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本論文電子全文於2011-02-18起於校外公開使用
本論文紙本於2011-02-18起公開使用

系統識別號	U0002-0802200915340200
DOI	10.6846/TKU.2009.00177
論文名稱(中文)	(Bi2-xPbx)(Sr2-yRy)CuOZ (R = La, Pr)之結構、氧計量與超導性研究
論文名稱(英文)	Structure, Oxygen Stoichiometry and Superconductivity of (Bi2-xPbx)(Sr2-yRy)CuOZ (R = La, Pr)
第三語言論文名稱
校院名稱	淡江大學
系所名稱(中文)	化學學系碩士班
系所名稱(英文)	Department of Chemistry
外國學位學校名稱
外國學位學院名稱
外國學位研究所名稱
學年度	97
學期	1
出版年	98
研究生(中文)	洪勝男
研究生(英文)	Shan-Nan Hong
學號	695160332
學位類別	碩士
語言別	繁體中文
第二語言別
口試日期	2009-01-12
論文頁數	116頁
口試委員	指導教授 - 高惠春(kaohci@mail.tku.edu.tw) 委員 - 陳錦明(jmchen@nsrrc.org.tw) 委員 - 林大欽(dcling@mail.tku.edu.tw)
關鍵字(中)	正交晶系超導性吸收光譜電洞填充效應
關鍵字(英)	hole concentration doping superconductivity XANES
第三語言關鍵字
學科別分類
中文摘要	本實驗是利用固態法製備了三系列(Bi2-xPbx)(Sr2-yRy)CuOZ (R = La, Pr) 取代量0 ≤ x ≤ 0.1 的單相樣品與一系列(Bi2.2-xPbx)(Sr2-y Lay)CuOZ 取代量0 ≤ x ≤ 0.2 的單相樣品，透過X-光繞射光粉末繞射圖譜與SEM 鑑定為單相，樣品結構為層狀堆疊。Pb2+會減少過量的氧原子進入Bi2O2 2+雙層，受到Pb 摻雜的影響，造成madulation peak 減少。四系列樣品透過Rietveld 精算的結果，所有系列樣品皆為正交晶相。Pr3+、La3+離子半徑比Sr2+離子半徑小，會使c 軸晶胞參數隨取代量增加而縮短；在Bi2O2 平面上，有過量的氧原子掺入，造成結構上的破壞，同時也撐大了a、b 方向的軸長。導電度的量測結果，La18 系列在低溫下(0-30 K)具有半導性，取代量y = 0，在低溫下(0-50 K)為半導體；La16、Pr16 與Pr18 系列均具有超導性；在所有樣品中，Pr02 系列取代量y = 0.05 時有著最大超導轉移溫度 Tc(onset) = 15.5 K。Bi-L edge、Pb-L edge 及Cu-L edge XANES 吸收光譜可知道，樣品中所含的元素Bi、Pb 與Cu 皆有混價的情形發生。 Bi 的平均價數小於三價，Pb 的平均價數等於三價；樣品所含的電洞濃度，則隨著取代量的增加而呈現減少的趨勢，為電洞填充效應。碘滴定法得知，四系列的氧計量隨著取代量的增加而增加，電子轉移量隨著取代量增加而下降，由此推論，四系列的電洞濃度隨取代量增加而呈現下降的趨勢。
英文摘要	Three series of single phase (Bi2-xPbx)(Sr2-yRy)CuOZ (R = La, Pr) oxides with 0 ≤ x ≤ 0.1 and a series of single phase (Bi2.2-xPbx)(Sr2-y La y)CuOZ oxides with 0 ≤ x ≤ 0.2 were prepared by a solid state reaction method. They all have the orthorhombic symmetry and laminar structure observed under SEM. Pb substitution for Bi is quite effective to the suppression of the modulation structure. For these calcultions we use Rietveld method. The a and b cell dimensions increased with R (R = rare-rarth) doping while the c cell dimensions deccreased with R doping. The decrease in c with increasing R content is explained primarily by the substitution of smaller R ion for the larger Sr. The smaller increase in a and b with increasing R content is probably caused by the added oxygen which is accommodated in the Bi2O2 slab of the structure. Most of sample are superconductors at low temperature. The series of (Bi2.2-xPbx)(Sr2-y La y)CuOZ oxides showed semiconducting properties at low temperature.The maximum Tc (15.5 K) is found in the R = Pr , x = 0.2 and y = 0.050 sample. The valence states of the Bi and Pb, and Cu, and the hole concentration of the all Bi2201 superconductors were studied by theXANES spectroscopy in the NSRRC of Taiwan. The L-absorption edge of the Bi atom shows that the Bi ions in all the samples have mixed valence states. The oxidation states of Bi which one state smaller then 3.The L-absorption edge of the Pb atom shows that the Pb ions in all the samples have mixed valence states. The oxidation states of Pb which one state to be equal to 3. The L-absorption edge of the Cu and The pre-edge of the K- absorption edge of the O atom is related to the hole concentration of these superconductors. Oxygen content (z) increasd with increasing y. Number of electron transfer decreased with increasing y. Hole concentration decreased with increasing y, showing a hole filling effect.
第三語言摘要
論文目次	目錄壹、緒論………………………………………………… 1 一、超導體的發展史…………………………………… 1 二、 Bi-Sr-Ca-Cu-O系統超導氧化物的結構簡介……... 4 三、氧含量與電洞濃度………………………………… 10 四、鉍系列超導體摻雜結果簡介……………………… 10 五、實驗目的…………………………………………… 15 貳、實驗………………………………………………… 16 一、試藥………………………………………………… 16 二、樣品的製備………………………………………… 17 三、物性與化性的測量………………………………… 18 1. X-光粉末繞射圖譜鑑定…………………………… 19 2. GSAS精算法………………………………………. 20 3. 導電度的測量……………………………………… 22 4. 氧含量滴定分析………………………………….... 25 5. 掃描式電子顯微術…………………………. 28 6. X-光吸收近邊緣結構光譜…………………. 29 參、結果與討論………………………………………… 33 一、樣品的製備與單相鑑定…………………………… 33 二、結構分析…………………………………………… 51 三、導電度的量測……………………………………… 70 四、 Bi-L edge及 Pb-L edge吸收光譜………………… 81 五、 Cu-L edge及O-K edge吸收光譜…………………. 88 六、氧計量 (z)與 Electron transfer……………………. 99 肆、結論………………………………………………… 108 伍、參考文獻…………………………………………… 110 圖目錄圖1-1 (a) Perovskite的單位晶胞結構圖 (b) Perovskite的單位晶胞結構的另一種示意圖 7 圖1-2 Bi4Ti3O12 (A-type)的單位晶胞結構圖…………… 8 圖 1-3 (a)Bi2Sr2CuO6 (b) Bi2Sr2CaCu2O8 (c) Bi2Sr2Ca2Cu3O10單位晶胞結構圖…………… 9 圖2-1 布拉格繞射示意圖………………………………. 19 圖2-2 標準四極法的樣品架設………………………… 24 圖2-3 超導體電阻率對溫度關係圖中Tc的定義………. 24 圖2-4 XANES與EXAFS區分圖………………………. 29 圖2-5 穿透式X-光吸收光譜……………………………. 30 圖2-6 X-光通過物質之強度衰減示意圖……………… 31 圖2-7 電子逸出式X-光吸收光譜……………………… 31 圖2-8 光子吸收過程……………………………………. 32 圖3-1 Bi-2201 的 X-光粉末繞射圖譜 (5°-52° λ =1.5418Å)……………………………… 36 圖3-2 (Bi1.6Pb0.4)(Sr2-yLay)CuOz 單相樣品XRD 圖 (0°-20°λ = 0.49594Å)…………………………….. 36 圖3-3 (Bi1.6Pb0.4)(Sr2-yLay)CuOz 單相樣品XRD 圖 (0°-12°λ = 0.49594Å)…………………………….. 37 圖3-4 (Bi1.6Pb0.4)(Sr2-yLay)CuOz 單相樣品XRD 圖 (7°-12°λ = 0.49594Å)…………………………….. 37 圖3-5 (Bi1.8Pb0.4)(Sr2-yLay)CuOz 單相樣品XRD 圖 (0°-20°λ = 0.49594Å)……………………………. 38 圖3-6 (Bi1.8Pb0.4)(Sr2-yLay)CuOz 單相樣品XRD 圖 (0°-15°λ = 0.49594Å)…………………………….. 38 圖3-7 (Bi1.8Pb0.4)(Sr2-yLay)CuOz 單相樣品XRD 圖 (9.5°-15°λ = 0.49594Å)………………………….. 39 圖3-8 (Bi1.6Pb0.4)(Sr2-yPry)CuOz 單相樣品XRD 圖 (0°-20°λ = 0.49594Å)……………………………. 39 圖3-9 (Bi1.6Pb0.4)(Sr2-yPry)CuOz 單相樣品XRD 圖 0°-12°λ = 0.49594Å)……………………………... 40 圖3-10 (Bi1.6Pb0.4)(Sr2-yPry)CuOz 單相樣品XRD 圖 (6°-10°λ = 0.49594Å)…………………………….. 40 圖3-11 (Bi1.8Pb0.2)(Sr2-yPry)CuOz 單相樣品XRD 圖 (0°-20°λ = 0.49594Å)…………………………….. 41 圖3-12 (Bi1.8Pb0.2)(Sr2-yPry)CuOz 單相樣品XRD 圖 (0°-15°λ = 0.49594Å)……………………………. 41 圖3-13 (Bi1.8Pb0.2)(Sr2-yPry)CuOz 單相樣品XRD 圖 (8°-12°λ = 0.49594Å)…………………………….. 42 圖3-14 (Bi1.6Pb0.4)Sr2CuOz 樣品影像(10 kX)…………….. 43 圖3-15 (Bi1.6Pb0.4)(Sr1.975La0.025)CuOz 樣品影像(10 kX)… 43 圖3-16 (Bi1.6Pb0.4)(Sr1.95La0.05)CuOz 樣品影像(10 kX)…... 43 圖3-17 (Bi1.6Pb0.4)(Sr1.94La0.06)CuOz 樣品影像(10 kX)…... 43 圖3-18 (Bi1.6Pb0.4)( Sr1.925La0.075)CuOz樣品影像(10 kX)… 43 圖3-19 (Bi1.6Pb0.4)(Sr1.9La0.1)CuOz 樣品影像(10 kX)…….. 43 圖3-20 (Bi1.8Pb0.4)Sr2CuOz 樣品影像(10 kX)……………. 44 圖3-21 (Bi1.8Pb0.4)(Sr1.975La0.025)CuOz樣品影像(10 kX)…. 44 圖3-22 (Bi1.8Pb0.4)(Sr1.95La0.05)CuOz 樣品影像(10 kX)…... 44 圖3-23 (Bi1.8Pb0.4)(Sr1.925La0.075)CuOz樣品影像(10 kX)…. 44 圖3-24 (Bi1.8Pb0.4)(Sr1.9La0.1)CuOz 樣品影像(10 kX)…….. 44 圖3-25 (Bi1.8Pb0.4)(Sr1.875La0.125)CuOz樣品影像(10 kX)…. 44 圖3-26 (Bi1.8Pb0.4)(Sr1.85La015)CuOz 樣品影像(10 kX)…… 45 圖3-27 (Bi1.8Pb0.4)(Sr1.825La0.175)CuOz 樣品影像(10 kX)… 45 圖3-28 (Bi1.8Pb0.4)(Sr1.8La0.2)CuOz 樣品影像(10 kX)……. 45 圖3-29 (Bi1.6Pb0.4)(Sr1.99Pr0.01.)CuOz 樣品影像(10 kX)…... 45 圖3-30 (Bi1.6Pb0.4)(Sr1.975Pr0.025.)CuOz 樣品影像(10 kX)… 45 圖3-31 (Bi1.6Pb0.4)(Sr1.96Pr0.04.)CuOz 樣品影像(10 kX)…. 45 圖3-32 (Bi1.6Pb0.4)(Sr1.95Pr0.05.)CuOz 樣品影像(10 kX)…... 46 圖3-33 (Bi1.6Pb0.4)(Sr1.925Pr0.075.)CuOz樣品影像(10 kX)…. 46 圖3-34 (Bi1.6Pb0.4)(Sr1.9Pr0.1.)CuOz 樣品影像(10 kX)…….. 46 圖3-35 (Bi1.8Pb0.2)Sr2CuOz 樣品影像(10 kX)……………. 46 圖3-36 (Bi1.8Pb0.2)(Sr1.975Pr0.025.)CuOz樣品影像(10 kX)…. 46 圖3-37 (Bi1.8Pb0.2)(Sr1.96Pr0.04.)CuOz 樣品影像(10 kX)…... 46 圖3-38 (Bi1.8Pb0.2)(Sr1.95Pr0.05.)CuOz 樣品影像(10 kX)…... 47 圖3-39 (Bi1.8Pb0.2)(Sr1.94Pr0.06.)CuOz 樣品影像(10 kX)…... 47 圖3-40 (Bi1.8Pb0.2)(Sr1.925Pr0.075.)CuOz樣品影像(10 kX)…. 47 圖3-41 (Bi1.8Pb0.2)(Sr1.9Pr0.1.)CuOz 樣品影像(10 kX)…….. 47 圖3-42 Pr16 系列Bi、Pb 與Sr 元素相對誤差(%)對取代量作圖……………………………………………. 49 圖3-43 Pr02 系列Bi、Pb 與Sr 元素相對誤差(%)對取代量作圖…………………………………………… 49 圖3-44 (Bi1.6Pb0.4)(Sr2-yLay)CuOz 系列樣品晶胞常數與取代量關係圖………………………………………. 67 圖3-45 (Bi1.8Pb0.4)(Sr2-yLay)CuOz 系列樣品晶胞常數與取 67 代量關係圖………………………………………. 圖3-46 (Bi1.6Pb0.4)(Sr2-yPry)CuOz 系列樣品晶胞常數與取代量關係圖………………………………………. 68 圖3-47 (Bi1.8Pb0.2)(Sr2-yPry)CuOz 系列樣品晶胞常數與取代量關係圖………………………………………. 68 圖3-48 四系列樣品體積與取代量關係圖………………. 69 圖3-49 Bi2Sr2CuOy 電阻率對溫度的關係圖…………….. 70 圖3-50 (Bi1.6Pb0.4)(Sr2-yLay)CuOz 電阻率對溫度做圖 (0-300 K)………………………………………… 72 圖3-51 (Bi1.6Pb0.4)(Sr2-yLay)CuOz 電阻率對溫度做圖 (0-25 K)…………………………………………... 73 圖3-52 (Bi1.8Pb0.4)(Sr2-yLay)CuOz 電阻率對溫度做圖 (0-300 K)…………………………………………. 73 圖3-53 (Bi1.8Pb0.4)(Sr2-yLay)CuOz 電阻率對溫度做圖 (0-25 K)………………………………………….. 74 圖3-54 (Bi1.6Pb0.4)(Sr2-yPry)CuOz 電阻率對溫度做圖 (0-300 K)………………………………………… 74 圖3-55 (Bi1.6Pb0.4)(Sr2-yPry)CuOz 電阻率對溫度做圖 (0-25 K)………………………………………….. 75 圖3-56 (Bi1.8Pb0.2)(Sr2-yPry)CuOz 電阻率對溫度做圖 (0-300 K)…………………………………………. 75 圖3-57 (Bi1.8Pb0.2)(Sr2-yPry)CuOz 電阻率對溫度做圖 (0-25 K)…………………………………………... 76 圖3-58 (Bi1.6Pb0.4)(Sr2-yLay)CuOz系列樣品Tc與取代量關係圖………………………………………………. 76 圖3-59 (Bi1.8Pb0.4)(Sr2-yLay)CuOz系列樣品Tc與取代量關係圖………………………………………………. 77 圖3-60 (Bi1.6Pb0.4)(Sr2-yPry)CuOz 系列樣品Tc 與取代量關係圖………………………………………………. 77 圖3-61 (Bi1.8Pb0.2)(Sr2-yPry)CuOz 系列樣品Tc 與取代量關係圖……………………………………………… 78 圖3-62 四系列樣品Tc(onset)與取代量關係圖……………. 78 圖3-63 Bi-L edge 吸收光譜圖…………………………... 83 圖3-64 Bi-L edge 吸收光譜一次微分圖………………... 83 圖3-65 Bi-L edge 反曲點能量對取代量關係圖………… 84 圖3-66 Pb-L edge 吸收光譜圖…………………………... 85 圖3-67 Pb-L edge 吸收光譜一次微分圖………………... 85 圖3-68 Pb-L edge 反曲點能量對取代量關係圖………… 86 圖3-69 Pb-L edge 最大吸收值能量對取代量關係圖…… 87 圖3-70 (Bi1.6Pb0.4)(Sr2-yLay)CuOz 系列樣品Cu-L edge 吸收光譜圖…………………………………………. 91 圖3-71 (Bi1.8Pb0.4)(Sr2-yLay)CuOz 系列樣品Cu-L edge 吸收光譜圖…………………………………………. 91 圖3-72 (Bi1.6Pb0.4)(Sr2-yPry)CuOz 系列樣品Cu-L edge 吸收光譜圖…………………………………………. 92 圖3-73 (Bi1.6Pb0.4)(Sr2-yPry)CuOz 系列樣品Cu-L edge 吸收光譜圖………………………………………… 92 圖3-74 (Bi1.6Pb0.4)(Sr2-yLay)CuOz 系列樣品O-K edge 吸收光譜圖…………………………………………. 93 圖3-75 (Bi1.8Pb0.4)(Sr2-yLay)CuOz 系列樣品O-K edge 吸收光譜圖…………………………………………. 93 圖3-76 (Bi1.6Pb0.4)(Sr2-yPry)CuOz z 系列樣品O-K edge 吸收光譜圖………………………………………… 94 圖3-77 (Bi1.8Pb0.2)(Sr2-yPry)CuOz 系列樣品O-K edge 吸收光譜圖…………………………………………. 94 圖3-78 (Bi1.6Pb0.4)(Sr2-yLay)CuOz 系列樣品I 值對取代量關係圖……………………………………………. 95 圖3-79 (Bi1.8Pb0.4)(Sr2-yLay)CuOz 系列樣品I 值對取代量關係圖……………………………………………. 95 圖3-80 (Bi1.6Pb0.4)(Sr2-yPry)CuOz 系列樣品I 值對取代量關係圖……………………………………………. 96 圖3-81 (Bi1.8Pb0.2)(Sr2-yPry)CuO 系列樣品I 值對取代量關係圖……………………………………………. 96 圖3-82 (Bi1.6Pb0.4)(Sr2-yLay)CuOz 系列樣品O-K edge 面積對取代量關係圖………………………………. 97 圖3-83 (Bi1.8Pb0.4)(Sr2-yLay)CuOz 系列樣品O-K edge 面積對取代量關係圖……………………………… 97 圖3-84 (Bi1.6Pb0.4)(Sr2-yLay)CuOz 系列樣品O-K edge 面積對I 值作圖……………………………………... 98 圖3-85 (Bi1.8Pb0.4)(Sr2-yLay)CuOz 系列樣品O-K edge 面積對I 值作圖……………………………………... 98 圖3-86 四系列樣品氧計量與取代量關係圖……………. 102 圖3-87 四系列樣品電子轉移量與取代量關係圖……… 103 圖3-88 (Bi1.6Pb0.4)(Sr2-yLay)CuOz 系列樣品Tc(onset)對電子轉移量作圖………………………………………. 103 圖3-89 (Bi1.8Pb0.4)(Sr2-yLay)CuOz 系列樣品Tc(onset)對電子轉移量作圖……………………………………… 104 圖3-90 (Bi1.6Pb0.4)(Sr2-yPry)CuOz 系列樣品Tc(onset)對電子轉移量作圖………………………………………. 104 圖3-91 (Bi1.8Pb0.2)(Sr2-yPry)CuOz 系列樣品Tc(onset)對電子轉移量作圖……………………………………… 105 圖3-92 (Bi1.6Pb0.4)(Sr2-yLay)CuOz 系列樣品Tc(onset)對氧含量作圖……………………………………………. 105 圖3-93 (Bi1.8Pb0.4)(Sr2-yLay)CuOz 系列樣品Tc(onset)對氧含量作圖……………………………………………. 106 圖3-94 (Bi1.6Pb0.4)(Sr2-yPry)CuOz 系列樣品Tc(onset)對氧含量作圖…………………………………………… 106 圖3-95 (Bi1.8Pb0.2)(Sr2-yPry)CuOz 系列樣品Tc(onset)對氧含量作圖…………………………………………… 107 表目錄表1-1 2201、2212、2223 相的Tc 及Ca 和Cu-O 的層數以及晶胞參數的比較……………………………… 9 表2-1 固態法製作所用之藥品…………………………… 16 表3-1 四系列組成、代號與取代量範圍………………… 33 表3-2 雜相之XRD 繞射峰角度一覽表………………… 35 表3-3 樣品中元素重量百分比(wt%)…………………….. 48 表3-4 樣品的元素莫耳比(mol)比與相對誤差(%)……… 48 表3-5 Bi2Sr2CuO6+δ原子位置與晶胞參數……………….. 52 表3-6 Bi1.6Pb0.4Sr2CuOz樣品Rietveld 精算結果…………. 53 表3-7 Bi1.6Pb0.4(Sr1.975La0.025)CuOz樣品Rietveld 精算結果 53 表3-8 Bi1.6Pb0.4(Sr1.95La0.05)CuOz 樣品Rietveld 精算結果 54 表3-9 Bi1.6Pb0.4(Sr1.94La0.06)CuOz 樣品Rietveld 精算結果 54 表3-10 Bi1.6Pb0.4(Sr1.925La0.075)CuOz樣品Rietveld 精算結果 55 表3-11 Bi1.6Pb0.4(Sr1.9La0.1)CuOz 樣品Rietveld 精算結果… 55 表3-12 Bi1.8Pb0.4Sr2CuOz樣品Rietveld 精算結果…………. 56 表3-13 Bi1.8Pb0.4(Sr1.975La0.025)CuOz樣品Rietveld 精算結果 56 表3-14 Bi1.8Pb0.4(Sr1.95La0.05)CuOz 樣品Rietveld 精算結果 57 表3-15 Bi1.8Pb0.4(Sr1.925La0.075)CuOz樣品Rietveld 精算結果 57 表3-16 Bi1.8Pb0.4(Sr1.9La0.1)CuOz 樣品Rietveld 精算結果… 58 表3-17 Bi1.8Pb0.4(Sr1.875La0.125)CuOz樣品Rietveld 精算結果 58 表3-18 Bi1.8Pb0.4(Sr1.85La0.15)CuOz 樣品Rietveld 精算結果 59 表3-19 Bi1.8Pb0.4(Sr1.825La0.175)CuOz樣品Rietveld 精算結果 59 表3-20 Bi1.8Pb0.4(Sr1.8La0.2)CuOz樣品Rietveld 精算結果…. 60 表3-21 Bi1.6Pb0.4(Sr1.99Pr0.01)CuOz 樣品Rietveld 精算結果 60 表3-22 Bi1.6Pb0.4(Sr1.975Pr0.025)CuOz 樣品Rietveld 精算結果 61 表3-23 Bi1.6Pb0.4(Sr1.96Pr0.04)CuOz 樣品Rietveld 精算結果 61 表3-24 Bi1.6Pb0.4(Sr1.95Pr0.05)CuOz 樣品Rietveld 精算結果 62 表3-25 Bi1.6Pb0.4(Sr1.925Pr0.075)CuOz 樣品Rietveld 精算結果 62 表3-26 Bi1.6Pb0.4(Sr1.9Pr0.1)CuOz 樣品Rietveld 精算結果…. 63 表3-27 Bi1.8Pb0.2Sr2CuOz 樣品Rietveld 精算結果………… 63 表3-28 Bi1.8Pb0.2(Sr1.975Pr0.025)CuOz 樣品Rietveld 精算結果 64 表3-29 Bi1.8Pb0.2(Sr1.96Pr0.04)CuOz 樣品Rietveld 精算結果... 64 表3-30 Bi1.8Pb0.2(Sr1.95Pr0.05)CuOz 樣品Rietveld 精算結果... 65 表3-31 Bi1.8Pb0.2(Sr1.94Pr0.06)CuOz 樣品Rietveld 精算結果.. 65 表3-32 Bi1.8Pb0.2(Sr1.925Pr0.075)CuOz 樣品Rietveld 精算結果 66 表3-33 Bi1.8Pb0.2(Sr1.9Pr0.1)CuOz 樣品Rietveld 精算結果… 66 表3-34 (Bi1.6Pb0.4)(Sr2-yLay)CuOz 系列樣品的電性量測值 71 表3-35 (Bi1.6Pb0.4)(Sr2-yPry)CuOz 系列樣品的電性量測值 71 表3-36 (Bi1.8Pb0.2)(Sr2-yPry)CuOz 系列樣品的電性量測值 71 表3-37 (Bi1.8Pb0.4)(Sr2-yLay)CuOz 系列樣品的電性量測值 72 表3-38 四系列中最高Tc(onset) (K)值與相對取代量(y)……. 79 表3-39 Bi-L edge 反曲點能量與價數................................... 84 表3-40 Pb-L edge 反曲點能量與價數……………………... 86 表3-41 Pb-L edge 最高點能量與價數…………………….. 87 表3-42 (Bi1.6Pb0.4)(Sr2-yLay)CuOz 系列樣品的X-光吸收光譜測量值…………………………………………… 89 表3-43 (Bi1.8Pb0.4)(Sr2-yLay)CuOz 系列樣品的X-光吸收光譜測量值…………………………………………… 90 表3-44 (Bi1.6Pb0.4)(Sr2-yPry)CuOz 系列樣品的X-光吸收光譜測量值…………………………………………… 90 表3-45 (Bi1.8Pb0.2)(Sr2-yPry)CuOz 系列樣品的X-光吸收光譜測量值…………………………………………… 90 表3-46 (Bi1.6Pb0.4)(Sr2-yLay)CuOz 系列樣品的氧含量與電子轉移量…………………………………………… 101 表3-47 (Bi1.8Pb0.4)(Sr2-yLay)CuOz 系列樣品的氧含量與電子轉移量…………………………………………… 101 表3-48 (Bi1.6Pb0.4)(Sr2-yPry)CuO 系列樣品的氧含量與電子轉移量……………………………………………… 101 表3-49 (Bi1.6Pb0.4)(Sr2-yPry)CuO 系列樣品的氧含量與電子轉移量…………………………………………….. 102 表3-50 四系列最高Tc(onset)相對應的取代量、氧含量與電子轉移量…………………………………………… 102
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