Articles

UofT Libraries is getting a new library services platform in January 2021.
Learn more about the change.

Search Articles

Advanced search
Help

Catalogue

Articles

Databases

X
Search Filters
Format Format
Format Format
X
Sort by Item Count (A-Z)
Filter by Count
Journal Article (992) 992
Government Document (51) 51
Book Chapter (17) 17
Conference Proceeding (17) 17
Dissertation (2) 2
Publication (2) 2
Standard (1) 1
more...
Subjects Subjects
Subjects Subjects
X
Sort by Item Count (A-Z)
Filter by Count
science & technology (676) 676
physical sciences (539) 539
technology (463) 463
chemistry (396) 396
materials science (363) 363
materials science, multidisciplinary (333) 333
chemistry, physical (295) 295
electrochemistry (282) 282
high rate (223) 223
lithium (213) 213
high rate capability (211) 211
lithium-ion batteries (180) 180
physics (176) 176
batteries (169) 169
science & technology - other topics (155) 155
nanoscience & nanotechnology (147) 147
energy & fuels (146) 146
anode (131) 131
physics, applied (128) 128
exact sciences and technology (123) 123
chemistry, multidisciplinary (111) 111
electrodes (111) 111
physics, condensed matter (110) 110
anodes (107) 107
applied sciences (106) 106
lithium-ionen-akkumulator (104) 104
cathodes (101) 101
electrode materials (100) 100
high-rate capability (99) 99
kathode (96) 96
rechargeable batteries (96) 96
lithiumion (89) 89
discharge (88) 88
electrical engineering. electrical power engineering (88) 88
energy storage (88) 88
carbon (86) 86
komposit (85) 85
direct energy conversion and energy accumulation (83) 83
electrical power engineering (83) 83
electrochemical conversion: primary and secondary batteries, fuel cells (83) 83
graphene (81) 81
entladung (80) 80
engineering (79) 79
kathodenwerkstoff (79) 79
high-rate (78) 78
li-ion-batteries (76) 76
ableitvermögen (75) 75
anodenmaterial (75) 75
nanostructure (70) 70
elektrode (69) 69
high-rate performance (67) 67
high rate performance (64) 64
stromdichte (63) 63
kohlenstoff (60) 60
elektrolyt (59) 59
sodium (59) 59
nanoparticles (58) 58
electrolytes (56) 56
lithium ion battery (55) 55
lithium-ion battery (55) 55
natrium (55) 55
lithium ion batteries (54) 54
diffusion (53) 53
electrochemical analysis (51) 51
energiedichte (51) 51
nanopartikel (51) 51
elektron (50) 50
graphen (49) 49
analysis (48) 48
anode-materials (47) 47
mixed-material (46) 46
electric properties (45) 45
lithiumionenbatterie (44) 44
starkstrom (44) 44
cathode-materials (43) 43
nanofolie (42) 42
discharge-capacity (41) 41
elektrodenwerkstoff (41) 41
lithium-ions (41) 41
kapazität (40) 40
condensed matter physics (39) 39
kinetik (39) 39
lithiumbatterie (38) 38
materials (37) 37
cycles (36) 36
röntgendiffraktion (35) 35
sodium-ion batteries (34) 34
capacitors (33) 33
elektrochemische leistung (33) 33
engineering, chemical (33) 33
lithium batteries (32) 32
metallurgy & metallurgical engineering (32) 32
supercapacitors (30) 30
superkondensator (30) 30
current-density (29) 29
kinetics (29) 29
nickel (29) 29
electrode-materials (28) 28
ladungsübertragung (28) 28
leistungsdichte (28) 28
more...
Language Language
Publication Date Publication Date
Click on a bar to filter by decade
Slide to change publication date range


1. Full Text Hollow Carbon Nanospheres with Superior Rate Capability for Sodium‐Based Batteries
by Tang, Kun and Fu, Lijun and White, Robin J and Yu, Linghui and Titirici, Maria‐Magdalena and Antonietti, Markus and Maier, Joachim
Advanced energy materials, ISSN 1614-6832, 07/2012, Volume 2, Issue 7, pp. 873 - 877
anodes | hollow carbon nanospheres | sodium ion batteries | high rate capability | Physical Sciences | Chemistry | Materials Science | Technology | Materials Science, Multidisciplinary | Physics, Condensed Matter | Chemistry, Physical | Energy & Fuels | Physics | Science & Technology | Physics, Applied | Carbonization | Cycles | Nanospheres | Nanostructure | Glucose | Carbon | Anodes | Latex
Journal Article
Details down arrow
Digital rights down arrow
loading Loading Rights
2. Full Text Boosted Charge Transfer in SnS/SnO2 Heterostructures: Toward High Rate Capability for Sodium‐Ion Batteries
by Zheng, Yang and Zhou, Tengfei and Zhang, Chaofeng and Mao, Jianfeng and Liu, Huakun and Guo, Zaiping
Angewandte Chemie (International ed.), ISSN 1433-7851, 03/2016, Volume 55, Issue 10, pp. 3408 - 3413
SnO2 | SnS | heterostructures | sodium-ion batteries | high rate capability | SnO | Physical Sciences | Chemistry | Chemistry, Multidisciplinary | Science & Technology | Optoelectronics | Electric charge | Construction materials | Crystals | Mobility | Electronics | Construction specifications | Batteries | Rechargeable batteries | Design | Tin dioxide | Nanocrystals | Sodium | Driving ability | High speed | Kinetics | Electron transport | Charge transfer | Diffusion | Anodes | Heterostructures
Journal Article
Details down arrow
Digital rights down arrow
loading Loading Rights
3. Full Text Three-Dimensional Graphene Foam Supported Fe3O4 Lithium Battery Anodes with Long Cycle Life and High Rate Capability
by Luo, Jingshan and Liu, Jilei and Zeng, Zhiyuan and Ng, Chi Fan and Ma, Lingjie and Zhang, Hua and Lin, Jianyi and Shen, Zexiang and Fan, Hong Jin
Nano letters, ISSN 1530-6984, 12/2013, Volume 13, Issue 12, pp. 6136 - 6143
iron oxide | 3D graphene foam | atomic layer deposition | lithium ion battery | Li ion storage | high rate capability | Electrical engineering. Electrical power engineering | Fullerenes and related materials; diamonds, graphite | Electrical power engineering | Electrochemical conversion: primary and secondary batteries, fuel cells | Exact sciences and technology | Condensed matter: structure, mechanical and thermal properties | Materials science | Low-dimensional structures (superlattices, quantum well structures, multilayers): structure, and nonelectronic properties | Surfaces and interfaces; thin films and whiskers (structure and nonelectronic properties) | Direct energy conversion and energy accumulation | Physics | Applied sciences | Specific materials | Cross-disciplinary physics: materials science; rheology | Electrodes | Electric Power Supplies | Lithium - chemistry | Surface Properties | Nanostructures - chemistry | Ferric Compounds - chemistry | Graphite - chemistry | Index Medicus
Journal Article
Details down arrow
Digital rights down arrow
loading Loading Rights
4. Full Text Atomistic Origins of High Rate Capability and Capacity of N‑Doped Graphene for Lithium Storage
by Wang, Xi and Weng, Qunhong and Liu, Xizheng and Wang, Xuebin and Tang, Dai-Ming and Tian, Wei and Zhang, Chao and Yi, Wei and Liu, Dequan and Bando, Yoshio and Golberg, Dmitri
Nano letters, ISSN 1530-6984, 03/2014, Volume 14, Issue 3, pp. 1164 - 1171
lithium storage | atomistic origins | high capacity | N-doped graphene | high rate capability | Materials Science | Materials Science, Multidisciplinary | Physics, Condensed Matter | Science & Technology - Other Topics | Chemistry, Physical | Physics | Science & Technology | Physics, Applied | Physical Sciences | Chemistry | Nanoscience & Nanotechnology | Technology | Chemistry, Multidisciplinary | Fullerenes and related materials; diamonds, graphite | Exact sciences and technology | Condensed matter: structure, mechanical and thermal properties | Structural transitions in nanoscale materials | Materials science | Specific phase transitions | Specific materials | Equations of state, phase equilibria, and phase transitions | Cross-disciplinary physics: materials science; rheology | Transmission electron microscopy | Hole defects | Graphene | Lithium | Nanostructure | Charge transfer | Order disorder | Sheds
Journal Article
Details down arrow
Digital rights down arrow
loading Loading Rights
5. Full Text Ti3+ Self‐Doped Dark Rutile TiO2 Ultrafine Nanorods with Durable High‐Rate Capability for Lithium‐Ion Batteries
by Chen, Jun and Song, Weixin and Hou, Hongshuai and Zhang, Yan and Jing, Mingjun and Jia, Xinnan and Ji, Xiaobo
Advanced functional materials, ISSN 1616-301X, 11/2015, Volume 25, Issue 43, pp. 6793 - 6801
Ti3+ self‐doping | lithium‐ion batteries | high‐rate capabilities | nanorods | rutile TiO2 | Materials Science | Materials Science, Multidisciplinary | Physics, Condensed Matter | Science & Technology - Other Topics | Chemistry, Physical | Physics | Science & Technology | Physics, Applied | Physical Sciences | Chemistry | Nanoscience & Nanotechnology | Technology | Chemistry, Multidisciplinary | Titanium dioxide | Batteries
Journal Article
Details down arrow
Digital rights down arrow
loading Loading Rights
6. Full Text High‐Rate Capability Silicon Decorated Vertically Aligned Carbon Nanotubes for Li‐Ion Batteries
by Gohier, Aurélien and Laïk, Barbara and Kim, Ki‐Hwan and Maurice, Jean‐Luc and Pereira‐Ramos, Jean‐Pierre and Cojocaru, Costel Sorin and Van, Pierre Tran
Advanced materials (Weinheim), ISSN 0935-9648, 05/2012, Volume 24, Issue 19, pp. 2592 - 2597
nanostructure | lithium‐ion batteries | silicon | carbon nanotubes | high rate capability | lithium-ion batteries | Materials Science | Materials Science, Multidisciplinary | Physics, Condensed Matter | Science & Technology - Other Topics | Chemistry, Physical | Physics | Science & Technology | Physics, Applied | Physical Sciences | Chemistry | Nanoscience & Nanotechnology | Technology | Chemistry, Multidisciplinary | Electrodes | Electric Power Supplies | Ions - chemistry | Lithium - chemistry | Nanoparticles - chemistry | Nanotubes, Carbon - chemistry | Silicon - chemistry | Index Medicus | Condensed Matter
Journal Article
Details down arrow
Digital rights down arrow
loading Loading Rights
7. Full Text A Multi‐Ion Strategy towards Rechargeable Sodium‐Ion Full Batteries with High Working Voltage and Rate Capability
by Jiang, Chunlei and Fang, Yue and Zhang, Wenyong and Song, Xiaohe and Lang, Jihui and Shi, Lei and Tang, Yongbing
Angewandte Chemie (International ed.), ISSN 1433-7851, 12/2018, Volume 57, Issue 50, pp. 16370 - 16374
multi-ion chemistry | sodium-ion batteries | high rate performance | long cycling life | high working voltage | Physical Sciences | Chemistry | Chemistry, Multidisciplinary | Science & Technology | Electrochemistry | Electrolytes | Batteries | Electric potential | Electrochemical analysis | Electrode materials | Storage | Sodium | Feasibility studies | Sodium channels (voltage-gated) | Storage batteries | Energy storage | Design optimization | Rechargeable batteries
Journal Article
Details down arrow
Digital rights down arrow
loading Loading Rights
8. Full Text Graphitic Nanocarbon–Selenium Cathode with Favorable Rate Capability for Li–Se Batteries
by Zhang, Shuai-Feng and Wang, Wen-Peng and Xin, Sen and Ye, Huan and Yin, Ya-Xia and Guo, Yu-Guo
ACS applied materials & interfaces, ISSN 1944-8244, 03/2017, Volume 9, Issue 10, pp. 8759 - 8765
Research | graphitic carbon | high-rate capability | Li−Se batteries | chain-like Se molecules | Se cathode | Science & Technology - Other Topics | Materials Science | Nanoscience & Nanotechnology | Technology | Materials Science, Multidisciplinary | Science & Technology
Journal Article
Details down arrow
Digital rights down arrow
loading Loading Rights
9. Full Text High-rate capability of three-dimensionally ordered macroporous T-Nb2O5 through Li+ intercalation pseudocapacitance
by Lou, Shuaifeng and Cheng, Xinqun and Wang, Long and Gao, Jinlong and Li, Qin and Ma, Yulin and Gao, Yunzhi and Zuo, Pengjian and Du, Chunyu and Yin, Geping
Journal of power sources, ISSN 0378-7753, 09/2017, Volume 361, pp. 80 - 86
Lithium ion batteries | T-Nb2O5 anode | Li+ intercalation pseudocapacitance | High-rate capability | anode | intercalation pseudocapacitance | T-Nb | Physical Sciences | Chemistry | Materials Science | Technology | Materials Science, Multidisciplinary | Electrochemistry | Chemistry, Physical | Energy & Fuels | Science & Technology
Journal Article
Details down arrow
Digital rights down arrow
loading Loading Rights
10. Full Text Superior cycle stability and high rate capability of Zn–Al–In-hydrotalcite as negative electrode materials for Ni–Zn secondary batteries
by Wang, Ruijuan and Yang, Zhanhong and Yang, Bin and Wang, Tingting and Chu, Zhihao
Journal of power sources, ISSN 0378-7753, 04/2014, Volume 251, pp. 344 - 350
High rate capability | High discharge capacity | Nickel–Zinc secondary batteries | Long cycle life | Layered double hydroxides | Nickel-Zinc secondary batteries | Physical Sciences | Chemistry | Materials Science | Technology | Materials Science, Multidisciplinary | Electrochemistry | Chemistry, Physical | Energy & Fuels | Science & Technology | Electrical engineering. Electrical power engineering | Electrical power engineering | Electrochemical conversion: primary and secondary batteries, fuel cells | Exact sciences and technology | Materials | Applied sciences | Direct energy conversion and energy accumulation | Zinc compounds | Hydroxides | Batteries | Electron microscopy | Nonferrous metals | Scanning electron microscopy | Electrode materials | Nickel zinc batteries | Aluminum | Rations | Nickel | Storage batteries | Discharge | Electric batteries | Zinc
Journal Article
Details down arrow
Digital rights down arrow
loading Loading Rights
11. Full Text Elemental Sulfur and Molybdenum Disulfide Composites for Li–S Batteries with Long Cycle Life and High-Rate Capability
by Dirlam, Philip T and Park, Jungjin and Simmonds, Adam G and Domanik, Kenneth and Arrington, Clay B and Schaefer, Jennifer L and Oleshko, Vladimir P and Kleine, Tristan S and Char, Kookheon and Glass, Richard S and Soles, Christopher L and Kim, Chunjoong and Pinna, Nicola and Sung, Yung-Eun and Pyun, Jeffrey
ACS applied materials & interfaces, ISSN 1944-8244, 06/2016, Volume 8, Issue 21, pp. 13437 - 13448
Research | MoS | lithium-sulfur | rechargeable battery | inverse vulcanization | Li-S | molybdenum disulfide | high-rate | elemental sulfur | Science & Technology - Other Topics | Materials Science | Nanoscience & Nanotechnology | Technology | Materials Science, Multidisciplinary | Science & Technology
Journal Article
Details down arrow
Digital rights down arrow
loading Loading Rights
12. Full Text Rate capability improvement of Co−Ni double hydroxides integrated in cathodically partially exfoliated graphite
by Cai, Xiang and Song, Yu and Sun, Zhen and Guo, Di and Liu, Xiao-Xia
Journal of power sources, ISSN 0378-7753, 10/2017, Volume 365, pp. 126 - 133
High rate capability | Co−Ni double hydroxide | Cathodically-exfoliated graphene | Hierarchical structure | Physical Sciences | Chemistry | Materials Science | Technology | Materials Science, Multidisciplinary | Electrochemistry | Chemistry, Physical | Energy & Fuels | Science & Technology | Graphene | Hydroxides | Graphite
Journal Article
Details down arrow
Digital rights down arrow
loading Loading Rights