Publications

Journals

International Patents

1. A system for direct conversion of CO2 into electrical energy based on Fe-CO2 battery, Wonbong Choi, Anil Pathak (Filed August, 2022) Application No. 63/462,518 (UNTP P0040USP1/1001248960

2. TWO-DIMENSIONAL (2D) TRANSITION METAL DICHALCOGENIDE (TMD) MATERIAL-COATED ANODE FOR IMPROVED METAL ION RECHARGEABLE BATTERIES, PCT 17/689,974, W. Choi, S. Bhoyate (2021); US Patent App. 17/689,974 (2022)

3. Anode-less solid state Li-S batteries and methods of making same, W. Choi, J. Park, David, In, 02/16/2021, US 63/137,712, UNTP.P0030US.P1/1001149409; US Patent App. 17/576,632 (2022)

4. Two Dimensional (2D) Transition Metal Dichalcogenide (TMD) Materials and Alloys as catalysts for cathode in lithium sulfur batteries, W. Choi, US Patent 11,652,206; U.S. application No. 17/219,523 (2020)

5. CATHODE COATED WITH CATALYSTS AND HYBRID ELECTROLYTES FOR HIGH-ENERGY DENSITY LITHIUM-SULFUR (Li-S) BATTERIES, W. Choi, S. Bhoyate, US20220320487A1; 63/170,862 (2021); US Patent App. 17/713,973

6. Two-dimensional transition metal dichalcogenide micro-supercapacitors, Choi, Wonbong (2019). Unites States Patent No. 16/091474. PCT/US2017/026659. (http://www.freepatentsonline.com/y2019/0139713.html)

7. Passivation of lithium metal by two-dimensional materials for rechargeable batteries, W Choi, CHA Eunho, US Patent 11,355,739

9. Korea Patent재충전용 배터리를 위한 2차원 물질에 의한 리튬 금속의 패시베이션, 10-2019-7026437 (PCT/US2018/017585) (2019)

10. China National Intellectual Property Administration, “PASSIVATION OF LITHIUM METAL BY TWO-DIMENSIONAL MATERIALS FOR RECHARGEABLE BATTERIES”, Dispatching Number: 2019082000805150 (2019)

11. European Patent “PASSIVATION OF LITHIUM METAL BY TWO-DIMENSIONAL MATERIALS FOR RECHARGEABLE BATTERIES”, Application number EP18751759.4 (PCT/US2018017585) (2019)

12. Japan: Passivation of Lithium metal by two-dimensional materials for rechargeable batteries, 2020-506519

13. THERMIONIC EMISSION BASED HIGH-EFFICIENCY PHOTOVOLTAIC SYSTEMS AND METHODS, Wonbong Choi, Weihuan Zhao, Vish Prasad, P0014US.P1 (2017)

14. Nationalized PCT 11,355,739, US Patent 16/482,372, PASSIVATION OF LITHIUM METAL BY TWO-DIMENSIONAL MATERIALS FOR RECHARGEABLE BATTERIES, Wonbong Choi, Eunho Cha, Application No. 62526656 (P0012US.P2/11704202) W. Choi, E. Cha. (2018) (FILE Date 7/31/2019; issue date 6/7/2022)

15. Choi, W.B., Cho, S.J. & Lahiri, I., High efficiency lithium ion battery anode using interface-controlled binder-free carbon nanotubes grown on metal/alloy substrates, US Patent Appl. No. 61/222,481 (2009)

16. “Nanoscale DNA Detection System Using Species- and Disease-Specific Probes for Rapid Identification” US Patent US8,597,492 B2 (Date of patent, Dec.3, 2013) Patent number: 8597492, Patent Publication Number: 20100101956. Application Number: 12/518,841

17. “Miniaturized energy-efficient plasma generator”, Wonbong Choi, FIU (2004)

18. “Method of synthesizing Y-junction single-walled carbon nanotubes and products formed thereby”, Y. Choi and W. Choi, FIU (2004)

19. US6566704B2, “Vertical carbon nanotube-field effect transistor and method of manufacturing the same”, Wonbong Choi, Jo-Won Lee, Young-Hee Lee

20. CHINA, 200410034828.5 (4/15/2004), “Method of forming conductive line for semiconductor device using carbon nanotube and semiconductor device manufactured using the method”.

21. JAPAN, 2004-137261 (5/6/2004), “Method of forming conductive line for semiconductor device using carbon nanotube and semiconductor device manufactured using the method”.

22. USA, 835,044 (4/30/2004), “Method of forming conductive line for semiconductor device using carbon nanotube and semiconductor device manufactured using the method”

23. EUROPE, 04252117.9 (4/8/2004), “Method of forming conductive line for semiconductor device using carbon nanotube and semiconductor device manufactured using the method”.

24. CANADA, 03136336.9 (5/29/2003), “Memory device utilizing vertical nanotubes”.

25. EUROPE, 03013966.1 (6/20/2003), “Memory device utilizing vertical nanotubes”.

26. JAPAN, 2003-401458 (12/1/2003), “Memory device utilizing vertical nanotubes”.

27. USA, 747,438 (12/30/2003), “Memory device utilizing vertical nanotubes”.

28. CANADA, 200310113815.2 (11/4/2003), “Nonvolatile memory device utilising vertical nanotube”.

29. EUROPE, 03257104.4 (11/11/2003), “Nonvolatile memory device utilising vertical nanotube”.

30. JAPAN, 2003-384459 (11/14/2003), “Nonvolatile memory device utilising vertical nanotube”.

31. USA, 713,214 (11/17/2003), 6,930,343 (8/16/2005) “Nonvolatile memory device utilising vertical nanotube”.

32. USA, 601,872 (6/24/2003), “Carbon nanotubes for fuel cells, method for manufacturing the same, and fuel cell using the same”.

33. JAPAN, 2003-281779 (7/29/2003), 3705795 (8/5/2005) “Carbon nanotubes for fuel cells, method for manufacturing the same, and fuel cell using the same”.

34. CANADA, 03145137.3 (6/23/2003) “Carbon nanotubes for fuel cells, method for manufacturing the same, and fuel cell using the same”.

35. CANADA, 03107258.5 (3/19/2003) “Method of manufacturing inorganic nanotube”.

36. JAPAN, 2003-174325 (6/19/2003) “Method of manufacturing inorganic nanotube”.

37. USA, 464,860 (6/19/2003) “Method of manufacturing inorganic nanotube”.

38. EUROPE, 03251320.2 (3/5/2003) “Method of manufacturing inorganic nanotube”.

39. CANADA, 03145424.0 (5/3/2003) “Semiconductor carbon nanotubes fabricated by hydrogen functionalization and method for fabricating the same”.

40. EUROPE, 03252763.2 (5/1/2003) “Semiconductor carbon nanotubes fabricated by hydrogen functionalization and method for fabricating the same”.

41. USA, 428,835 (5/5/2003) “Semiconductor carbon nanotubes fabricated by hydrogen functionalization and method for fabricating the same”.

42. JAPAN, 2003-0126118 (5/1/2003) “Semiconductor carbon nanotubes fabricated by hydrogen functionalization and method for fabricating the same”.

43. CANADA, 03128592.9 (2/9/2003) “Memory device utilizing carbon nanotubes and method of fabricating the memory device”.

44. EUROPE, 03250805.3 (2/7/2003) “Memory device utilizing carbon nanotubes and method of fabricating the memory device”.

45. USA, 361,024 (2/10/2003) “Memory device utilizing carbon nanotubes and method of fabricating the memory device”.

46. JAPAN, 2003-0030273 (2/7/2003) “Memory device utilizing carbon nanotubes and method of fabricating the memory device”.

47. JAPAN, 2003-30522 (2/7/2003) “Memory device with quantum dot and method for manufacturing the same”.

48. USA, 225,431(8/22/2002) “Memory device with quantum dot and method for manufacturing the same”.

49. CANADA, 02130478.5 (8/21/2002) “Memory device with quantum dot and method for manufacturing the same”.

50. EUROPE, 02255824.1 (8/21/2002) “Memory device with quantum dot and method for manufacturing the same”.

51. USA, 225,431 (9/27/2004) “Memory device with quantum dot and method for manufacturing the same”.

52. USA, 138,691 (5/27/2005) “Memory device with quantum dot and method for manufacturing the same”.

53. USA, 255,198 (9/25/2002) “Biochip including carbon nanotubes and method for sample separation using the same”.

54. EUROPE, 02021881.4 (9/30/2002) “Biochip including carbon nanotubes and method for sample separation using the same”.

55. JAPAN, 2002-370793 (12/20/2002) “Biochip including carbon nanotubes and method for sample separation using the same”.

56. CANADA, 02143346.1 (9/26/2002) “Biochip including carbon nanotubes and method for sample separation using the same”.

57. USA, 252,085 (9/23/2002) “High density data recording/erproduction method utilizing electron emission and phase change media, and data recording system adopting the same, and media for the system”.

58. JAPAN, 2002-270422 (9/17/2002) “High density data recording/erproduction method utilizing electron emission and phase change media, and data recording system adopting the same, and media for the system”.

59. CANADA, 02129754.1 (8/13/2002) “High density data recording/erproduction method utilizing electron emission and phase change media, and data recording system adopting the same, and media for the system”.

60. EUROPE, 02255382.0 (8/1/2002) “High density data recording/erproduction method utilizing electron emission and phase change media, and data recording system adopting the same, and media for the system”.

61. USA, 090,629 (3/6/2002) “High-density information storage apparatus using electron emission and methods of writing, reading and erasing information using same”.

62. JAPAN, 2002-103767 (4/5/2002) “High-density information storage apparatus using electron emission and methods of writing, reading and erasing information using same”.

63. CANADA, “High-density information storage apparatus using electron emission and methods of writing, reading and erasing information using same”.

64. EUROPE, “High-density information storage apparatus using electron emission and methods of writing, reading and erasing information using same”.

65. WO, PCT/KR02/01544 (8/13/2002) “Sensor for detecting biomolecule using carbon nanotubes”.

66. USA, 240,227 (9/27/2002) “Sensor for detecting biomolecule using carbon nanotubes”.

67. USA, 160,102 (6/4/2002) 6,794,666 (9/21/2004) “Electron emission lithography apparatus and method using selectively grown carbon nanotube”.

68. JAPAN, 2002-162592 (6/4/2002) “Electron emission lithography apparatus and method using selectively grown carbon nanotube”.

69. CANADA, 02144390.4 (6/4/2002), ZL02411390.4 (3/16/2005) “Electron emission lithography apparatus and method using selectively grown carbon nanotube”.

70. USA, 891,240 (6/27/2001), 6,566,704 (5/20/2003) “Vertical nano-size transistor using carbon nanotubes and manufacturing method thereof”.

71. CANADA, 01122021.X (6/22/2001), ZL01122021.X (3/16/2005) “Vertical nano-size transistor using carbon nanotubes and manufacturing method thereof”.

72. JAPAN, 2001-192414 (6/26/2001) “Vertical nano-size transistor using carbon nanotubes and manufacturing method thereof”.

73. USA, 386,536 (3/13/2003), 6,833,567 (12/21/2004) “Vertical nano-size transistor using carbon nanotubes and manufacturing method thereof”.

74. USA, 387,561 (3/14/2003), 6,855,641 (2/15/2005) “Vertical nano-size transistor using carbon nanotubes and manufacturing method thereof”.

75. USA, 388,450 (3/17/2003), 6,815,294 (11/9/2004) “Vertical nano-size transistor using carbon nanotubes and manufacturing method thereof”.

76. CANADA, 1111250.6 (3/12/2001), 01111250.6 (1/19/2005) “Field emission array with carbon nanutubes and method for fabricating the field emission array”.

77. Great Britain, 106005.2 (3/12/2001), 2361805 (9/29/2004) “Field emission array with carbon nanutubes and method for fabricating the field emission array”.

78. JAPAN, 2001-124604 (4/23/2001) “Field emission array with carbon nanotubes and method for fabricating the field emission array”.

79. USA, 837,225 (4/19/2001), 6,642,639 (11/4/2003) “Field emission array with carbon nanotubes and method for fabricating the field emission array”.

80. USA, 658,526 (9/10/2003) “Field emission array with carbon nanotubes and method for fabricating the field emission array”.

81. EUROPE, 1302389 (3/15/2001) “Method of vertically aligning carbon nanotubes on substrates at low pressure and low pressure using thermal chemical vapoor deposition with DC bias”.

82. JAPAN, 2001-73546 (3/15/2001) “Method of vertically aligning carbon nanotubes on substrates at low pressure and low pressure using thermal chemical vapoor deposition with DC bias”.

83. USA, 808,011 (3/15/2001), 6,673,392 (1/6/2004) “Method of vertically aligning carbon nanotubes on substrates at low pressure and low pressure using thermal chemical vapour deposition with DC bias”.

84. EUROPE, 303448.5 (4/25/2000) “Secondary electron amplification structure employing carbon nanotube, and plasma display panel and back light using the same”.

85. USA, 562,891 (5/1/2000), 6,346,775 (2/12/2002) “Secondary electron amplification structure employing carbon nanotube, and plasma display panel and back light using the same”.

86. JAPAN, 2000-334120 (11/1/2000) “Secondary electron amplification structure employing carbon nanotube, and plasma display panel and back light using the same”.

87. DE, 10020383.3 (4/26/2000) “Method of manufacturing carbon nanotube field emitter by electrophoretic deposition”.

88. JAPAN, 2000-239544 (8/8/2000) “Method of manufacturing carbon nanotube field emitter by electrophoretic deposition”.

89. USA, 603,201 (6/26/2000), 6,616,497 (9/9/2003) “Method of manufacturing carbon nanotube field emitter by electrophoretic deposition”.

90. Great Britain, 10071.9 (4/25/2000) “Method of manufacturing carbon nanotube field emitter by electrophoretic deposition”.

91. USA, 570,403 (5/12/2000), 6,440,761 (8/27/2002) “Carbon nanotube field emission array and method for fabricating the same”.

92. USA, 191,492 (7/10/2002) “Carbon nanotube field emission array and method for fabricating the same”.

Korean Domestic Patents

1. Y. H. Lee, W. B. Choi, 'Fabrication of a semiconducting carbon nanotube by hydrogen functionalization' (수소 기능화에 대한 반도체 탄소나노튜브 및 그 제조방법), application number: 2002-0024476, 2002.05.03.

2. W. B. Choi, Y. H. Lee, J. W. Lee, 'Vertical nanosize transistor using carbon nanotubes and manufactoring method thereof', application number: 10-2000-35702, 2000.06.27.

3. Y. H. Lee, W. B. Choi, J. W. Lee, 'Design of CNT-transistor vertically grown using a nanomask by chemical vapor deposition', application number: 10-2000-35703, 2000.06.27.

4. Y. H. Lee, K. H. An, and J. E. Yu, 'Supercapacitor using electrode of new material', application number: 00-19232, 2000.04.12.

5. Y. H. Lee, Y. C. Choi, B. S. Lee, W. B. Choi, N. S. Lee, J. M. Kim, 'Growth method for vertically aligned carbon nanotubes by changing morphologies of transition metal thin films', 2000.06, application number: 00-25333.

6. Y. H. Lee, J. M. Kim, N. S. Lee, and W. B. Choi, 'Method of larger area, vertically aligned carbon nanotubes on substrates at low temperature and low pressure using TCVD', 2000.03.15, application number: 00-13039.

7. W.B. Choi, "Growth method for vertically aligned carbon nanotubes by changing morphologies of transition metal thin films", application number: 00-25333.

8. W.B. Choi, P2000-0035702 나노마스크를 이용해 화학기상증착법으로 성장된 수직형~

9. W.B. Choi, P1998-00399 전기영동법에 의한 field emitter의 초미세 다이아몬드 분말

10. W.B. Choi, P2000-003570 탄소나노튜브를 이용한 나노크기의 수직 transistor 구조

11. W.B. Choi, P2000-003570 나노마스크를 이용해 화학기상증착법으로 성장된 수직형

12. W.B. Choi, P2000-000564 CNT를 이용한 FED

13. W.B. Choi, USP 837,255, RX-200003-014-1-US 절연성기판을 이용한 삼극관 탄소나노튜브 필드에미션 디바이스

14. W.B.Choi, P2001-0001351 탄소나노튜브를 이용한 MRAM 및 그 제조방법

15. W.B. Choi, P2000-0025333 전이금속 박막형상 조절에 의한 대면적, 수직 성장된 탄소나노튜브,

16. W. B. Choi, P1999-00331 전기영동법을 이용한 carbon nanotube의 선택증착 및 Field

17. W. B. Choi, RX-199908-012-1, P2000-000564 CNT를 이용한 DEVICE

18. W. B. Choi, P1999-001865 카본 나노 튜부를 이용한 필드에미션 어레이 제조

19. W. B. Choi, P1998-00295, Spindt형 비정질탄소 전자방출원 제조방법

20. W. B. Choi, P1998-00548, Spindt형 tip과 Schottky 접합특성을 갖는 비정질탄소막의 코팅

21. W. B. Choi, P20010049033, 탄소나노튜브를 이용한 고용량의 바이오분자 검출센서

22. W. B. Choi, '2002-0071398 (5/1/2003), 수직 탄소나노튜브 메모리 소자

23. W. B. Choi, 2002-0071041 (11/15/2002), 수직 나노튜브를 이용한 비휘발성 메모리 소자

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