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You searched for subject:( lithium dendrite). Showing records 1 – 12 of 12 total matches.

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1. Tikekar, Mukul Deepak. The effect of ion transport and electrolyte rheology on morphological instabilities in electrodeposition.

Degree: PhD, Mechanical Engineering, 2017, Cornell University

 Morphological instabilities in electrodeposition have long been studied due to their important applications in electroplating and energy storage. They are receiving increased attention due to… (more)

Subjects/Keywords: Chemical engineering; Mechanical engineering; electroconvection; electrodeposition; instabilities; lithium dendrite; Lithium Battery; Electrolyte

…W. Suppression of lithium dendrite growth using cross-linked polyethylene/poly(… …Z., Xiao, J. & Liu, X. Dendrite-free lithium deposition via selfhealing electrostatic… …dual-salts electrolyte solution for dendrite-free lithium-metal based rechargeable batteries… …thought about Li dendrite formation 1.1.1 Unstable ion transport drives unstable deposition… …2.9 2.10 3.1 Schematic illustrating different stages of dendrite growth on a planar Li… 

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APA (6th Edition):

Tikekar, M. D. (2017). The effect of ion transport and electrolyte rheology on morphological instabilities in electrodeposition. (Doctoral Dissertation). Cornell University. Retrieved from http://hdl.handle.net/1813/56970

Chicago Manual of Style (16th Edition):

Tikekar, Mukul Deepak. “The effect of ion transport and electrolyte rheology on morphological instabilities in electrodeposition.” 2017. Doctoral Dissertation, Cornell University. Accessed September 28, 2020. http://hdl.handle.net/1813/56970.

MLA Handbook (7th Edition):

Tikekar, Mukul Deepak. “The effect of ion transport and electrolyte rheology on morphological instabilities in electrodeposition.” 2017. Web. 28 Sep 2020.

Vancouver:

Tikekar MD. The effect of ion transport and electrolyte rheology on morphological instabilities in electrodeposition. [Internet] [Doctoral dissertation]. Cornell University; 2017. [cited 2020 Sep 28]. Available from: http://hdl.handle.net/1813/56970.

Council of Science Editors:

Tikekar MD. The effect of ion transport and electrolyte rheology on morphological instabilities in electrodeposition. [Doctoral Dissertation]. Cornell University; 2017. Available from: http://hdl.handle.net/1813/56970


Cornell University

2. Tu, Zhengyuan. Nanoporous Polymer/Ceramic Separator Electrolyte For Lithium Metal Battery Applications.

Degree: M.S., Materials Science and Engineering, Materials Science and Engineering, 2014, Cornell University

Subjects/Keywords: lithium metal batteries; nanoporous composite; dendrite

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APA (6th Edition):

Tu, Z. (2014). Nanoporous Polymer/Ceramic Separator Electrolyte For Lithium Metal Battery Applications. (Masters Thesis). Cornell University. Retrieved from http://hdl.handle.net/1813/37153

Chicago Manual of Style (16th Edition):

Tu, Zhengyuan. “Nanoporous Polymer/Ceramic Separator Electrolyte For Lithium Metal Battery Applications.” 2014. Masters Thesis, Cornell University. Accessed September 28, 2020. http://hdl.handle.net/1813/37153.

MLA Handbook (7th Edition):

Tu, Zhengyuan. “Nanoporous Polymer/Ceramic Separator Electrolyte For Lithium Metal Battery Applications.” 2014. Web. 28 Sep 2020.

Vancouver:

Tu Z. Nanoporous Polymer/Ceramic Separator Electrolyte For Lithium Metal Battery Applications. [Internet] [Masters thesis]. Cornell University; 2014. [cited 2020 Sep 28]. Available from: http://hdl.handle.net/1813/37153.

Council of Science Editors:

Tu Z. Nanoporous Polymer/Ceramic Separator Electrolyte For Lithium Metal Battery Applications. [Masters Thesis]. Cornell University; 2014. Available from: http://hdl.handle.net/1813/37153


Delft University of Technology

3. Sreekumar Menon, Ashok (author). Strategies for Dendrite-free Lithium and Sodium Metal Anodes.

Degree: 2017, Delft University of Technology

 As the public demand for electric vehicles and consumer electronics grows at an exponential rate, traditional energy storage systems like lithium-ion batteries are proving to… (more)

Subjects/Keywords: Lithium metal battery; dendrite formation; atomic layer deposition; 3D porous nickel

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APA (6th Edition):

Sreekumar Menon, A. (. (2017). Strategies for Dendrite-free Lithium and Sodium Metal Anodes. (Masters Thesis). Delft University of Technology. Retrieved from http://resolver.tudelft.nl/uuid:3a3a1aad-4fa0-4af2-a189-5ace3e73a05f

Chicago Manual of Style (16th Edition):

Sreekumar Menon, Ashok (author). “Strategies for Dendrite-free Lithium and Sodium Metal Anodes.” 2017. Masters Thesis, Delft University of Technology. Accessed September 28, 2020. http://resolver.tudelft.nl/uuid:3a3a1aad-4fa0-4af2-a189-5ace3e73a05f.

MLA Handbook (7th Edition):

Sreekumar Menon, Ashok (author). “Strategies for Dendrite-free Lithium and Sodium Metal Anodes.” 2017. Web. 28 Sep 2020.

Vancouver:

Sreekumar Menon A(. Strategies for Dendrite-free Lithium and Sodium Metal Anodes. [Internet] [Masters thesis]. Delft University of Technology; 2017. [cited 2020 Sep 28]. Available from: http://resolver.tudelft.nl/uuid:3a3a1aad-4fa0-4af2-a189-5ace3e73a05f.

Council of Science Editors:

Sreekumar Menon A(. Strategies for Dendrite-free Lithium and Sodium Metal Anodes. [Masters Thesis]. Delft University of Technology; 2017. Available from: http://resolver.tudelft.nl/uuid:3a3a1aad-4fa0-4af2-a189-5ace3e73a05f


Delft University of Technology

4. van de Lagemaat, Rutger (author). Unweaving dendrite formation through in operando synchrotron X-ray diffraction study of individual lithium crystallites.

Degree: 2018, Delft University of Technology

  In the search for renewable energy storage materials, lithium metal has been considered the ideal electrode material for decades, due to its high specific… (more)

Subjects/Keywords: In Operando; Lithium Metal Anode; Synchrotron XRD; High Capacity Batteries; Dendrite

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APA (6th Edition):

van de Lagemaat, R. (. (2018). Unweaving dendrite formation through in operando synchrotron X-ray diffraction study of individual lithium crystallites. (Masters Thesis). Delft University of Technology. Retrieved from http://resolver.tudelft.nl/uuid:c06eff9f-a3bd-43fa-872f-c58c233ea5dd

Chicago Manual of Style (16th Edition):

van de Lagemaat, Rutger (author). “Unweaving dendrite formation through in operando synchrotron X-ray diffraction study of individual lithium crystallites.” 2018. Masters Thesis, Delft University of Technology. Accessed September 28, 2020. http://resolver.tudelft.nl/uuid:c06eff9f-a3bd-43fa-872f-c58c233ea5dd.

MLA Handbook (7th Edition):

van de Lagemaat, Rutger (author). “Unweaving dendrite formation through in operando synchrotron X-ray diffraction study of individual lithium crystallites.” 2018. Web. 28 Sep 2020.

Vancouver:

van de Lagemaat R(. Unweaving dendrite formation through in operando synchrotron X-ray diffraction study of individual lithium crystallites. [Internet] [Masters thesis]. Delft University of Technology; 2018. [cited 2020 Sep 28]. Available from: http://resolver.tudelft.nl/uuid:c06eff9f-a3bd-43fa-872f-c58c233ea5dd.

Council of Science Editors:

van de Lagemaat R(. Unweaving dendrite formation through in operando synchrotron X-ray diffraction study of individual lithium crystallites. [Masters Thesis]. Delft University of Technology; 2018. Available from: http://resolver.tudelft.nl/uuid:c06eff9f-a3bd-43fa-872f-c58c233ea5dd


Georgia Tech

5. Goodman, Johanna Karolina Stark. The morphology and coulombic efficiency of lithium metal anodes.

Degree: PhD, Chemical and Biomolecular Engineering, 2014, Georgia Tech

 Since their commercialization in 1990, the electrodes of the lithium-ion battery have remained fundamentally the same. While energy density improvements have come from reducing the… (more)

Subjects/Keywords: Battery; Lithium; Lithium metal anode; Ionic liquid; Dendrite; Whisker

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APA (6th Edition):

Goodman, J. K. S. (2014). The morphology and coulombic efficiency of lithium metal anodes. (Doctoral Dissertation). Georgia Tech. Retrieved from http://hdl.handle.net/1853/53398

Chicago Manual of Style (16th Edition):

Goodman, Johanna Karolina Stark. “The morphology and coulombic efficiency of lithium metal anodes.” 2014. Doctoral Dissertation, Georgia Tech. Accessed September 28, 2020. http://hdl.handle.net/1853/53398.

MLA Handbook (7th Edition):

Goodman, Johanna Karolina Stark. “The morphology and coulombic efficiency of lithium metal anodes.” 2014. Web. 28 Sep 2020.

Vancouver:

Goodman JKS. The morphology and coulombic efficiency of lithium metal anodes. [Internet] [Doctoral dissertation]. Georgia Tech; 2014. [cited 2020 Sep 28]. Available from: http://hdl.handle.net/1853/53398.

Council of Science Editors:

Goodman JKS. The morphology and coulombic efficiency of lithium metal anodes. [Doctoral Dissertation]. Georgia Tech; 2014. Available from: http://hdl.handle.net/1853/53398


Michigan Technological University

6. Qian, Ziwei. Effects of Ionic Liquid on Lithium Dendrite Growth.

Degree: MS, Department of Physics, 2018, Michigan Technological University

Lithium Dendrites, the microscopic fibers of lithium, often lead to a short circuit in lithium rechargeable batteries that may cause explosions and fires. However,… (more)

Subjects/Keywords: Lithium dendrite; ionic liquid; battery; electrodeposition; Monte Carlo; Statistical, Nonlinear, and Soft Matter Physics

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APA (6th Edition):

Qian, Z. (2018). Effects of Ionic Liquid on Lithium Dendrite Growth. (Masters Thesis). Michigan Technological University. Retrieved from https://digitalcommons.mtu.edu/etdr/745

Chicago Manual of Style (16th Edition):

Qian, Ziwei. “Effects of Ionic Liquid on Lithium Dendrite Growth.” 2018. Masters Thesis, Michigan Technological University. Accessed September 28, 2020. https://digitalcommons.mtu.edu/etdr/745.

MLA Handbook (7th Edition):

Qian, Ziwei. “Effects of Ionic Liquid on Lithium Dendrite Growth.” 2018. Web. 28 Sep 2020.

Vancouver:

Qian Z. Effects of Ionic Liquid on Lithium Dendrite Growth. [Internet] [Masters thesis]. Michigan Technological University; 2018. [cited 2020 Sep 28]. Available from: https://digitalcommons.mtu.edu/etdr/745.

Council of Science Editors:

Qian Z. Effects of Ionic Liquid on Lithium Dendrite Growth. [Masters Thesis]. Michigan Technological University; 2018. Available from: https://digitalcommons.mtu.edu/etdr/745


Penn State University

7. Park, Mansu. development of lithium powder based anode with conductive carbon materials for lithium batteries.

Degree: 2016, Penn State University

 Current lithium ion battery with a graphite anode shows stable cycle performance and safety. However, the lithium ion battery still has the limitation of having… (more)

Subjects/Keywords: lithium batteries; lithium powder; lithium dendrite; lithium cycling efficiency; Cycling performance; Internal short

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APA (6th Edition):

Park, M. (2016). development of lithium powder based anode with conductive carbon materials for lithium batteries. (Thesis). Penn State University. Retrieved from https://submit-etda.libraries.psu.edu/catalog/28028

Note: this citation may be lacking information needed for this citation format:
Not specified: Masters Thesis or Doctoral Dissertation

Chicago Manual of Style (16th Edition):

Park, Mansu. “development of lithium powder based anode with conductive carbon materials for lithium batteries.” 2016. Thesis, Penn State University. Accessed September 28, 2020. https://submit-etda.libraries.psu.edu/catalog/28028.

Note: this citation may be lacking information needed for this citation format:
Not specified: Masters Thesis or Doctoral Dissertation

MLA Handbook (7th Edition):

Park, Mansu. “development of lithium powder based anode with conductive carbon materials for lithium batteries.” 2016. Web. 28 Sep 2020.

Vancouver:

Park M. development of lithium powder based anode with conductive carbon materials for lithium batteries. [Internet] [Thesis]. Penn State University; 2016. [cited 2020 Sep 28]. Available from: https://submit-etda.libraries.psu.edu/catalog/28028.

Note: this citation may be lacking information needed for this citation format:
Not specified: Masters Thesis or Doctoral Dissertation

Council of Science Editors:

Park M. development of lithium powder based anode with conductive carbon materials for lithium batteries. [Thesis]. Penn State University; 2016. Available from: https://submit-etda.libraries.psu.edu/catalog/28028

Note: this citation may be lacking information needed for this citation format:
Not specified: Masters Thesis or Doctoral Dissertation


Texas A&M University

8. Kalan, Michael Andrew. A Multi-Pronged, Noninvasive Probing of Electrodeposition in Li-Ion Batteries.

Degree: MS, Mechanical Engineering, 2017, Texas A&M University

Lithium ion batteries hold the potential to play a key role in meeting our future and increasing energy storage needs. Lithium ion batteries have the… (more)

Subjects/Keywords: lithium ion battery; electrodeposition; dendrite growth; electrochemical impedance spectroscopy; python; graphite electrode; equivalent circuit; lithium plating

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APA (6th Edition):

Kalan, M. A. (2017). A Multi-Pronged, Noninvasive Probing of Electrodeposition in Li-Ion Batteries. (Masters Thesis). Texas A&M University. Retrieved from http://hdl.handle.net/1969.1/161539

Chicago Manual of Style (16th Edition):

Kalan, Michael Andrew. “A Multi-Pronged, Noninvasive Probing of Electrodeposition in Li-Ion Batteries.” 2017. Masters Thesis, Texas A&M University. Accessed September 28, 2020. http://hdl.handle.net/1969.1/161539.

MLA Handbook (7th Edition):

Kalan, Michael Andrew. “A Multi-Pronged, Noninvasive Probing of Electrodeposition in Li-Ion Batteries.” 2017. Web. 28 Sep 2020.

Vancouver:

Kalan MA. A Multi-Pronged, Noninvasive Probing of Electrodeposition in Li-Ion Batteries. [Internet] [Masters thesis]. Texas A&M University; 2017. [cited 2020 Sep 28]. Available from: http://hdl.handle.net/1969.1/161539.

Council of Science Editors:

Kalan MA. A Multi-Pronged, Noninvasive Probing of Electrodeposition in Li-Ion Batteries. [Masters Thesis]. Texas A&M University; 2017. Available from: http://hdl.handle.net/1969.1/161539


University of California – Berkeley

9. Harry, Katherine Joann. Lithium dendrite growth through solid polymer electrolyte membranes.

Degree: Materials Science & Engineering, 2016, University of California – Berkeley

 The next generation of rechargeable batteries must have significantly improved gravimetric and volumetric energy densities while maintaining a long cycle life and a low risk… (more)

Subjects/Keywords: Materials Science; Chemical engineering; Battery; Block copolymer electrolyte; Lithium dendrite; Lithium globule; Solid polymer electrolyte; X-ray microtomography

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APA (6th Edition):

Harry, K. J. (2016). Lithium dendrite growth through solid polymer electrolyte membranes. (Thesis). University of California – Berkeley. Retrieved from http://www.escholarship.org/uc/item/9xs390n4

Note: this citation may be lacking information needed for this citation format:
Not specified: Masters Thesis or Doctoral Dissertation

Chicago Manual of Style (16th Edition):

Harry, Katherine Joann. “Lithium dendrite growth through solid polymer electrolyte membranes.” 2016. Thesis, University of California – Berkeley. Accessed September 28, 2020. http://www.escholarship.org/uc/item/9xs390n4.

Note: this citation may be lacking information needed for this citation format:
Not specified: Masters Thesis or Doctoral Dissertation

MLA Handbook (7th Edition):

Harry, Katherine Joann. “Lithium dendrite growth through solid polymer electrolyte membranes.” 2016. Web. 28 Sep 2020.

Vancouver:

Harry KJ. Lithium dendrite growth through solid polymer electrolyte membranes. [Internet] [Thesis]. University of California – Berkeley; 2016. [cited 2020 Sep 28]. Available from: http://www.escholarship.org/uc/item/9xs390n4.

Note: this citation may be lacking information needed for this citation format:
Not specified: Masters Thesis or Doctoral Dissertation

Council of Science Editors:

Harry KJ. Lithium dendrite growth through solid polymer electrolyte membranes. [Thesis]. University of California – Berkeley; 2016. Available from: http://www.escholarship.org/uc/item/9xs390n4

Note: this citation may be lacking information needed for this citation format:
Not specified: Masters Thesis or Doctoral Dissertation


University of Colorado

10. Cengiz, Mazlum. Lithium Dentrite Growth Suppression and Ionic Conductivity of Li2S-P2S5-P2O5 Glass Solid Electrolytes Prepared by Mechanical Milling.

Degree: MS, 2018, University of Colorado

 Conductivity of the 77.5Li2S·22.5P2S5 (mol %) and 77.5Li2S.(22.5 – x).P2S5.xP2O5 (mol %) glassy solid state electrolytes (SSEs) and possible correlation among the conductivity, density properties,… (more)

Subjects/Keywords: solid state electrolytes; mechanical milling; dendrite growth; lithium; conductivity; Mechanical Engineering; Power and Energy

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APA (6th Edition):

Cengiz, M. (2018). Lithium Dentrite Growth Suppression and Ionic Conductivity of Li2S-P2S5-P2O5 Glass Solid Electrolytes Prepared by Mechanical Milling. (Masters Thesis). University of Colorado. Retrieved from https://scholar.colorado.edu/mcen_gradetds/166

Chicago Manual of Style (16th Edition):

Cengiz, Mazlum. “Lithium Dentrite Growth Suppression and Ionic Conductivity of Li2S-P2S5-P2O5 Glass Solid Electrolytes Prepared by Mechanical Milling.” 2018. Masters Thesis, University of Colorado. Accessed September 28, 2020. https://scholar.colorado.edu/mcen_gradetds/166.

MLA Handbook (7th Edition):

Cengiz, Mazlum. “Lithium Dentrite Growth Suppression and Ionic Conductivity of Li2S-P2S5-P2O5 Glass Solid Electrolytes Prepared by Mechanical Milling.” 2018. Web. 28 Sep 2020.

Vancouver:

Cengiz M. Lithium Dentrite Growth Suppression and Ionic Conductivity of Li2S-P2S5-P2O5 Glass Solid Electrolytes Prepared by Mechanical Milling. [Internet] [Masters thesis]. University of Colorado; 2018. [cited 2020 Sep 28]. Available from: https://scholar.colorado.edu/mcen_gradetds/166.

Council of Science Editors:

Cengiz M. Lithium Dentrite Growth Suppression and Ionic Conductivity of Li2S-P2S5-P2O5 Glass Solid Electrolytes Prepared by Mechanical Milling. [Masters Thesis]. University of Colorado; 2018. Available from: https://scholar.colorado.edu/mcen_gradetds/166


University of Colorado

11. Whiteley, Justin Michael. Design and Materials Innovations in Emergent Solid Batteries.

Degree: PhD, Mechanical Engineering, 2016, University of Colorado

  Emergent technologies, such as electric vehicles and grid energy storage, are driving iterations of the lithium-ion battery (LIB) to exhibit enhanced safety and higher… (more)

Subjects/Keywords: lithium battery; lithium dendrite; pseudocapacitance; self healing polymer; solid electrolyte; solid state battery; Inorganic Chemistry; Materials Science and Engineering; Power and Energy

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APA (6th Edition):

Whiteley, J. M. (2016). Design and Materials Innovations in Emergent Solid Batteries. (Doctoral Dissertation). University of Colorado. Retrieved from https://scholar.colorado.edu/mcen_gradetds/130

Chicago Manual of Style (16th Edition):

Whiteley, Justin Michael. “Design and Materials Innovations in Emergent Solid Batteries.” 2016. Doctoral Dissertation, University of Colorado. Accessed September 28, 2020. https://scholar.colorado.edu/mcen_gradetds/130.

MLA Handbook (7th Edition):

Whiteley, Justin Michael. “Design and Materials Innovations in Emergent Solid Batteries.” 2016. Web. 28 Sep 2020.

Vancouver:

Whiteley JM. Design and Materials Innovations in Emergent Solid Batteries. [Internet] [Doctoral dissertation]. University of Colorado; 2016. [cited 2020 Sep 28]. Available from: https://scholar.colorado.edu/mcen_gradetds/130.

Council of Science Editors:

Whiteley JM. Design and Materials Innovations in Emergent Solid Batteries. [Doctoral Dissertation]. University of Colorado; 2016. Available from: https://scholar.colorado.edu/mcen_gradetds/130


University of Michigan

12. Ho, Szushen. Layer-by-layer Assembly of Nanocomposites for Energy Applications.

Degree: PhD, Chemical Engineering, 2011, University of Michigan

 In the dissertation we utilized the versatility of layer-by-layer assembly to explore the possibilities of improving membrane characteristics in energy-related applications using such technique. Nanocomposite… (more)

Subjects/Keywords: Layer-by-Layer Assembly; Nanocomposite Membranes; Lithium Battery; Zeolite-L; Ionic Conductivity; Dendrite Inhibition; Chemical Engineering; Engineering

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APA (6th Edition):

Ho, S. (2011). Layer-by-layer Assembly of Nanocomposites for Energy Applications. (Doctoral Dissertation). University of Michigan. Retrieved from http://hdl.handle.net/2027.42/84629

Chicago Manual of Style (16th Edition):

Ho, Szushen. “Layer-by-layer Assembly of Nanocomposites for Energy Applications.” 2011. Doctoral Dissertation, University of Michigan. Accessed September 28, 2020. http://hdl.handle.net/2027.42/84629.

MLA Handbook (7th Edition):

Ho, Szushen. “Layer-by-layer Assembly of Nanocomposites for Energy Applications.” 2011. Web. 28 Sep 2020.

Vancouver:

Ho S. Layer-by-layer Assembly of Nanocomposites for Energy Applications. [Internet] [Doctoral dissertation]. University of Michigan; 2011. [cited 2020 Sep 28]. Available from: http://hdl.handle.net/2027.42/84629.

Council of Science Editors:

Ho S. Layer-by-layer Assembly of Nanocomposites for Energy Applications. [Doctoral Dissertation]. University of Michigan; 2011. Available from: http://hdl.handle.net/2027.42/84629

.