Espectroscopia de impedância aplicada a sistemas nanoestruturados e polímeros condutores

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(9) 5 32% 25% 16% 8% 4% 2% 1%. A b s o rb â n cia (u .a ,). 4. 3. 2. 1. 0 400. 600. 800 λ (n m ). 1000. 1200. 1400.

(10) 3 ,0. A b s o rç ã o. A b s o rç ã o. (u .a .). 2 ,5. 2 ,0. 1 ,5. 1 ,0. 0 ,5. 0 ,0 0. 1 0. 2 0. Q td . P P y (% ). 3 0.

(11) 9 0 0 8 0 0 7 0 0 6 0 0 5 0 0. Z ' Ω ( ). 4 0 0. 3 0 0. 2 0 0. 1 6 ,6 % 3 3 ,3 % 50% 6 6 ,6 % 8 3 ,3 % 100% 1 0 0 1 0. 0. 1 0. 1. 1 0. 2. 1 0. 3. 1 0. F r e q ü ê n c ia ( H z ). 4. 1 0. 5. 1 0. 6.

(12) P P Y + P V A + lu tr o l. Z ' Ω ( ). 0 1 3 5 6 8 1. 1 0 0. 10. 0. 10. 1. 10. 2. 10. 3. F r e q ü ê n c ia. 10. 4. 10. 5. 10. 6. (H z). ppy ppy+pva. 100000. Z ' Ω ( ). 10000. 1000. 100. 0. 20. 40. 60. C o n c e n tra ç ã o (% ). 80. 100. % 6 ,6 % 3 ,3 % 0% 6 ,6 % 3 ,3 % 00%.

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(14) 0 ,0 1 0. 1 / Z 'P V A= 5 , 0 4 1 3 5 e - 4 + 3 , 2 3 5 9 6 e - 5 * C 1 / Z 'H 20 = 2 , 9 4 8 8 1 e - 4 + 8 , 8 2 0 3 7 e - 5 * C 0 ,0 0 8. %. 0 ,0 0 6. 1 /Z ' Ω (. -1. ). C = C o n c e n tra ç ã o e m. 0 ,0 0 4. 0 ,0 0 2. ppy+ p va ppy. 0 ,0 0 0 0. 2 0. 4 0. 6 0. C o n c e n tr a ç ã o ( % ). 8 0. 1 0 0.

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(16) 1 2 16% 32% 50%. - Z " (1 0 8 Ω ). 1 0. 8. 6. 4. 2. 0 0. 2. 4. 6. Z' 1 ( 08Ω ). 8. 1 0. 1 2.

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(21) N a S cl Fe C. 40 30 20 10 0. C. 18. 9 A. Fe. 17. m. cl. os 6 tr a 1. S. 15. N. a. P e so (% ). 50.

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(25) L u tro l -1 0 0. -1 2 0 0. - Z " (Ω ). -8 0 0. -6 0 0. P P Y -F e 1 0 0 -0 8 5 -1 0 7 0 -2 5 5 5 -4 0 4 0 -5 5 2 5 -7 0 1 0 -8 5 0 -1 0 0. -8 0. P P Y -F e 1 0 0 -0 8 5 -1 0 7 0 -2 5 5 5 -4 0 4 0 -5 5 2 5 -7 0 1 0 -8 5 0 -1 0 0. -6 0. -Z "(Ω ). -1 0 0 0. -4 0. -2 0. 0 30. 40. 50. 60. 70. 80. Z' Ω ( ). -4 0 0. -2 0 0. 0. 0. 1 0 0. 2 0 0. 3 0 0. Z' Ω ( ). 4 0 0. 5 0 0. 90.

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(27) -1 2 0 0. s d s - 1 0 0 /0 s d s - 8 5 /1 0 s d s - 7 0 /2 5 s d s - 5 5 /4 0 s d s - 4 0 /5 5 s d s - 2 5 /7 0 s d s - 1 0 /8 5 s d s - 0 /1 0 0. -1 0 0 0. -6 0 0. -4 0 0. -2 0 0. 0. 40. 80. 120. 160. 200. 240. 280. 320. 360. Z' Ω ( ). 7 5. 7 0. 6 5. 6 0. Z ' Ω ( ). Z " (Ω ). -8 0 0. 5 5. 5 0. L u tro l S D S. 4 5. 4 0. 0. 2 0. 4 0. 6 0. Q td . P P Y. 8 0. 1 0 0. 400.

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(29) 1 ,0 0 ,8. sds lu t r o l. 0 ,6 0 ,4 0 ,2. d Z ' /d C. 0 ,0 -0 ,2 -0 ,4 -0 ,6 -0 ,8 -1 ,0 -1 ,2 -1 ,4 0. 2 0. 4 0. 6 0. C o n c e n tra ç ã o (% ). 8 0. 1 0 0.

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(38) CAR. TAR.

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(40) S ub s tra to B arreira m ó vel. S ub-fa se a q u osa. M olé c ula s a nfifílic as.

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(42) RZ. RY. Rx.

(43) 0,6. A bsorbância (u.a.). 0,5 0,4 0,3 0,2 0,1 0,0 30 0. 35 0. 40 0. 45 0. λ (nm ). 50 0. 55 0. 60 0.

(44) TAR 1 0. 9. 1 0. 8. 1 0. 7. 1 0. 6. R. Y X. Z '. (Ω ). R. 1 0. 5. 1 0. 2. 1 0. 3. 1 0. 4. 1 0. F r e q ü ê n c ia ( H z ). 5. 1 0. 6.

(45) C A R 1 0. 9. 1 0. 8. 1 0. 7. 1 0. 6. 1 0. 5. Z ' (Ω ). R. 1 0. R. 2. 1 0. 3. 1 0. 4. 1 0. F r e q ü ê n c ia ( H z ). 5. y X. 1 0. 6.

(46) TAR. Z ' (Ω ). 1 4 0. 1 2 0. 1 0. 4. 1 0. 5. 1 0. 6. C a p a c itâ n c ia ( F ). F r e q ü ê n c ia ( H z ). 1 0. -6. 1 0. -7. 1 0. -8. 1 0. -9. 1 0. -1 0. 1 0. -1 1. 1 0. -1 2. 1 0. -1 3. 1 0. C z C y. 1. 1 0. 2. 1 0. 3. 1 0. 4. 1 0. F r e q ü ê n c ia ( H z ). 5. 1 0. 6.

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(48) TAR 1:1 50 off 1 min 5 min 10 min 15 min 20 min 25 min 30 min. 40. Z"(Ω). 30. 20. 10. 0 140. 160. 180. 200. Z' Ω( ). 220. 240. 260.

(49) CAR 1:1 250. Z' Ω ' )(. 200. 150. off 1 min 5 min 10 min 15 min 20 min 25 min 30 min. 100. 50. 0 1000. 1100. 1200. 1300. 1400. Z' Ω( ). 1500. 1600. 1700.

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(52) S olu çã o aqu osa. Em u lsã o.

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(58) cis I - c iIs. 1 0 6. C - cCi s B - cBi s B C BC - c is A - cAi s A c AC - c is A BAB - c is. Z ' (Ω ). A BABC C - c is. 1 0 5. 1 0 4. 1 0 -1. 1 0 0. 1 0 1. 1 0 2. 1 0 3. F r e q ü ê n c ia. 1 0 4. 1 0 5. (H z ). 1 0 6. 1 0 7.

(59) A -P V A B - R e tin a l C - T e m p o d e a g ita ç ã o TR AN S C IS. 1 ,0 0 ,8 0 ,6. B. R e s p o s ta - Z '. 0 ,4. A C. 0 ,2 0 ,0 1. 2. 3. 4. 5. 6. 7. B C. A B C. -0 ,2 -0 ,4 -0 ,6 -0 ,8 -1 ,0. A. C. A B.

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(63) 1 ,0. A- PVA B - Á c i d o r e t in ó i c o C - T e m p o d e a g it a ç ã o. 0 ,8. R e s p o s ta -D e n s id a d e d e p a r t í c u la s. 0 ,6. C. 0 ,4 0 ,2. AB. A. ABC. AC. 0 ,0 1. 2. - 0 ,2 - 0 ,4 - 0 ,6 - 0 ,8. 3. 4. 5. 6. BC B. 7.

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(67) Ab sorbân c ia (u. arb.). tran s-3 0% c is -3 0%. 2. 0 300. 400. λ (n m ). 500.

(68) A b so rb â n c ia (u . a rb .). c is. lu tro l 4 1 μL 8 3 μL 1 2 4 μL 1 6 8 μL 2 0 8 μL. 0 ,2. 0 ,0 300. 400. λ (nm ). 500.

(69) 0 ,3 0. Y = -0 ,0 6 0 7 1 + 0 ,0 0 1 5 4 X. A b s o rb â n c ia (u . a rb .). 0 ,2 5. 0 ,2 0. 0 ,1 5. 0 ,1 0. 0 ,0 5. 0 ,0 0 20. 40. 60. 80. 100. 120. 140. Q td . r e tin a l ( μ L ). 160. 180. 200. 220.

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(71) 3. Z' Ω (). 6 x1 0. cis trans 5 x1 0. 3. 10. 1. 10. 2. 10. 3. 10. 4. F req üên cia (H z). 10. 5. 10. 6.

(72) -2 0 0 0. Z "(Ω). c is tra n s. -1 0 0 0. 0 6000. 6500. Z' Ω (). 7000.

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(74) 16200 16000 15800. Z' Ω (). 15600 15400 15200 15000. trans cis. 14800 14600 14400 20. 40. 60. 80. 100. 120. 140. V ol. retinal ( μl). 160. 180. 200. 220.

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(76) 0 ,2 0 0 ,1 8. c is - e s c u ro 3 0 m in -lu z 6 0 m in - lu z. A b s o rb â n c ia (u .a .). 0 ,1 6 0 ,1 4 0 ,1 2 0 ,1 0 0 ,0 8 0 ,0 6 0 ,0 4 0 ,0 2 0 ,0 0 200. 300. 400. λ(n m ).

(77) 0 ,2 0 0 ,1 8. A b s o rb â n c ia (u .a .). 0 ,1 6 0 ,1 4 0 ,1 2 0 ,1 0 0 ,0 8 0 ,0 6. tra n s -e s c u ro 3 0 m in -lu z 6 0 m in -lu z. 0 ,0 4 0 ,0 2 0 ,0 0 200. 300. 400. λ(n m ).

(78) 0,78. Z' ics/Z'trans. 1,070. 0,76. Acis/Atrans 1,065. 0,74. 0,72 1,060 0,70 1,055 0,68. 1,050. 0,66. 0,64 1,045 0,62 0. 20. 40. 60. t(min). 80. 100. 120.

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(90) 10. Z ' Ω( ). 10. 10. 10. 10. 7. 6. 5. g a s o lin a g a s o lin a -9 0 % g a s o lin a -8 0 % g a s o lin a -6 5 % g a s o lin a -5 0 % á lc o o l. 4. 3. 10. 0. 10. 1. 10. 2. 10. 3. 10. 4. 10. 5. 10. 6. 10. 6. F re q ü ê n c ia (H z). 10. 5. Z "(Ω). 10. 6. 10. 10. g a s o lin a g a s o lin a -9 0 % g a s o lin a -8 0 % g a s o lin a -6 5 % g a s o lin a -5 0 % á lc o o l. 4. 3. 10. 2. 10. 3. 10. 4. F re q ü ê n c ia (H z). 10. 5.

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(94) Água 700 1 0 0 ,0. 600. leite 100 μL 200 μL 300 μL 400 μL 500 μL 600 μL 700 μL 800 μL 900 μL 1000μL. 500 9 9 ,5. Y A x i s T i t le. 400. Z' Ω) (. 300. 9 9 ,0. 9 8 ,5. 200. 9 8 ,0 2x10. 5. 4x10. 5. 5. 5. 6x108x1010. 6. X A x is T it le. 100 10. 0. 10. 1. 10. 2. 10. 3. 10. 4. 10. 5. 10. 6. Freqüência (Hz). C á lc io 110 100 90. le it e 10m g 20m g 30m g 40m g 50m g 60m g 70m g 80m g 90m g 100m g. 80. Z ' Ω ( ). 70 60 50. Z ' Ω ( ). 40. 30 2 x1 0. 5. 4 x1 0. 5. 5. 5. 6 x1 08 x1 01 0. 6. F r e q ü ê n c ia (H z ). 1 0. 0. 1 0. 1. 1 0. 2. 1 0. 3. 1 0. F r e q ü ê n c ia ( H z ). 4. 1 0. 5. 1 0. 6.

(95) C o le s te ro l 1000. Z' Ω ( ). Z ' (Ω ). 100. le ite 0 ,5 m g 1m g 1 ,5 m g 2m g 2 ,5 m g 3m g 3 ,5 m g 4m g 4 ,5 m g 5m g. 98. 96. 10. 4. 10. 5. 10. 6. F r e qü ê n cia (H z ). 100. 10. 0. 10. 1. 10. 2. 10. 3. 10. 4. 10. 5. 10. 6. F r e q ü ê n c ia ( H z ). Ferro 600. 101. 500. leite 1mg 2mg 3mg 4mg 5mg 6mg 7mg 8mg 9mg 10mg. 100. 400 99. Z' Ω) (. Z ' (Ω ). 300. 98. 97. 200. 96. 95 2 x1 0. 5. 4 x1 0. 5. 5. 5. 6 x 1 08 x 1 0 1 0. 6. F r e q ü ê n c ia (H z ). 100 10. 0. 10. 1. 10. 2. 10. 3. Freqüência (Hz). 10. 4. 10. 5. 10. 6.

(96) S ó d io S ó d io. 1 0 0 9 0 8 0. le ite 10m g 20m g 30m g 40m g 50m g 60m g 70m g 80m g 90m g 100m g. 7 0. Z ' (Ω ). 6 0 5 0. 4 0. 3 0. Z' Ω ( ). 2 x1 0. 5. 4 x1 0. 5. 5. 5. 6 x1 08 x1 0 1 0. 6. F r e q ü ê n c i a (H z ). 100. 10. 0. 10. 1. 10. 2. 10. 3. 10. F r e q ü ê n c ia ( H z ). 4. 10. 5. 10. 6.

(97) 100. 90 Água C á lc io S ó d io F e rro C o le s te ro l. 80. Z ' (Ω ). 70. 60. 50. 40. 30 0. 20. 40. 60. In c r e m e n to ( % ). 80. 100.

(98) Loadings 0,3 C 10_10 C 9_10 C 8_10 C 7_10. 0,2. C 6_10. 0,1. C 5_10 C 4_10. PC2. 0,0 C 3_10. -0,1. C 2_10. -0,2 C 1_10. -0,3 -0,4 0,93. C0. 0,94. 0,95. 0,96. 0,97. 0,98. 0,99. 1,00. 1,01. PC1. GR Á FIC O D OS E SC OR E S 1,5 1,0 0,5. Z´´SO D IO ZÁGUA ZĆZ´FER O LEST RO ZÉPIKUR O N. Z´Ć ALCIO Z´ÁGUA Z´´FER RO O Z´Ć O LEST Z´ÉPIKUR. 0,0. PC2. -0,5 -1,0 -1,5. ZĆ ALC IO. -2,0 Z´SO D IO. -2,5 -3,0 -1,2. -0,8. -0,4. 0,0. 0,4 PC1. 0,8. 1,2. 1,6.

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(100) 1 10. 1 00. 90. [Z ] ( Ω ). 80. 70. le it e as a m id o b ic so d io. 60. 50 10 4. 10. 5. 10 6. [ Z ] (Ω ). F r e qü ê n cia (H z ). le it e as a m id o N aH C O 3. 1 0 1 0. 0. 1 0. 1. 1 0. 2. 1 0. 3. 1 0. F r e q ü ê n c ia ( H z ). 4. 1 0. 5. 1 0. 6.

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(108) Mapa dos pesos 1.0 ALFACPE. 0.6. Z´ 1MHZ. F ato r 2. 0.2. -0.2 ´ Z´RELAX Z´Z´ RCPE RELAXA 0. -0.6. FRELAXA CCPE. -1.0 -0.8. -0.4. 0.0. 0.4 Fator 1. 0.8. 1.2.

(109) Mapa dos escores. 1.0. 1.5. bc. 0.9 0.8. bbcd cd d bd acd abcd abd ad. 1. 0.5. PC2. bc. 1.0. bd. 0.7. -0.1 PC1. ac ci. -1.0. 0.60. abc. -1.5. PC2. PC2. cd. acd abcd abd ad. 0.5 -0.2. a. -0.5. bcd d. 2.1. 0.6. 2. 0.0. 2.2 b. -2.0. abd abcd. 3. acd. ad. 0.50 -0.170. ab. -2.5. 0.55. -0.165. -0.160. PC1. -3.0 -2. -1. 0. 1 PC1. 2. 3.

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(111) Mapa dos escores. 1. ace abe ae abce cd dbc bcd bd de cde bde acd abcd abd ad b ce e bcde ade acde be abde bce abcde. 3. 2. 0. 1 a. -1. ci. PC2. ac. abc. -2. -3 ab. -4 -2. -1. 0. 1. 2 PC1. 3. 4. 5.

(112) 1.0. PC2. 0.5 0.4. ad. abdabcdacd ace aeabe. 0.3 -0.15. bcd. PC1. PC2. d. abce cd. bc. bd de. 0.5. cde bde acd abcd abd ad e. b ce. bcde ade acde abde abcde. 0.0 -0.3. be bce. -0.2. -0.1 PC1. 0.0.

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