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

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Penn State University

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

Degree: PhD, Materials Science and Engineering, 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. (Doctoral Dissertation). Penn State University. Retrieved from https://etda.libraries.psu.edu/catalog/28028

Chicago Manual of Style (16th Edition):

Park, Mansu. “development of lithium powder based anode with conductive carbon materials for lithium batteries.” 2016. Doctoral Dissertation, Penn State University. Accessed August 05, 2020. https://etda.libraries.psu.edu/catalog/28028.

MLA Handbook (7th Edition):

Park, Mansu. “development of lithium powder based anode with conductive carbon materials for lithium batteries.” 2016. Web. 05 Aug 2020.

Vancouver:

Park M. development of lithium powder based anode with conductive carbon materials for lithium batteries. [Internet] [Doctoral dissertation]. Penn State University; 2016. [cited 2020 Aug 05]. Available from: https://etda.libraries.psu.edu/catalog/28028.

Council of Science Editors:

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


Georgia Tech

2. 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 August 05, 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. 05 Aug 2020.

Vancouver:

Goodman JKS. The morphology and coulombic efficiency of lithium metal anodes. [Internet] [Doctoral dissertation]. Georgia Tech; 2014. [cited 2020 Aug 05]. 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


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 August 05, 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. 05 Aug 2020.

Vancouver:

Sreekumar Menon A(. Strategies for Dendrite-free Lithium and Sodium Metal Anodes. [Internet] [Masters thesis]. Delft University of Technology; 2017. [cited 2020 Aug 05]. 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 August 05, 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. 05 Aug 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 Aug 05]. 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


Michigan Technological University

5. 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 August 05, 2020. https://digitalcommons.mtu.edu/etdr/745.

MLA Handbook (7th Edition):

Qian, Ziwei. “Effects of Ionic Liquid on Lithium Dendrite Growth.” 2018. Web. 05 Aug 2020.

Vancouver:

Qian Z. Effects of Ionic Liquid on Lithium Dendrite Growth. [Internet] [Masters thesis]. Michigan Technological University; 2018. [cited 2020 Aug 05]. 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


University of Colorado

6. 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 August 05, 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. 05 Aug 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 Aug 05]. 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


Cornell University

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

Degree: 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 . (Thesis). Cornell University. Retrieved from http://hdl.handle.net/1813/37153

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):

Tu, Zhengyuan. “Nanoporous Polymer/Ceramic Separator Electrolyte For Lithium Metal Battery Applications .” 2014. Thesis, Cornell University. Accessed August 05, 2020. http://hdl.handle.net/1813/37153.

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

MLA Handbook (7th Edition):

Tu, Zhengyuan. “Nanoporous Polymer/Ceramic Separator Electrolyte For Lithium Metal Battery Applications .” 2014. Web. 05 Aug 2020.

Vancouver:

Tu Z. Nanoporous Polymer/Ceramic Separator Electrolyte For Lithium Metal Battery Applications . [Internet] [Thesis]. Cornell University; 2014. [cited 2020 Aug 05]. Available from: http://hdl.handle.net/1813/37153.

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

Council of Science Editors:

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

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


University of California – Berkeley

8. 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 August 05, 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. 05 Aug 2020.

Vancouver:

Harry KJ. Lithium dendrite growth through solid polymer electrolyte membranes. [Internet] [Thesis]. University of California – Berkeley; 2016. [cited 2020 Aug 05]. 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


Texas A&M University

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

Degree: 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. (Thesis). Texas A&M University. Retrieved from http://hdl.handle.net/1969.1/161539

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):

Kalan, Michael Andrew. “A Multi-Pronged, Noninvasive Probing of Electrodeposition in Li-Ion Batteries.” 2017. Thesis, Texas A&M University. Accessed August 05, 2020. http://hdl.handle.net/1969.1/161539.

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

MLA Handbook (7th Edition):

Kalan, Michael Andrew. “A Multi-Pronged, Noninvasive Probing of Electrodeposition in Li-Ion Batteries.” 2017. Web. 05 Aug 2020.

Vancouver:

Kalan MA. A Multi-Pronged, Noninvasive Probing of Electrodeposition in Li-Ion Batteries. [Internet] [Thesis]. Texas A&M University; 2017. [cited 2020 Aug 05]. Available from: http://hdl.handle.net/1969.1/161539.

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

Council of Science Editors:

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

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


University of Michigan

10. 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 August 05, 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. 05 Aug 2020.

Vancouver:

Ho S. Layer-by-layer Assembly of Nanocomposites for Energy Applications. [Internet] [Doctoral dissertation]. University of Michigan; 2011. [cited 2020 Aug 05]. 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


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 August 05, 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. 05 Aug 2020.

Vancouver:

Whiteley JM. Design and Materials Innovations in Emergent Solid Batteries. [Internet] [Doctoral dissertation]. University of Colorado; 2016. [cited 2020 Aug 05]. 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

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

Degree: 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 . (Thesis). Cornell University. Retrieved from http://hdl.handle.net/1813/56970

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):

Tikekar, Mukul Deepak. “The effect of ion transport and electrolyte rheology on morphological instabilities in electrodeposition .” 2017. Thesis, Cornell University. Accessed August 05, 2020. http://hdl.handle.net/1813/56970.

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

MLA Handbook (7th Edition):

Tikekar, Mukul Deepak. “The effect of ion transport and electrolyte rheology on morphological instabilities in electrodeposition .” 2017. Web. 05 Aug 2020.

Vancouver:

Tikekar MD. The effect of ion transport and electrolyte rheology on morphological instabilities in electrodeposition . [Internet] [Thesis]. Cornell University; 2017. [cited 2020 Aug 05]. Available from: http://hdl.handle.net/1813/56970.

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

Council of Science Editors:

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

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

.