as a source of hydrogen, the Haber-Bosch process emits 1% of all anthropogenic carbon dioxide. The high temperature and pressure required by the Haber-Bosch process also necessitates large, centralized plants. In this thesis, I explore a possible alternative, electrochemical ammonia synthesis. This process uses proton-electron pairs to reduce nitrogen at a cathode in an electrochemical cell. The only inputs are air, water, and electricity. If successful, an electrochemical ammonia cell could operate at ambient temperature and pressure due to the high driving force provided by the electric potential. The challenge of electrochemical ammonia synthesis comes from the inert nature of dinitrogen and the ease of the competing hydrogen evolution reaction. In the Haber-Bosch process, high temperatures are used to help break the N-N triple bond. In electrochemical ammonia synthesis, voltage and reactive catalysts are used. Unfortunately, at these conditions protons can be readily reduced to hydrogen rather than added to the nitrogen to form ammonia. Not only is ammonia synthesis difficult from a fundamental standpoint, it is also difficult from the standpoint of experimental validation. Because the amounts of ammonia detected are generally small, contamination is easily mistaken for positive results. For example, a human breath contains enough ammonia to produce what appears to be a promising result. Many common materials, epoxy, nitric acid, rubber gloves, etc., contain nitrogen compounds that can be reduced more easily than dinitrogen. Working with our collaborators in Ib Chorkendorff's group at DTU and other SUNCAT researchers at Stanford University we developed rigorous protocols to overcome these challenges. The only way to definitively prove ammonia synthesis is with quantitative isotopically labeled experiments with purified 15N2 gas. However, the contamination found in many commercially available cylinders of 15N2 means that such an experiment could easily be fooled. Our work on proton limitations combined with rigorous verification led to the first unambiguous demonstration of electrochemical ammonia synthesis using a lithium mediated strategy, described in chapter 3. The lithium-mediated protocol was first explored in 1993 by Tsuneto et. al., but they did not possess the techniques necessary to truly prove ammonia synthesis. Our definitive result is important for two reasons. First, it validated our theoretical framework and should inspire future research into non-aqueous systems for nitrogen reduction and other challenging reactions. Second, it allowed for a positive demonstration of ammonia synthesis. we investigated the nature of the ammonia synthesis as well as the reaction at the counter electrode. The lithium mediated system uses a THF electrolyte with dissolved lithium perchlorate as a lithium source and electrolyte and ethanol as a proton donor. The cell is operated at a voltage where lithium is plated onto the cathode. The nature of the catalyst is not obvious. Using electrochemical characterization and density functional theory, we show that lithium metal, lithium nitride, and lithium hydride are all plausible candidate catalysts. Experiments show that appreciable amount of the current ends up as lithium on the surface. Surprisingly, relatively little of this reacts to form fixed nitrogen on the cathode. Density Functional Theory experiments support this observation by showing that lithium nitride should be unstable relative to lithium metal and ammonia at the operating conditions. These calculations also suggest that lithium hydride and nitride can both act as catalysts for ammonia synthesis, opening up exciting options for materials that are stable at less reducing conditions.
Theoretical Approaches Towards Selective Electrochemical Nitrogen Reduction
Theoretical Approaches Towards Selective Electrochemical Nitrogen Reduction - read free eBook in online reader or directly download on the web page. Select files or add your book in reader. Download and read online ebook Theoretical Approaches Towards Selective Electrochemical Nitrogen Reduction write by Michael John Statt. This book was released on 2021. Theoretical Approaches Towards Selective Electrochemical Nitrogen Reduction available in PDF, EPUB and Kindle. Anthropogenic climate change poses an extraordinary risk to all aspects of life on the planet in the coming decades. There is an urgent need to diminish the world's reliance on fossil fuels. However, transitioning industrial chemical processes to renewable energy inputs presents a unique challenge to net-zero emission targets. Many processes struggle with the intermittency of renewable energy sources, such as wind and solar, and even worse, several rely on fossil fuels as chemical inputs. Ammonia synthesis is one such chemical process. Ammonia plays a vital role as fertilizer in the world's global food supply chain. At 182 M tonnes of production volume per year, the Haber- Bosch process for synthesizing ammonia is the largest chemical process operating today. However, inherent drawbacks to the Haber-Bosch process make it unsuitable for a sustainable future. The process utilizes fossil-fuel derived hydrogen as an input, accounting for 1.6% of global carbon dioxide emissions. Additionally, the process's centralization and high capital costs make it challenging to deploy in the developing world, resulting in prohibitively high fertilizer costs in regions of the world with the most food scarcity. Developing alternative, sustainable forms of ammonia production is essential towards attaining global emissions goals and decentralizing agriculture. Electrochemical ammonia synthesis is an attractive alternative to the Haber-Bosch process. By removing the need for fossil-fuel derived hydrogen and replacing the prohibitively high pressures and temperatures with moderate reducing potentials, the electrochemical nitrogen reduction reaction (NRR) addresses many of the Haber-Bosch process's fundamental drawbacks. However, electrochemical ammonia synthesis is hindered by prohibitively low selectivity; hydrogen production is kinetically favored over ammonia production on every potential electrocatalyst currently known. In this thesis, we show how insights from electronic structure calculations and theoretical kinetic modeling can be used to (1) understand the activity and selectivity challenges in electrochemical NH3 synthesis and (2) propose and improve alternative ammonia synthesis systems. In particular, we examine the role that metal nitrides will play in achieving these goals by developing a theoretical understanding of their formation, activity, and stability. We also develop kinetic models for understanding non-aqueous NRR, with a focus on lithium-mediated nitrogen reduction. These theoretical frameworks are further improved through successful experimental collaborations. The resulting systems demonstrate a promising pathway towards selective and sustainable ammonia production.
Deep Learning for the Life Sciences
Deep Learning for the Life Sciences - read free eBook in online reader or directly download on the web page. Select files or add your book in reader. Download and read online ebook Deep Learning for the Life Sciences write by Bharath Ramsundar. This book was released on 2019-04-10. Deep Learning for the Life Sciences available in PDF, EPUB and Kindle. Deep learning has already achieved remarkable results in many fields. Now it’s making waves throughout the sciences broadly and the life sciences in particular. This practical book teaches developers and scientists how to use deep learning for genomics, chemistry, biophysics, microscopy, medical analysis, and other fields. Ideal for practicing developers and scientists ready to apply their skills to scientific applications such as biology, genetics, and drug discovery, this book introduces several deep network primitives. You’ll follow a case study on the problem of designing new therapeutics that ties together physics, chemistry, biology, and medicine—an example that represents one of science’s greatest challenges. Learn the basics of performing machine learning on molecular data Understand why deep learning is a powerful tool for genetics and genomics Apply deep learning to understand biophysical systems Get a brief introduction to machine learning with DeepChem Use deep learning to analyze microscopic images Analyze medical scans using deep learning techniques Learn about variational autoencoders and generative adversarial networks Interpret what your model is doing and how it’s working
Sustainable Ammonia Production
Sustainable Ammonia Production - read free eBook in online reader or directly download on the web page. Select files or add your book in reader. Download and read online ebook Sustainable Ammonia Production write by Inamuddin. This book was released on 2020-01-09. Sustainable Ammonia Production available in PDF, EPUB and Kindle. This book presents sustainable synthetic pathways and modern applications of ammonia. It focuses on the production of ammonia using various catalytic systems and its use in fuel cells, membrane, agriculture, and renewable energy sectors. The book highlights the history, investigation, and development of sustainable pathways for ammonia production, current challenges, and state-of-the-art reviews. While discussing industrial applications, it fills the gap between laboratory research and viable applications in large-scale production.
