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M.; Deutsch, A. R.; Tran, L.; Jones, G.; Leonard, K. C. Total Eclipse of the Zoo: Animal Behavior during a Total Solar Eclipse. Animals 2020, 10 (4), 587. https://doi.org/10.3390/ani10040587.\n"},{"item":{"id":69,"uri":"http://zotero.org/users/13528735/items/H2EF4MQM","type":"journalArticle"},"attachment":{"id":480,"type":"attachment-pdf"},"bib":"(2) Zhang, D.-L.; Zhu, J.; Qu, T.; Lattery, D. M.; Victora, R. H.; Wang, X.; Wang, J.-P. High-Frequency Magnetoacoustic Resonance through Strain-Spin Coupling in Perpendicular Magnetic Multilayers. Sci. Adv. 2020, 6 (38), eabb4607. https://doi.org/10.1126/sciadv.abb4607.\n"},{"item":{"id":103,"uri":"http://zotero.org/users/13528735/items/NVA4BDE3","type":"conferencePaper"},"attachment":{"id":678,"type":"attachment-pdf"},"bib":"(3) Xin, M.; Xu, C.; Zhu, J.; Li, P.; Tian, B.; Liu, Z.; Han, Z. Micro Electric-Field Sensor Based on Converse Piezoelectric Effect. In 22nd International Symposium on High Voltage Engineering (ISH 2021); Institution of Engineering and Technology: Hybrid Conference, Xi’an, China, 2021; pp 1404–1408. https://doi.org/10.1049/icp.2022.0425.\n"},{"item":{"id":109,"uri":"http://zotero.org/users/13528735/items/RKWNAN7T","type":"journalArticle"},"attachment":{"id":683,"type":"attachment-pdf"},"bib":"(4) Davies, C. J.; Constable, C. G. Rapid Geomagnetic Changes Inferred from Earth Observations and Numerical Simulations. Nat Commun 2020, 11 (1), 3371. https://doi.org/10.1038/s41467-020-16888-0.\n"},{"item":{"id":112,"uri":"http://zotero.org/users/13528735/items/XCRUCPLM","type":"journalArticle"},"attachment":{"id":686,"type":"attachment-pdf"},"bib":"(5) Landeau, M.; Fournier, A.; Nataf, H.-C.; Cébron, D.; Schaeffer, N. Sustaining Earth’s Magnetic Dynamo. 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In 22nd International Symposium on High Voltage Engineering (ISH 2021); Institution of Engineering and Technology: Hybrid Conference, Xi’an, China, 2021; pp 1404–1408. https://doi.org/10.1049/icp.2022.0425.\\n\"},{\"item\":{\"id\":109,\"uri\":\"http://zotero.org/users/13528735/items/RKWNAN7T\",\"type\":\"journalArticle\"},\"attachment\":{\"id\":683,\"type\":\"attachment-pdf\"},\"bib\":\"(4) Davies, C. J.; Constable, C. G. Rapid Geomagnetic Changes Inferred from Earth Observations and Numerical Simulations. Nat Commun 2020, 11 (1), 3371. https://doi.org/10.1038/s41467-020-16888-0.\\n\"},{\"item\":{\"id\":112,\"uri\":\"http://zotero.org/users/13528735/items/XCRUCPLM\",\"type\":\"journalArticle\"},\"attachment\":{\"id\":686,\"type\":\"attachment-pdf\"},\"bib\":\"(5) Landeau, M.; Fournier, A.; Nataf, H.-C.; Cébron, D.; Schaeffer, N. Sustaining Earth’s Magnetic Dynamo. 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The paper by Davies et al. (2020) discusses rapid geomagnetic changes, providing insights into the variability of the geomagnetic field as inferred from both Earth observations and numerical simulations. This work highlights the dynamic nature of the geodynamo and the importance of continuous monitoring and modeling to understand its behavior over time. Landeau et al. (2022) focus on the mechanisms that sustain Earth's magnetic dynamo, exploring the underlying physical processes that maintain the geomagnetic field. Their research is crucial for understanding the long-term stability and evolution of the geodynamo. While the other papers in the collection may not directly address the history of the geodynamo process, they contribute to the broader field of geophysics and our understanding of magnetic phenomena. For instance, the study by Zhang et al. (2020) on high-frequency magnetoacoustic resonance through strain-spin coupling in perpendicular magnetic multilayers, although not directly related to the geodynamo, reflects the ongoing research into magnetic properties and interactions that can inform geodynamo models. Similarly, the work by Xin et al. (2020) on micro electric-field sensors based on the converse piezoelectric effect, while not specific to the geodynamo, demonstrates the technological advancements that can aid in the measurement and analysis of geomagnetic and geoelectric fields. Collectively, these papers illustrate the multifaceted research efforts that contribute to our understanding of the geodynamo, from direct studies of the Earth's magnetic field to related technological and methodological developments.","sources":[{"item":{"id":109,"uri":"http://zotero.org/users/13528735/items/RKWNAN7T","type":"journalArticle"},"attachment":{"id":683,"type":"attachment-pdf"},"bib":"(1) Davies, C. J.; Constable, C. G. Rapid Geomagnetic Changes Inferred from Earth Observations and Numerical Simulations. Nat Commun 2020, 11 (1), 3371. https://doi.org/10.1038/s41467-020-16888-0.\n"},{"item":{"id":112,"uri":"http://zotero.org/users/13528735/items/XCRUCPLM","type":"journalArticle"},"attachment":{"id":686,"type":"attachment-pdf"},"bib":"(2) Landeau, M.; Fournier, A.; Nataf, H.-C.; Cébron, D.; Schaeffer, N. Sustaining Earth’s Magnetic Dynamo. Nat Rev Earth Environ 2022, 3 (4), 255–269. https://doi.org/10.1038/s43017-022-00264-1.\n"}]},"_raw":"{\"action\":\"qa\",\"payload\":{\"widget\":\"QA_RESPONSE\",\"input\":{\"answer\":\"The history of the geodynamo process, as reflected in the selected papers from the geodynamo collection, encompasses a range of studies that contribute to our understanding of Earth's magnetic field and its dynamics. The paper by Davies et al. (2020) discusses rapid geomagnetic changes, providing insights into the variability of the geomagnetic field as inferred from both Earth observations and numerical simulations. This work highlights the dynamic nature of the geodynamo and the importance of continuous monitoring and modeling to understand its behavior over time. Landeau et al. (2022) focus on the mechanisms that sustain Earth's magnetic dynamo, exploring the underlying physical processes that maintain the geomagnetic field. Their research is crucial for understanding the long-term stability and evolution of the geodynamo. While the other papers in the collection may not directly address the history of the geodynamo process, they contribute to the broader field of geophysics and our understanding of magnetic phenomena. For instance, the study by Zhang et al. (2020) on high-frequency magnetoacoustic resonance through strain-spin coupling in perpendicular magnetic multilayers, although not directly related to the geodynamo, reflects the ongoing research into magnetic properties and interactions that can inform geodynamo models. Similarly, the work by Xin et al. (2020) on micro electric-field sensors based on the converse piezoelectric effect, while not specific to the geodynamo, demonstrates the technological advancements that can aid in the measurement and analysis of geomagnetic and geoelectric fields. Collectively, these papers illustrate the multifaceted research efforts that contribute to our understanding of the geodynamo, from direct studies of the Earth's magnetic field to related technological and methodological developments.\",\"sources\":[{\"item\":{\"id\":109,\"uri\":\"http://zotero.org/users/13528735/items/RKWNAN7T\",\"type\":\"journalArticle\"},\"attachment\":{\"id\":683,\"type\":\"attachment-pdf\"},\"bib\":\"(1) Davies, C. 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Although the abstract is not provided, the title suggests that Larmor was exploring the concept that the rotation of a body like the Sun could be responsible for generating its magnetic field. This idea is foundational to the concept of the dynamo theory, which posits that the motion of conductive fluids in a rotating body can create and sustain a magnetic field. Larmor's work would have been pioneering for its time, contributing to the early theoretical framework that would eventually lead to a deeper understanding of astrophysical and geophysical magnetic phenomena, including the geodynamo process responsible for Earth's magnetic field.","sources":[{"item":{"id":415,"uri":"http://zotero.org/users/13528735/items/PTBMP3XN","type":"journalArticle"},"attachment":{"id":675,"type":"attachment-pdf"},"bib":"(1) Larmor, J. 17. 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Larmor's work would have been pioneering for its time, contributing to the early theoretical framework that would eventually lead to a deeper understanding of astrophysical and geophysical magnetic phenomena, including the geodynamo process responsible for Earth's magnetic field.\",\"sources\":[{\"item\":{\"id\":415,\"uri\":\"http://zotero.org/users/13528735/items/PTBMP3XN\",\"type\":\"journalArticle\"},\"attachment\":{\"id\":675,\"type\":\"attachment-pdf\"},\"bib\":\"(1) Larmor, J. 17. How Could a Rotating Body Such as the Sun Become a Magnet? 1919.\\n\"}]}}}","id":"lMQfPUlMjRB3PHYp","timestamp":"2024-04-27T06:35:53.038Z"} {"type":"USER_MESSAGE","content":{"newValue":"Give me a summary of /[Energy of Dissociation of Carbon Monoxide](items|386) ","newPlainTextValue":"Give me a summary of Energy of Dissociation of Carbon... 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Unfortunately, the abstract for this article is not provided in the context, and therefore, a summary of the content cannot be given based on the information available. To provide a summary, more details from the article itself would be required.","sources":[{"item":{"id":386,"uri":"http://zotero.org/users/13528735/items/KGTNTNK6","type":"journalArticle"},"attachment":{"id":643,"type":"attachment-pdf"},"bib":"(1) Gaydon, A. G.; Penney, W. G. Energy of Dissociation of Carbon Monoxide. Nature 1942, 150 (3805), 406–407. https://doi.org/10.1038/150406a0.\n"}]},"_raw":"{\"action\":\"qa\",\"payload\":{\"widget\":\"QA_RESPONSE\",\"input\":{\"answer\":\"The document with the ID 386 is a journal article titled \\\"Energy of Dissociation of Carbon Monoxide\\\" by Gaydon et al., published in 1942. Unfortunately, the abstract for this article is not provided in the context, and therefore, a summary of the content cannot be given based on the information available. To provide a summary, more details from the article itself would be required.\",\"sources\":[{\"item\":{\"id\":386,\"uri\":\"http://zotero.org/users/13528735/items/KGTNTNK6\",\"type\":\"journalArticle\"},\"attachment\":{\"id\":643,\"type\":\"attachment-pdf\"},\"bib\":\"(1) Gaydon, A. G.; Penney, W. G. Energy of Dissociation of Carbon Monoxide. Nature 1942, 150 (3805), 406–407. https://doi.org/10.1038/150406a0.\\n\"}]}}}","id":"bDOFTiQpw9pRJfpN","timestamp":"2024-04-27T07:33:44.019Z"} {"type":"USER_MESSAGE","content":{"newValue":"Provide a summary of /[A class of self-sustaining dissipative spherical dynamos](items|421) ","newPlainTextValue":"Provide a summary of A class of self-sustaining dissi... ","mentions":[{"id":"items|421","display":"A class of self-sustaining dissi...","childIndex":2,"index":21,"plainTextIndex":21}]},"states":{"creators":[],"tags":[],"items":[{"id":421,"uri":"http://zotero.org/users/13528735/items/XAH9PBLS","type":"journalArticle","title":"A class of self-sustaining dissipative spherical dynamos","creators":"George Backus","year":null}],"collections":[],"images":[]},"id":"ioRQ5ZzSsjDuJonf","timestamp":"2024-04-27T07:34:14.052Z"} {"type":"BOT_INTERMEDIATE_STEP","widget":"MARKDOWN","input":{"content":"📖 Generating the reply (this may take some time...)"},"id":"nTSlwNwKzx5MtDBw","timestamp":"2024-04-27T07:34:16.146Z"} {"type":"BOT_MESSAGE","widget":"QA_RESPONSE","input":{"answer":"The document with the ID 421 is a journal article titled \"A class of self-sustaining dissipative spherical dynamos\" by George Backus. Unfortunately, the abstract for this article is not provided in the context, and therefore, a summary of the content cannot be given based on the information available. To provide a summary, more details from the article itself would be required.","sources":[{"item":{"id":421,"uri":"http://zotero.org/users/13528735/items/XAH9PBLS","type":"journalArticle"},"attachment":{"id":676,"type":"attachment-pdf"},"bib":"(1) Backus, G. A Class of Self-Sustaining Dissipative Spherical Dynamos. Annals of Physics 1958, 4 (4), 372–447. https://doi.org/10.1016/0003-4916(58)90054-X.\n"}]},"_raw":"{\"action\":\"qa\",\"payload\":{\"widget\":\"QA_RESPONSE\",\"input\":{\"answer\":\"The document with the ID 421 is a journal article titled \\\"A class of self-sustaining dissipative spherical dynamos\\\" by George Backus. Unfortunately, the abstract for this article is not provided in the context, and therefore, a summary of the content cannot be given based on the information available. To provide a summary, more details from the article itself would be required.\",\"sources\":[{\"item\":{\"id\":421,\"uri\":\"http://zotero.org/users/13528735/items/XAH9PBLS\",\"type\":\"journalArticle\"},\"attachment\":{\"id\":676,\"type\":\"attachment-pdf\"},\"bib\":\"(1) Backus, G. A Class of Self-Sustaining Dissipative Spherical Dynamos. Annals of Physics 1958, 4 (4), 372–447. https://doi.org/10.1016/0003-4916(58)90054-X.\\n\"}]}}}","id":"Cg5ei9Hp90VY5bIG","timestamp":"2024-04-27T07:34:19.591Z"}