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題 名 | 添加奈米/微米金微粒之碘化鉀/碘酸鉀劑量計於γ光子劑量量測之應用=Application of γ-photon Dose Measurement with KI/KIO₃ Dosimeter Added with Nano/Micro Gold Particles |
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作 者 | 林群智; 吳坤隆; 劉威忠; 黃玉芬; | 書刊名 | 臺灣應用輻射與同位素雜誌 |
卷 期 | 5:3 2009.09[民98.09] |
頁 次 | 頁707-714 |
分類號 | 418.94 |
關鍵詞 | 劑量; 劑量計; 輻射分解; 碘化鉀; 奈米金; Dose; Dosimeter; Radiolysis; Potassium iodide; Nano gold; |
語 文 | 中文(Chinese) |
中文摘要 | 本研究旨在探討KI/KIO3劑量計在不同KI濃度及添加微米金和奈米金微粒後,其各吸收峰對γ光子吸收劑量之回應,並觀察其線性表現以及G值的變化,並進而探討添加微米金及奈米金微粒後對於KI/KIO3劑量計性能的影響。研究結果顯示,KI/KIO3溶液在352、400、426及450 nm 處可找到吸收峰。未添加金微粒時,I3(上标 -)在352 nm處之吸收度均隨吸收劑量(0-20 Gy)增加而成線性增加,且低劑量量測以配製1.0 M KI並使用352 nm處之吸收峰爲佳,且在低劑量(≤20 Gy)下,劑量愈低G值愈高。在較高劑量(>20 Gy)時,各吸收峰之吸收度與吸收劑量之問存在對數線性關係,且在波長較長處之吸收峰可用於量測更高之劑量,線性範圍廣闊,其中,在352 nm處之吸收峰適於量測100 Gy以F之γ光子劑量,而450 nm處之吸收峰適於量測100-1000 Gy之γ光子劑量。添加微米金微粒後,吸收度與吸收劑量不再呈現對數線性,較低劑量(500 Gy 以下),以352 nm處吸收度之線性較佳,且其線性範圈可延伸至500 Gy。在400 nm處之吸收值存在50-200 Gy及200-500 Gy兩個線性範間。而在較長之吸收波長(426及450 nm)處,當劑量低於500 Gy時線性較差,在高劑量時則線性隨著波長增加且範圓隨之增廣,顯示添加微米金微粒之KI/KIO3化學劑量計適合以較長之波長(426及450 nm)量測較高劑量,在352及的450 nm處之吸收之G值各在500 Gy及200 Gy時最高,而後緩慢降低。添加奈米金微粒後,KI(1.0 M)/KIO3化學劑量計在352 nm處對於γ光子劑量之回應與未添加奈米金微粒前相近(>2.0),但吸收度變化很小,不適於量測。在較長之吸收波長(400、426、450 nm)處,其靈敏度降低但線性範圍隨之增加,顯示添加奈米金微粒之KI/KIO3化學劑量計適合以較長之波長(450 nm)量測劑量;其中,400 nm處之吸收波長適合量測200 Gy以下之吸收劑量,426及450 nm處之吸收波長均適合量測500 Gy以下之吸收劑量,且後者之線性範圍則可向更高劑量延伸。此外,在352及450 nm處之G值均隨劑量增加而提高,各在500 Gy及1000 Gy時達最大值。 |
英文摘要 | This research aimed to investigate the response of absorbance of KI/KIO3 dosimeter irradiated by γ-rays before and after adding micro/nano gold particles. The variation of linearity and G values were also investigated to probe the effect of micro/nano gold particles on characteristics of KI/KIO3 dosimeter. The results indicated that the KI/KIO3 solution has absorption peaks at 352, 400, 426 and 450 nm. Before added with gold particles, the absorption of I3(superscript -) at 352 nm increased linearly with absorbed dose (0-20 Gy). Absorption at 352 nm was relatively better in measuring lower dose (≤20 Gy) when 1.0 M KI was prepared for the dosimeter. The G values decreased with dose (≤20 Gy) at 352 nm peak. At measuring higher dose (>20 Gy), the absorbance increased with dose in a logarithm relationship. Peaks at longer wavelengths were suitable for higher dose measurement, and the linear range was wide. Among them, the peak at 352 nm could be used to estimate y-ray dose lower than 100 Gy, while that at 450 nm was adequate for 100-1000 Gy. After micro gold particles were added the relationship between absorption and dose was no longer logarithmic. At dose lower than 500 Gy, the linearity was better at 352 nm,and the range could be extended to 500 Gy. Two linear ranges existed in 50-200 Gy and 200-500 Gy. At longer absorption wavelengths (426 and 450 nm), the linearity promoted with dose and the linear range extended with wavelength, indicating that longer wavelength (450 nm) was fitting for higher dose survey with KI/KIO3 dosimeter added with micro gold particles. Among the wavelengths, 400 nm was suitable for dose less than 200 Gy, while 426 and 450 nm were fitting for that lower than 500 Gy; the linear range for the later could be extended to higher doses. The G values at 352 and 450 nm were maximum at 500 and 1000 Gy, respectively, and then decreased slightly. The response of KI(l.0 M)/KIO3 dosimeter added with nano gold particles to γ photons was similar to original KI(l.0 M)/KIO3 solution at 352 nm (>2.0); however, the absorbance variation was too slight to be used for measurement. At longer absorption wavelengths (400, 426 and 450 nm), the sensitivity lowered while the linear range increased, indicating that the KI(l.0 M)/KIO3 dosimeter added with nano gold particles was suitable for dose measurement with longer wavelength (i. e, 450 nm). Among the wavelengths, 400 nm was suitable for measuring dose less than 200 Gy, while 426 and 450 nm were fitting for that lower than 500 Gy; the linear range of the latter could be extended to higher doses. Moreover, the G values at 352 and |
本系統中英文摘要資訊取自各篇刊載內容。