ΠΠ»Π΅ΠΊΡΡΠΎΠ½Π½Π°Ρ ΡΡΡΡΠΊΡΡΡΠ° ΡΠ³Π»Π΅ΡΠΎΠ΄Π½ΡΡ Π½Π°Π½ΠΎΡΡΡΠ±ΠΎΠΊ, ΠΊΠ°ΡΠ±ΠΈΠ½Π° ΠΈ ΠΌΠ΅ΡΠ°Π»Π»ΠΈΡΠ΅ΡΠΊΠΈΡ Π½Π°Π½ΠΎΠΏΡΠΎΠ²ΠΎΠ΄ΠΎΠ² Ρ ΡΠΎΡΠ΅ΡΠ½ΡΠΌΠΈ Π΄Π΅ΡΠ΅ΠΊΡΠ°ΠΌΠΈ Π·Π°ΠΌΠ΅ΡΠ΅Π½ΠΈΡ
ΠΠΈΡΡΠ΅ΡΡΠ°ΡΠΈΡ
Π Π°Π·Π²ΠΈΡΠΈΠ΅ Π½Π°Π½ΠΎΡΠ»Π΅ΠΊΡΡΠΎΠΏΠΈΠΊΠΈ Π½Π΅Π²ΠΎΠ·ΠΌΠΎΠΆΠ½ΠΎ Π±Π΅Π· ΡΠ΅ΠΎΡΠ΅ΡΠΈΡΠ΅ΡΠΊΠΈΡ ΠΌΠ΅ΡΠΎΠ΄ΠΎΠ² ΡΠ°ΡΡΠ΅ΡΠ° ΡΠ»Π΅ΠΊΡΡΠΎΠ½Π½ΡΡ ΡΠ²ΠΎΠΉΡΡΠ² Π½Π°Π½ΠΎΡΡΡΡΠΊΡΡΡ. ΠΠ»Π°Π³ΠΎΠ΄Π°ΡΡ ΡΡΡΠΎΠ³ΠΎ ΠΎΠΏΡΠ΅Π΄Π΅Π»Π΅Π½Π½ΠΎΠΉ ΡΡΡΠΎΠΉΡΠΈΠ²ΠΎΠΉ Π°ΡΠΎΠΌΠ½ΠΎΠΉ ΡΡΡΡΠΊΡΡΡΠ΅ ΠΈ ΡΠ½ΠΈΠΊΠ°Π»ΡΠ½ΡΠΌ ΡΠ»Π΅ΠΊΡΡΠΎΠ½Π½ΡΠΌ ΡΠ²ΠΎΠΉΡΡΠ²Π°ΠΌ, ΠΎΡΠΎΠ±ΡΠΉ ΠΈΠ½ΡΠ΅ΡΠ΅Ρ Π²ΡΠ·ΡΠ²Π°ΡΡ ΠΎΠ΄Π½ΠΎΡΠ»ΠΎΠΉΠ½ΡΠ΅ ΡΠ³Π»Π΅ΡΠΎΠ΄Π½ΡΠ΅ Π½Π°Π½ΠΎΡΡΡΠ±ΠΊΠΈ (ΠΠ£ΠΠ’). ΠΠ·Π²Π΅ΡΡΠ½ΠΎ ΠΌΠ½ΠΎΠΆΠ΅ΡΡΠ²ΠΎ ΠΏΡΠΈΠΌΠ΅Π½Π΅Π½ΠΈΠΉ ΠΠ£ΠΠ’ Π² Π½Π°Π½ΠΎΡΠ»Π΅ΠΊΡΡΠΎΠ½ΠΈΠΊΠ΅, Π° ΠΎΡΠ½ΠΎΠ²Π°Π½Π½ΡΠ΅ Π½Π° ΠΠ£ΠΠ’ ΡΠ»Π΅ΠΊΡΡΠΎΠ½Π½ΡΠ΅ ΡΡΡΡΠΎΠΉΡΡΠ²Π° ΡΡΠΈΡΠ°ΡΡΡΡ Π΄Π°ΠΆΠ΅ Π²ΠΎΠ·ΠΌΠΎΠΆΠ½ΡΠΌΠΈ… Π§ΠΈΡΠ°ΡΡ Π΅ΡΡ >
- Π‘ΠΎΠ΄Π΅ΡΠΆΠ°Π½ΠΈΠ΅
- ΠΡΠ΄Π΅ΡΠΆΠΊΠ°
- ΠΠΈΡΠ΅ΡΠ°ΡΡΡΠ°
- ΠΡΡΠ³ΠΈΠ΅ ΡΠ°Π±ΠΎΡΡ
- ΠΠΎΠΌΠΎΡΡ Π² Π½Π°ΠΏΠΈΡΠ°Π½ΠΈΠΈ
Π‘ΠΎΠ΄Π΅ΡΠΆΠ°Π½ΠΈΠ΅
- ΠΠ»Π°Π²Π° 1. ΠΠ±Π·ΠΎΡ Π»ΠΈΡΠ΅ΡΠ°ΡΡΡΡ
- 1. 1. Π’ΠΎΡΠ΅ΡΠ½ΡΠ΅ Π΄Π΅ΡΠ΅ΠΊΡΡ Π² ΡΠ³Π»Π΅ΡΠΎΠ΄Π½ΡΡ Π½Π°Π½ΠΎΡΡΡΠ±ΠΊΠ°Ρ , ΠΊΠ°ΡΠ±ΠΈΠ½Π΅ ΠΈ ΠΌΠ΅ΡΠ°Π»Π»ΠΈΡΠ΅ΡΠΊΠΈΡ Π½Π°Π½ΠΎΠ½ΡΠΎΠ²ΠΎΠ΄Π°Ρ
- 1. 2. ΠΠ΅ΡΠΎΠ΄ Π»ΠΈΠ½Π΅Π°ΡΠΈΠ·ΠΎΠ²Π°Π½Π½ΡΡ
ΠΏΡΠΈΡΠΎΠ΅Π΄ΠΈΠ½Π΅Π½Π½ΡΡ
ΡΠΈΠ»ΠΈΠ½Π΄ΡΠΈΡΠ΅ΡΠΊΠΈΡ
Π²ΠΎΠ»Π½ Π΄Π»Ρ ΠΈΠ΄Π΅Π°Π»ΡΠ½ΡΡ
Π½Π΅Ρ
ΠΈΡΠ°Π»ΡΠ½ΡΡ
Π½Π°Π½ΠΎΡΡΡΠ±ΠΎΠΊ
- 1. 2. 1. ΠΠ²Π΅Π΄Π΅Π½ΠΈΠ΅
- 1. 2. 2. Π‘ΡΡΡΠΊΡΡΡΠ° Π½Π°Π½ΠΎΡΡΡΠ±ΠΎΠΊ
- 1. 2. 3. ΠΠ΄Π½ΠΎΡΠ»Π΅ΠΊΡΡΠΎΠ½Π½ΡΠΉ Π³Π°ΠΌΠΈΠ»ΡΡΠΎΠ½ΠΈΠ°Π½ ΠΈ ΡΠΈΠ»ΠΈΠ½Π΄ΡΠΈΡΠ΅ΡΠΊΠΈΠΉ ΠΌΠ°ΡΡΠΈΠ½-ΡΠΈΠ½ ΠΏΠΎΡΠ΅Π½ΡΠΈΠ°Π»
- 1. 2. 4. Π Π΅ΡΠ΅Π½ΠΈΠ΅ ΡΡΠ°Π²Π½Π΅Π½ΠΈΡ Π¨ΡΡΠ΄ΠΈΠ½Π³Π΅ΡΠ° Π΄Π»Ρ ΠΌΠ΅ΠΆΡΡΠ΅ΡΠ½ΠΎΠΉ ΠΎΠ±Π»Π°ΡΡΠΈ
- 1. 2. 5. Π Π΅ΡΠ΅Π½ΠΈΠ΅ ΡΡΠ°Π²Π½Π΅Π½ΠΈΡ Π¨ΡΡΠ΄ΠΈΠ½Π³Π΅ΡΠ° Π΄Π»Ρ ΠΎΠ±Π»Π°ΡΡΠΈ ΠΠ’-ΡΡΠ΅Ρ
- 1. 2. 6. Π‘ΡΠΈΠ²ΠΊΠ° ΡΡΠ½ΠΊΡΠΈΠΉ Π½Π° Π³ΡΠ°Π½ΠΈΡΠ°Ρ ΠΠ’-ΡΡΠ΅Ρ
- 1. 2. 7. ΠΠ½ΡΠ΅Π³ΡΠ°Π»Ρ ΠΏΠ΅ΡΠ΅ΠΊΡΡΠ²Π°Π½ΠΈΡ
- 1. 2. 8. ΠΠ°ΡΡΠΈΡΠ½ΡΠ΅ ΡΠ»Π΅ΠΌΠ΅Π½ΡΡ Π³Π°ΠΌΠΈΠ»ΡΡΠΎΠ½ΠΈΠ°Π½Π°
- 1. 2. 9. ΠΠ°ΠΊΠΎΠ½Ρ Π΄ΠΈΡΠΏΠ΅ΡΡΠΈΠΈ ΡΠ»Π΅ΠΊΡΡΠΎΠ½ΠΎΠ² Π½Π°Π½ΠΎΡΡΡΠ±ΠΊΠΈ
- 1. 2. 10. ΠΠ°ΡΡΠΈΠ°Π»ΡΠ½ΡΠ΅ Π·Π°ΡΡΠ΄Ρ
- 1. 3. ΠΠ΅ΡΠΎΠ΄ Π»ΠΈΠ½Π΅Π°ΡΠΈΠ·ΠΎΠ²Π°ΠΈΠΏΡΡ
ΠΏΡΠΈΡΠΎΠ΅Π΄ΠΈΠ½Π΅Π½Π½ΡΡ
ΡΠΈΠ»ΠΈΠ½Π΄ΡΠΈΡΠ΅ΡΠΊΠΈΡ
Π²ΠΎΠ»Π½ Π΄Π»Ρ Ρ
ΠΈΡΠ°Π»ΡΠ½ΡΡ
Π½Π°Π½ΠΎΡΡΡΠ±ΠΎΠΊ
- 1. 3. 1. ΠΠ²Π΅Π΄Π΅Π½ΠΈΠ΅
- 1. 3. 2. ΠΠΈΠ½ΡΠΎΠ²Π°Ρ ΠΈ Π²ΡΠ°ΡΠ°ΡΠ΅Π»ΡΠ½Π°Ρ ΡΠΈΠΌΠΌΠ΅ΡΡΠΈΡ Π½Π°Π½ΠΎΡΡΡΠ±ΠΎΠΊ
- 1. 3. 3. Π‘ΠΈΠΌΠΌΠ΅ΡΡΠΈΡ Π²ΠΎΠ»Π½ΠΎΠ²ΡΡ ΡΡΠ½ΠΊΡΠΈΠΉ
- 1. 3. 4. ΠΠ΄Π½ΠΎΡΠ»Π΅ΠΊΡΡΠΎΠ½Π½ΡΠ΅ ΡΠΎΠ±ΡΡΠ²Π΅Π½Π½ΡΠ΅ ΡΡΠ½ΠΊΡΠΈΠΈ
- 1. 3. 5. Π‘ΠΈΠΌΠΌΠ΅ΡΡΠΈΠ·ΠΎΠ²Π°Π½Π½ΡΠ΅ Π±Π°Π·ΠΈΡΠ½ΡΠ΅ Π²ΠΎΠ»Π½ΠΎΠ²ΡΠ΅ ΡΡΠ½ΠΊΡΠΈΠΈ Π² ΠΌΠ΅ΠΆΡΡΠ΅ΡΠ½ΠΎΠΉ ΠΎΠ±Π»Π°ΡΡΠΈ
- 1. 3. 6. Π‘ΠΈΠΌΠΌΠ΅ΡΡΠΈΠ·ΠΎΠ²Π°Π½Π½ΡΠ΅ Π±Π°Π·ΠΈΡΠ½ΡΠ΅ Π²ΠΎΠ»Π½ΠΎΠ²ΡΠ΅ ΡΡΠ½ΠΊΡΠΈΠΈ Π² ΠΠ’ ΠΎΠ±Π»Π°ΡΡΠΈ
- 1. 3. 7. ΠΠ½ΡΠ΅Π³ΡΠ°Π»Ρ ΠΏΠ΅ΡΠ΅ΠΊΡΡΠ²Π°Π½ΠΈΡ ΠΈ ΠΌΠ°ΡΡΠΈΡΠ½ΡΠ΅ ΡΠ»Π΅ΠΌΠ΅Π½ΡΡ Π³Π°ΠΌΠΈΠ»ΡΡΠΎΠ½ΠΈΠ°Π½Π°
- 1. 4. ΠΠ΅ΡΠΎΠ΄ Π»ΠΈΠ½Π΅Π°ΡΠΈΠ·ΠΎΠ²Π°Π½Π½ΡΡ ΠΏΡΠΈΡΠΎΠ΅Π΄ΠΈΠ½Π΅Π½Π½ΡΡ ΡΠΈΠ»ΠΈΠ½Π΄ΡΠΈΡΠ΅ΡΠΊΠΈΡ Π²ΠΎΠ»Π½ Π΄Π»Ρ Π½Π°Π½ΠΎΠΏΡΠΎΠ²ΠΎΠ΄ΠΎΠ²
- 1. 5. ΠΡΡΠ΅ΠΊΡΡ, Π²ΠΎΠ·Π½ΠΈΠΊΠ°ΡΡΠΈΠ΅ ΠΏΡΠΈ ΡΡΠ΅ΡΠ΅ ΡΠΏΠΈΠ½-ΠΎΡΠ±ΠΈΡΠ°Π»ΡΠ½ΠΎΠ³ΠΎ Π²Π·Π°ΠΈΠΌΠΎΠ΄Π΅ΠΉΡΡΠ²ΠΈΡ Π² Π½Π°Π½ΠΎΡΡΡΠ±ΠΊΠ°Ρ
- 1. 6. ΠΡΠ²ΠΎΠ΄Ρ ΠΊ ΠΏΠ΅ΡΠ²ΠΎΠΉ Π³Π»Π°Π²Π΅
- ΠΠ»Π°Π²Π° 2. ΠΠ΅ΡΠΎΠ΄ ΡΡΠ½ΠΊΡΠΈΠΉ ΠΡΠΈΠ½Π° ΠΈ Π»ΠΈΠ½Π΅Π°ΡΠΈΠ·ΠΎΠ²Π°Π½Π½ΡΡ
ΠΏΡΠΈΡΠΎΠ΅Π΄ΠΈΠ½Π΅Π½Π½ΡΡ
ΡΠΈΠ»ΠΈΠ½Π΄ΡΠΈΡΠ΅ΡΠΊΠΈΡ
Π²ΠΎΠ»Π½ Π΄Π»Ρ ΡΠΎΡΠ΅ΡΠ½ΡΡ
Π΄Π΅ΡΠ΅ΠΊΡΠΎΠ² Π² ΠΎΠ΄Π½ΠΎΠ°ΡΠΎΠΌΠ½ΡΡ
Π½Π°Π½ΠΎΠΏΡΠΎΠ²ΠΎΠ΄Π°Ρ
ΠΈ Π½Π΅Ρ
ΠΈΡΠ°Π»ΡΠ½ΡΡ
Π½Π°Π½ΠΎΡΡΡΠ±ΠΊΠ°Ρ
- 2. 1. Π’Π΅ΠΎΡΠ΅ΡΠΈΡΠ΅ΡΠΊΠ°Ρ ΡΠ°ΡΡΡ: Π²ΡΠ²ΠΎΠ΄ ΡΡΠ°Π²Π½Π΅Π½ΠΈΠΉ
- 2. 1. 1. ΠΠ΄Π½ΠΎΡΠ»Π΅ΠΊΡΡΠΎΠΏΠ½Π°Ρ ΡΡΠ½ΠΊΡΠΈΡ ΠΡΠΈΠ½Π°
- 2. 1. 2. ΠΠ΄Π½ΠΎΡΠ»Π΅ΠΊΡΡΠΎΠΏΠ½Π°Ρ ΡΡΠ½ΠΊΡΠΈΡ ΠΡΠΈΠ½Π° Π΄Π»Ρ ΠΌΠ°ΡΡΠΈΠ²Π° ΠΠ’ ΡΡΠ΅Ρ
- 2. 1. 3. Π‘ΡΡΡΠΊΡΡΡΠ½Π°Ρ ΡΡΠ½ΠΊΡΠΈΡ ΠΡΠΈΠ½Π° Π΄Π»Ρ ΠΈΠ΄Π΅Π°Π»ΡΠ½ΠΎΠΉ Π½Π΅Ρ ΠΈΡΠ°Π»ΡΠ½ΠΎΠΉ Π½Π°Π½ΠΎΡΡΡΠ±ΠΊΠΈ ΠΈ Π½Π°Π½ΠΎΠΏΡΠΎΠ²ΠΎΠ΄Π°
- 2. 1. 4. ^ΠΌΠ°ΡΡΠΈΡΠ°
- 2. 1. 5. Π€ΡΠ½ΠΊΡΠΈΡ ΠΡΠΈΠ½Π° ΠΈ ΠΏΠ»ΠΎΡΠ½ΠΎΡΡΡ ΡΠΎΡΡΠΎΡΠ½ΠΈΠΉ Π΄Π»Ρ Π½Π΅Ρ ΠΈΡΠ°Π»ΡΠ½ΠΎΠΉ Π½Π°Π½ΠΎΡΡΡΠ±ΠΊΠΈ ΠΈ Π½Π°Π½ΠΎΠΏΡΠΎΠ²ΠΎΠ΄Π° Ρ Π΄Π΅ΡΠ΅ΠΊΡΠΎΠΌ Π·Π°ΠΌΠ΅ΡΠ΅Π½ΠΈΡ
- 2. 2. ΠΠ΅Π·ΡΠ»ΡΡΠ°ΡΡ ΡΠ°ΡΡΠ΅ΡΠΎΠ² ΡΠΎΡΠ΅ΡΠ½ΡΡ Π΄Π΅ΡΠ΅ΠΊΡΠΎΠ² Π ΠΈ N Π² ΠΊΠ°ΡΠ±ΠΈΠ½Π΅
- 2. 3. Π Π΅Π·ΡΠ»ΡΡΠ°ΡΡ ΡΠ°ΡΡΠ΅ΡΠΎΠ² ΡΠΎΡΠ΅ΡΠ½ΡΡ Π΄Π΅ΡΠ΅ΠΊΡΠΎΠ² N1 ΠΈ Zn Π² ΠΌΠ΅Π΄Π½ΠΎΠΌ ΠΎΠ΄Π½ΠΎΠ°ΡΠΎΠΌΠ½ΠΎΠΌ Π½Π°Π½ΠΎΠ½ΡΠΎΠ²ΠΎΠ΄Π΅
- 2. 4. ΠΡΠ²ΠΎΠ΄Ρ ΠΊΠΎ Π²ΡΠΎΡΠΎΠΉ Π³Π»Π°Π²Π΅
- 2. 1. Π’Π΅ΠΎΡΠ΅ΡΠΈΡΠ΅ΡΠΊΠ°Ρ ΡΠ°ΡΡΡ: Π²ΡΠ²ΠΎΠ΄ ΡΡΠ°Π²Π½Π΅Π½ΠΈΠΉ
- ΠΠ»Π°Π²Π° 3. ΠΠ΅ΡΠΎΠ΄ ΡΡΠ½ΠΊΡΠΈΠΉ ΠΡΠΈΠ½Π° ΠΈ Π»ΠΈΠ½Π΅Π°ΡΠΈΠ·ΠΎΠ²Π°Π½Π½ΡΡ
ΠΏΡΠΈΡΠΎΠ΅Π΄ΠΈΠ½Π΅Π½Π½ΡΡ
ΡΠΈΠ»ΠΈΠ½Π΄ΡΠΈΡΠ΅ΡΠΊΠΈΡ
Π²ΠΎΠ»Π½ Π΄Π»Ρ ΡΠΎΡΠ΅ΡΠ½ΡΡ
Π΄Π΅ΡΠ΅ΠΊΡΠΎΠ² Π² Ρ
ΠΈ-ΡΠ°Π»ΡΠ½ΡΡ
Π½Π°Π½ΠΎΡΡΡΠ±ΠΊΠ°Ρ
- 3. 1. Π’Π΅ΠΎΡΠ΅ΡΠΈΡΠ΅ΡΠΊΠ°Ρ ΡΠ°ΡΡΡ: Π²ΡΠ²ΠΎΠ΄ ΡΡΠ°Π²Π½Π΅Π½ΠΈΠΉ
- 3. 2. Π Π΅Π·ΡΠ»ΡΡΠ°ΡΡ ΡΠ°ΡΡΠ΅ΡΠΎΠ² ΡΠΎΡΠ΅ΡΠ½ΡΡ Π΄Π΅ΡΠ΅ΠΊΡΠΎΠ² Π ΠΈ N Π² ΡΠ³Π»Π΅ΡΠΎΠ΄Π½ΡΡ Π½Π°Π½ΠΎΡΡΡΠ±ΠΊΠ°Ρ
- 3. 3. ΠΡΠ²ΠΎΠ΄Ρ ΠΊ ΡΡΠ΅ΡΡΠ΅ΠΉ Π³Π»Π°Π²Π΅
- ΠΠ»Π°Π²Π° 4. Π Π΅Π»ΡΡΠΈΠ²ΠΈΡΡΡΠΊΠΈΠΉ ΠΌΠ΅ΡΠΎΠ΄ Π»ΠΈΠ½Π΅Π°ΡΠΈΠ·ΠΎΠ²Π°Π½Π½ΡΡ
ΠΏΡΠΈΡΠΎΠ΅Π΄ΠΈΠ½Π΅Π½Π½ΡΡ
ΡΠΈΠ»ΠΈΠ½Π΄ΡΠΈΡΠ΅ΡΠΊΠΈΡ
Π²ΠΎΠ»Π½ Ρ ΡΡΠ΅ΡΠΎΠΌ ΡΠΏΠΈΠ½-ΠΎΡΠ±ΠΈΡΠ°Π»ΡΠ½ΠΎΠ³ΠΎ (Π‘Π) Π²Π·Π°ΠΈΠΌΠΎΠ΄Π΅ΠΉΡΡΠ²ΠΈΡ
- 4. 1. Π’Π΅ΠΎΡΠ΅ΡΠΈΡΠ΅ΡΠΊΠ°Ρ ΡΠ°ΡΡΡ: Π²ΡΠ²ΠΎΠ΄ ΡΡΠ°Π²Π½Π΅Π½ΠΈΠΉ
- 4. 1. 1. ΠΠ΅ΡΠΎΠ΄ ΡΠ°ΡΡΠ΅ΡΠ°
- 4. 1. 2. ΠΠ»Π΅ΠΊΡΡΠΎΠ½Π½ΡΠΉ ΠΏΠΎΡΠ΅Π½ΡΠΈΠ°Π»
- 4. 1. 3. ΠΠ°ΡΡΠΈΡΠ½ΡΠ΅ ΡΠ»Π΅ΠΌΠ΅Π½ΡΡ ΡΠΏΠΈΠ½-ΠΎΡΠ±ΠΈΡΠ°Π»ΡΠ½ΠΎΠ³ΠΎ Π²Π·Π°ΠΈΠΌΠΎΠ΄Π΅ΠΉΡΡΠ²ΠΈΡ
- 4. 2. Π Π΅Π·ΡΠ»ΡΡΠ°ΡΡ ΡΠ°ΡΡΠ΅ΡΠΎΠ² ΡΠΏΠΈΠ½-ΠΎΡΠ±ΠΈΡΠ°Π»ΡΠ½ΡΡ ΡΠ΅Π»Π΅ΠΉ Π² Π½Π°Π½ΠΎΡΡΡΠ±ΠΊΠ°Ρ ΡΠΈΠΏΠ° ΠΊΡΠ΅ΡΠ»ΠΎ ΠΏΠΎ ΡΠ΅Π»ΡΡΠΈΠ²ΠΈΡΡΡΠΊΠΎΠΌΡ ΠΌΠ΅ΡΠΎΠ΄Ρ ΠΠΠ¦Π
- 4. 3. ΠΡΠ²ΠΎΠ΄Ρ ΠΊ ΡΠ΅ΡΠ²Π΅ΡΡΠΎΠΉ Π³Π»Π°Π²Π΅
- 4. 1. Π’Π΅ΠΎΡΠ΅ΡΠΈΡΠ΅ΡΠΊΠ°Ρ ΡΠ°ΡΡΡ: Π²ΡΠ²ΠΎΠ΄ ΡΡΠ°Π²Π½Π΅Π½ΠΈΠΉ
- ΠΡΠ²ΠΎΠ΄Ρ
Π‘ΠΏΠΈΡΠΎΠΊ Π»ΠΈΡΠ΅ΡΠ°ΡΡΡΡ
- Z. Yao et al. Carbon nanotube intramolecular junctions. // Nature. 1999. № 402. P. 273−276.
- M. Bockrath et. al. Resonant electron scattering by defects in single-walled carbon nanotubes. // Science (New York, N.Y.). 2001. № 291. P. 283−5.
- X. Zhao, Y. Ando, Y. Liu, et. al. Carbon nanowire made of a long linear carbon chain inserted inside a multiwalled carbon nanotube // Phys. Rev. Lett. 2003. Vol. 90, № 18. P. 187 401.
- D’yachkov P.N., Kutlubaev D.Z., Makaev D.V. Linear augmented cylindrical wave Green’s function method for electronic structure of nanotubes with substitutional impurities // Phys. Rev. B. 2010. Vol. 82, № 3. P. 35 426.
- ΠΡΡΠ»ΡΠ±Π°Π΅Π² Π.Π., ΠΠ°ΠΊΠ°Π΅Π² Π. Π., ΠΡΡΡΠΊΠΎΠ² Π. Π. ΠΠ»Π΅ΠΊΡΡΠΎΠ½Π½Π°Ρ ΡΡΡΡΠΊΡΡΡΠ° ΡΠ³Π»Π΅ΡΠΎΠ΄Π½ΡΡ Π½Π°Π½ΠΎΡΡΡΠ±ΠΎΠΊ Ρ ΡΠΎΡΠ΅ΡΠ½ΠΎΠΉ ΠΏΡΠΈΠΌΠ΅ΡΡΡ // ΠΡΡΠ½Π°Π» Π½Π΅ΠΎΡΠ³Π°Π½ΠΈΡΠ΅ΡΠΊΠΎΠΉ Ρ ΠΈΠΌΠΈΠΈ. 2011. Vol. 56, № 8. Π . 1371−1375.
- D’yachkov P., Kutlubaev D. Spin-Orbit Gaps in Armchair Nanotubes Calculated Using the Linear Augmented Cylindrical Wave Method // IOP Conference Series: Materials Science and Engineering. 2012. Vol. 38. P. 12 003.
- R. Saito et al. Electronic structure of graphene tubules based on Cqq // Phys. Rev. B. 1992. Vol. 46, № 3. P. 1804−1811.
- R. Saito et al. Electronic structure of chiral graphene tubules // Applied Physics Letters. 1992. Vol. 60, № 18. P. 2204−2206.
- Hainada N., Sawada S., Oshiyama A. New one-dimensional conductors: Graphitic microtubules. // Phys. Rev. Lett. 1992. № 68. P. 1579−1581.
- Mintmire J.W., Dunlap B.I., White C.T. Are fullerene tubules metallic? // Phys. Rev. Lett. 1992. № 68. P. 631−634.
- White C.T., Robertson D.H., Mintmire J.W. Helical and rotational symmetries of nanoscale graphitic tubules. // Phys. Rev. B. 1993. № 47. P. 5485−5488.
- Ebbesen T.W. Carbon Nanotubcs. // Physics Today. 1996. № 49. P. 26−32.
- Dekker C. Carbon Nanotubes as Molecular Quantum Wires. // Physics Today. 1999. № 52. P. 22−28.
- Tans S.J. m Individual single-wall carbon nanotubes as quantum wires. //, Published online: 03 April 1997- | doi:10.1038/38 6474a0. 1997. № 386. P. 474−477.
- Tans S.J., Verschueren A.R.M., Dekker C. Room-temperature transistor based on a single carbon nanotube. // Nature. 1998. № 393. P. 49−52.
- H. W. Ch. Postma et al. Carbon Nanotube Single-Electron Transistors at Room Temperature // Science. 2001. Vol. 293, № 5527. P. 76−79.
- Kong J. et al. Nanotube Molecular Wires as Chemical Sensors // Science. 2000. Vol. 287, № 5453. P. 622−625.
- Modi A. et al. Miniaturized gas ionization sensors using carbon nanotubes // Nature. 2003. Vol. 424, № 6945. P. 171−174.
- Jensen K. et al. Nanotube Radio // Nano Lett. 2007. Vol. 7, № 11. P. 3508−3511.
- Jensen K., Kim K., Zettl A. An atomic-resolution nanomechanical mass sensor // Nature Nanotechnology. 2008. Vol. 3, № 9. P. 533−537.
- Xiao L. et al. Flexible, Stretchable, Transparent Carbon Nanotube Thin Film Loudspeakers // Nano Lett. 2008. Vol. 8, № 12. P. 4539−4545.
- Rinki? M. et al. High-Speed Memory from Carbon Nanotube Field-Effect Transistors with High-? Gate Dielectric // Nano Lett. 2009. Vol. 9, № 2. P. 643−647.
- Fan Y., Goldsmith B.R., Collins P.G. Identifying and counting point defects in carbon nanotubes // Nature Materials. 2005. Vol. 4, № 12. P. 906−911.
- Krasheninnikov A.V., Banhart F. Engineering of nanostructured carbon materials with electron or ion beams // Nature Materials. 2007. Vol. 6, № 10. P. 723−733.
- Hashimoto A. et al. Direct evidence for atomic defects in graphene layers // Nature. 2004. Vol. 430, № 7002. P. 870−873.
- Osv?th Z. et al. Scanning tunneling microscopy investigation of atomic-scale carbon nanotube defects produced by Ar+ ion irradiation // Materials Science and Engineering: C. 2006. Vol. 26, № 5−7. P. 1194−1197.
- Osv?th Z. et al. STM imaging of carbon nanotube point defects // Physica Status Solidi. A: Applications and Materials Science. 2007. Vol. 204, № 6. P. 1825−1829.
- Kotakoski J. et al. B and N ion implantation into carbon nanotubes: Insight from atomistic simulations // Physical Review B. 2005. Vol. 71, № 20.
- Berthe M. et al. Reversible Defect Engineering of Single-Walled Carbon Nanotubes Using Scanning Tunneling Microscopy // Nano Lett. 2007. Vol. 7, № 12. P. 3623−3627.
- Berthe M. et al. Reversible Defect Engineering of Single-Walled Carbon Nanotubes Using Scanning Tunneling Microscopy // Nano Lett. 2007. Vol. 7, № 12. P. 3623−3627.
- Odom T.W. et al. Magnetic Clusters on Single-Walled Carbon Nanotubes: The Kondo Effect in a One-Dimensional Host // Science. 2000. Vol. 290, № 5496. P. 1549−1552.
- J.A. Robinson et al. Role of Defects in Single-Walled Carbon Nanotube Chemical Sensors // Nano Lett. 2006. Vol. 6, № 8. P. 1747−1751
- Gordillo M.C. Role of Vacancies in the Adsorption of Quantum Noble Gases inside a Bundle of Carbon Nanotubes // Phys. Rev. Lett. 2006. Vol. 96, № 21. P. 216 102.
- Sun L. et al. Carbon Nanotubes as High-Pressure Cylinders and Nanoextruders // Science. 2006. Vol. 312, № 5777. P. 1199−1202.
- Rostov M.K. et al. Dissociation of Water on Defective Carbon Substrates // Phys. Rev. Lett. 2005. Vol. 95, № 13. P. 136 105.
- Fenoglio I. et al. Structural defects play a major role in the acute lung toxicity of multiwall carbon nanotubes: physicochemical aspects // Chem. Res. Toxicol. 2008. Vol. 21, № 9. P. 1690−1697.
- Tapaszt? L. et al. Electron scattering in a multiwall carbon nanotube bend junction studied by scanning tunneling microscopy // Physical Review B. 2006. Vol. 74, № 23. P. 235 422.
- Tolvanen A. et al. Modifying the electronic structure of semiconducting single-walled carbon nanotubes by Ar+ ion irradiation // Phys. Rev. B. 2009. Vol. 79, № 12. P. 125 430.
- Maciel I.O. et al. Electron and phonon renormalization near charged defects in carbon nanotubes // Nature Materials. 2008. Vol. 7, № 11. P. 878−883.
- Freitag M. Carbon nanotubes: Doped defects tracked down // Nature Materials. 2008. Vol. 7, № 11. P. 840−841.
- A. V. Krasheninnikov, «Irradiation-induced phenomena in carbon nanotubes». In «Chemistry of Carbon Nanotubes edited by V. A. Basiuk and E. V. Basiuk, American Scientific Publishers (2008).
- Charlier J.-C., Ebbesen T.W., Lambin P. Structural and electronic properties of pentagon-heptagon pair defects in carbon nanotubes // Phys. Rev. B. 1996. Vol. 53, № 16. P. 11 108−11 113.
- Chico L. et al. Erratum: Quantum conductance of carbon nanotubes with defects Phys. Rev. B 54, 2600 (1996). // Phys. Rev. B. 2000. Vol. 61, № 15. P. 10 511.
- Chico L. et al. Pure Carbon Nanoscale Devices: Nanotube Heterojunctions // Phys. Rev. Lett. 1996. Vol. 76, № 6. P. 971−974.
- Crespi V.H., Cohen M.L., Rubio A. In Situ Band Gap Engineering of Carbon Nanotubes // Phys. Rev. Lett. 1997. Vol. 79, № 11. P. 2093−2096.
- Chico L., L? pez Sancho M.P., Mu? oz M.C. Carbon-Nanotube-Based Quantum Dot // Phys. Rev. Lett. 1998. Vol. 81, № 6. P. 1278−1281.
- Kostyrko T., Bartkowiak M., Mahan G.D. Reflection by defects in a tight-binding model of nanotubes // Phys. Rev. B. 1999. Vol. 59, № 4. P. 3241−3249.
- Kostyrko T., Bartkowiak M., Mahan G.D. Localization in carbon nanotubes within a tight-binding model // Phys. Rev. B. 1999. Vol. 60, № 15. P. 10 735−10 738.
- Lambin P. et al. Structural and electronic properties of bent carbon nanotubes // Chemical Physics Letters. 1995. Vol. 245, № 1. P. 85−89.
- Igami M., Nakanishi T., Ando T. Numerical Study of Transport in Carbon Nanotubes with Lattice Vacancy // Journal of the Physical Society of Japan. 1999. Vol. 68, № 10. P. 3146−3149.
- Choi H.J., Ihm J. Exact solutions to the tight-binding model for the conductance of carbon nanotubes // Solid State Communications. 1999. Vol. Ill, № 7. P. 385−390.
- Neophytou N., Ahmed S., Klimeck G. Influence of vacancies on metallic nanotube transport properties // Applied Physics Letters. 2007. Vol. 90, № 18. P. 182 119−182 119−3.
- Weber B. et al. Ohm’s Law Survives to the Atomic Scale // Science. 2012. Vol. 335, № 6064. P. 64−67.
- Korshak V.V. et al. Electronic structure of carbynes studied by Auger and electron energy loss spectroscopy // Carbon. 1987. Vol. 25, № 6. P. 735−738.
- Krasheninnikov A.V. Predicted scanning tunneling microscopy images of carbon nanotubes with atomic vacancies // Solid State Communications. 2001. Vol. 118, № 7. P. 361−365.
- Krasheninnikov A.V. et al. Formation of ion-irradiation-induced atomic-scale defects on walls of carbon nanotubes // Phys. Rev. B. 2001. Vol. 63, № 24. P. 245 405.
- Ando T., Nakanishi T., Igami M. Effective-Mass Theory of Carbon Nanotubes with Vacancy // Journal of the Physical Society of Japan. 1999. Vol. 68, № 12. P. 3994−4008.
- Ando T. Theory of Electronic States and Transport in Carbon Nanotubes // Journal of the Physical Society of Japan. 2005. Vol. 74, № 3. P. 777−817.
- Nakanishi T., Ando T. Numerical Study of Impurity Scattering in Carbon Nanotubes // Journal of the Physical Society of Japan. 1999. Vol. 68, № 2. P. 561−566.
- Choi H.J. et al. Defects, Quasibound States, and Quantum Conductance in Metallic Carbon Nanotubes // Phys.-Rev. Lett. 2000. Vol. 84, № 13. P. 2917−2920.
- Anantram M.P., Govindan T.R. Conductance of carbon nanotubes with disorder: A numerical study // Phys. Rev. B. 1998. Vol. 58, № 8. P. 4882−4887.
- Carroll D.L. et al. Effects of Nanodomain Formation on the Electronic Structure of Doped Carbon Nanotubes // Phys. Rev. Lett. 1998. Vol. 81, № 11. P. 2332−2335.
- Carlsson J.M. Curvature and chirality dependence of the properties of point defects in nanotubes // physica status solidi (b). 2006. Vol. 243, № 13. P. 3452−3457.
- Tien L.-G. et al. Band-gap modification of defective carbon nanotubes under a transverse electric field // Phys. Rev. B. 2005. Vol. 72, № 24. P. 245 417.
- Shtogun Y.V., Woods L.M. Electronic Structure Modulations of Radially Deformed Single Wall Carbon Nanotubes under Transverse External Electric Fields // J. Phys. Chem. C. 2009. Vol. 113, № 12. P. 4792−4796.
- Shtogun Y.V., Woods L.M. Electronic and magnetic properties of deformed and defective single wall carbon nanotubes // Carbon. 2009. Vol. 47, № 14. P. 3252−3262.
- Shtogun Y.V., Woods L.M. Mechanical properties of defective single wall carbon nanotubes // Journal of Applied Physics. 2010. Vol. 107, № 6. P. 61 803−61 803−6.
- Clogston A.M. Impurity States in Metals // Phys. Rev. 1962. Vol. 125, № 2. P. 439−443.
- Beeby J.L. The Density of Electrons in a Perfect or Imperfect Lattice // Proc. R. Soc. Lond. A. 1967. Vol. 302, № 1468. P. 113−136.
- Zeller R., Dederichs P.H. Electronic Structure of Impurities in Cu, Calculated Self-Consistently by Korringa-Kohn-Rostoker Green’s-Function Method // Phys. Rev. Lett. 1979. Vol. 42, № 25. P. 1713−1716.
- Braspenning P.J. et al. Self-consistent cluster calculations with correct embedding for 3d, 4d, and some sp impurities in copper // Phys. Rev. B. 1984. Vol. 29, № 2. P. 703−718.
- Stepanyuk V.S. et al. Application of LAPW and Green-function methods to calculation of electronic structure of crystal defects // Zeitschrift fur Physik Π Condensed Matter. 1990. Vol. 81, № 3. P. 391−396.
- Dederichs P. H., Lounis S. and Zeller R. The Korringa-Kohn-Rostoker (KKR) Green Function Method. II. Impurities and Clusters in the Bulk and on Surfaces // Computational Nanoscience: Do It Yourself! NIC Series. 2006. Vol. 31. P. 279.
- Mavropoulos P. and Papanikolaou N. The Korringa-Kohn-Rostoker (KKR) Green Function Method. I. Electronic Structure of Periodic Systems // Computational Nanoscience: Do It Yourself! NIC Series. 2006. Vol. 31. P. 131.
- Farberovich O.V. et al. Electronic structure of transition-metal impurities in semiconductors: Cu in GaP // Phys. Rev. B. 2008. Vol. 78, № 8. P. 85 206.
- Π. H. ΠΡΡΡΠΊΠΎΠ², ΠΠ»Π΅ΠΊΡΡΠΎΠ½Π½ΡΠ΅ ΡΠ²ΠΎΠΉΡΡΠ²Π° ΠΈ ΠΏΡΠΈΠΌΠ΅Π½Π΅Π½ΠΈΠ΅ Π½Π°Π½ΠΎΡΡΡΠ±ΠΎΠΊ // ΠΠΎΡΠΊΠ²Π°, ΠΠΠΠΠ, ΠΠ°Π±ΠΎΡΠ°ΡΠΎΡΠΈΡ Π·Π½Π°Π½ΠΈΠΉ, 2011
- P.N. D’yachkov, Π. Π. ΠΠ΅ΡΡ, and A.V. Nikolaev, Dokl. Chern. (Engl. Trans.) 365, 67 (1999) — in: Science and Application of Nanotubes, edited by D. Tomanek and R.J. Enbody (Kluwer Academic / Plenum Publishers. New York, 2000), 77.
- P.N. D’yachkov and D.V. Kirin, Dokl. Phys. Chem. (Engl. Trans.) 1999, 369, 326- in Proc. School and Workshop Nanotubes Nanostructures, edited by S. Bellucci, Ital. Phys. Soc., Conf. Proc. 74, 203 (2000).
- P.N. D’yachkov, In: Encyclopedia of Nanoscience and Nanotechnology, edited by H.S. Nalwa, v. 1, p. 192, American Scientific Publishers, (2004).
- D’yachkov P.N., Makaev D.V. Linear augmented cylindrical wave method for calculating the electronic structure of double-wall carbon nanotubes // Phys. Rev. B. 2006. Vol. 74, № 15. P. 155 442.
- D’yachkov P.N., Makaev D.V. Electronic structure of embedded carbon nanotubes // Phys. Rev. B. 2005. Vol. 71, № 8. P. 81 101.
- D’yachkov P.N., Hermann H. Electronic structure and interband transitions of semiconducting carbon nanotubes // Journal of Applied Physics. 2004. Vol. 95, № 1. P. 399−401.
- D’yachkov P.N., Makaev D.V. Description of band structures of armchair nanotubes using the symmetry-adapted linear augmented cylindrical wave method // physica status solidi (b). 2009. Vol. 246, № 1. P. 140−146.
- D’yachkov P.N., Makaev D.V. Electronic structure of BN nanotubes with intrinsic defects NB and BN and isoelectronic substitutional impurities PN, AsN, SbN, InB, GaB, and A1B // Journal of Physics and Chemistry of Solids. 2009. Vol. 70, № 1. P. 180−185.
- D’yachkov P.N., Hermann H., Kirin D.V. Electronic structure and interband transitions of metallic carbon nanotubes // Applied Physics Letters. 2002. Vol. 81, № 27. P. 5228−5230.
- Andersen O.K. Electronic Structure of the fee Transition Metals Ir, Rh, Pt, and Pd // Phys. Rev. B. 1970. Vol. 2, № 4. P. 883−906.
- Koelling D.D., Arbman G.O. Use of energy derivative of the radial solution in an augmented plane wave method: application to copper // Journal of Physics F: Metal Physics. 1975. Vol. 5, № 11. P. 2041−2054.
- Singh D.J., Planewaves, Pseudopotentials and the LAPW method. Kluwer: Boston, 1994.
- Nevidomskyy A.H., Cs? nyi G., Payne M.C. Chemically Active Substitutional Nitrogen Impurity in Carbon Nanotubes // Phys. Rev. Lett. 2003. Vol. 91, № 10. P. 105 502.
- J.C. Slater, Quantum chemistry of molecules and crystals, vol. 4: The self-consistent field for molecules and solids (New York, McGraw-Hill, 1974).
- Hohenberg P., Kohn W. Inhomogeneous Electron Gas // Phys. Rev. 1964. Vol. 136, № 3B. P. B864-B871.
- Kohn W., Sham L.J. Self-Consistent Equations Including Exchange and Correlation Effects // Phys. Rev. 1965. Vol. 140, № 4A. P. A1133-A1138.
- Korringa J. On the calculation of the energy of a Bloch wave in a metal // Physica. 1947. Vol. 13, № 6−7. P. 392−400.
- Kohn W., Rostoker N. Solution of the Schr? dinger Equation in Periodic Lattices with an Application to Metallic Lithium // Phys. Rev. 1954. Vol. 94, № 5. P. 1111−1120.
- Yu.P. Kudryavtsev, M.B. Evsyukov, and M.B. Guseva, Izv. Akad. Nauk, Ser. Khim., no 3, 450 (1993).
- Varfolorneeva T. et al. High-Pressure Structural Transformations of Carbyne // Inorganic Materials. 2005. Vol. 41, № 9. P. 950−954.
- Lenz J.A. et al. Processing of amorphous carbon films by ultrafast temperature treatment in a confined geometry // Journal of Applied Physics. 2001. Vol. 89, № 12. P. 8284−8290.
- Baughman R.H. Dangerously Seeking Linear Carbon // Science. 2006. Vol. 312, № 5776. P. 1009−1110.
- Bachilo S.M. et al. Structure-Assigned Optical Spectra of Single-Walled Carbon Nanotubes // Science. 2002. Vol. 298, № 5602. P. 2361−2366.
- Ouyang M. et al. Energy Gaps in «Metallic» Single-Walled Carbon Nanotubes // Science. 2001. Vol. 292, № 5517. P. 702−705.
- Skylaris C.-K. et al. Introducing ONETEP: Linear-scaling density functional simulations on parallel computers // The Journal of Chemical Physics. 2005. Vol. 122, № 8. P. 84 119−84 119−10.
- Kuemmeth F. et al. Coupling of spin and orbital motion of electrons in carbon nanotubes // Nature. 2008. Vol. 452, № 7186. P. 448−452.
- Minot E.D. et al. Determination of electron orbital magnetic moments in carbon nanotubes // Nature. 2004. Vol. 428, № 6982. P. 536−539.
- Iijima S. Helical microtubules of graphitic carbon //, Published online: 07 November 1991- | doi:10.1038/35 4056a0. 1991. Vol. 354, № 6348. P. 56−58.
- Ando T. Spin-Orbit Interaction in Carbon Nanotubes // Journal of the Physical Society of Japan. 2000. Vol. 69, № 6. P. 1757−1763.
- Chico L., L? pez-Sancho M.P., Mu? oz M.C. Curvature-induced anisotropic spin-orbit splitting in carbon nanotubes // Phys. Rev. B. 2009. Vol. 79, № 23. P. 235 423.
- Izumida W., Sato K., Saito R. Spin-Orbit Interaction in Single Wall Carbon Nanotubes: Symmetry Adapted Tight-Binding Calculation and Effective Model Analysis // Journal of the Physical Society of Japan. 2009. Vol. 78, № 7. P. 74 707.
- Huertas-Hernando D., Guinea F., Brataas A. Spin-orbit coupling in curved graphene, fullerenes, nanotubes, and nanotube caps // Phys. Rev. B. 2006. Vol. 74, № 15. P. 155 426.
- Kuemmeth F. et al. Coupling of spin and orbital motion of electrons in carbon nanotubes // Nature. 2008. Vol. 452, № 7186. P. 448−452.
- Conklin J.B., Johnson L.E., Pratt G.W. Energy Bands in PbTe // Phys. Rev. 1965. Vol. 137, № 4A. P. A1282-A1294.
- ΠΠ°Π²ΡΠ΄ΠΎΠ² A.C. ΠΠ²Π°Π½ΡΠΎΠ²Π°Ρ ΠΌΠ΅Ρ Π°Π½ΠΈΠΊΠ° // M: ΠΠ°ΡΠΊΠ°, 1973.
- Π¨ΠΈΡΡ Π.Π. ΠΠ²Π°Π½ΡΠΎΠ²Π°Ρ ΠΌΠ΅Ρ Π°Π½ΠΈΠΊΠ° // Π.: ΠΠ, 1959.
- Jeong J.-S., Lee H.-W. Curvature-enhanced spin-orbit coupling in a carbon nanotube // Phys. Rev. B. 2009. Vol. 80, № 7. P. 75 409.
- Jhang S.H. et al. Spin-orbit interaction in chiral carbon nanotubes probed in pulsed magnetic fields // Phys. Rev. B. 2010. Vol. 82, № 4. P. 41 404.
- Jespersen T.S. et al. Gate-dependent spin-orbit coupling in multielectron carbon nanotubes // Nature Physics. 2011. Vol. 7, № 4. P. 348−353.
- Ilani S., McEuen P.L. Electron Transport in Carbon Nanotubes // Annual Review of Condensed Matter Physics. 2010. Vol. 1, № 1. P. 1−25.
- Schulz A., De Martino A., Egger R. Spin-orbit coupling and spectral function of interacting electrons in carbon nanotubes // Phys. Rev. B. 2010. Vol. 82, № 3. P. 33 407.