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    • 1. 发明申请
    • Process parameter assessment method for the solid target for gallium (Ga)-68/germanium (Ge)-68 generator
    • 镓(Ga)-68 /锗(Ge)-68发生器的固体靶的工艺参数评估方法
    • US20110077894A1
    • 2011-03-31
    • US12569908
    • 2009-09-30
    • Ming-Hsin LiTing Shien DuhWuu-Jyn Lin
    • Ming-Hsin LiTing Shien DuhWuu-Jyn Lin
    • G06F15/00
    • G21G1/10G21G2001/0094
    • A process parameter assessment method for the solid target for gallium (Ga)-68/germanium (Ge)-68 generator mainly consists of the procedures: first calculate the thickness d for the electroplated gallium (Ga)-69 on the solid target; and then through a graph of decay curves comprising 69Ga(p, 2n) 68Ge target thickness and incident energy with 5 different incident energy doses (30, 26, 25, 24, 23 MeV), based on electroplating thickness d, derive the corresponding irradiation energy dose Yi for each group after decay; and through the graph comprising 69Ga(p, 2n) 68Ge incident energy and reaction cross-sectional area (containing corrected function graph of incident energy for germanium-68, gallium-68, or zinc-65 and reaction cross-sectional area), based on the defined range by irradiation energy dose Xi and the corresponding irradiation energy dose Yi, derive the nuclear reaction cross-sectional area for each group for germanium (Ge)-68, gallium (Ga)-68, zinc (Zn)-65 and figure out the mean reaction area (MRA) from the reaction cross-sectional area of each group; and select the maximum germanium (Ge)-68 MRA value and the minimum gallium (Ga)-68 and zinc (Zn)-65 MRA values; and generate the required default irradiation energy for the MRA of each group as the optimal reaction energy.
    • 用于镓(Ga)-68 /锗(Ge)-68发生器的固体靶的工艺参数评估方法主要包括以下步骤:首先计算固体靶上电镀镓(Ga)-69的厚度d; 然后通过基于电镀厚度d的包括69Ga(p,2n)68Ge目标厚度和具有5种不同入射能量剂量(30,26,25,24,23MeV)的入射能)的衰减曲线图导出相应的辐射 能量Yi每组后衰变; 并且通过包括69Ga(p,2n)68Ge入射能和反应截面积(包含用于锗-68,镓-68或锌-65的入射能量的校正函数图和反应横截面积)的图,基于 通过照射能量剂量Xi和相应的照射能量剂量Yi定义的范围,得出锗(Ge)-68,镓(Ga)-68,锌(Zn)-65和 从每组的反应横截面积中求出平均反应面积(MRA); 并选择最大锗(Ge)-68 MRA值和最小镓(Ga)-68和锌(Zn)-65 MRA值; 并为每组的MRA产生所需的默认照射能量作为最佳反应能量。
    • 3. 发明授权
    • Method used to yield irradiation product with minimal impurity for solid target for gallium (Ga)-68/germanium (Ge)-68 generator
    • 用于为镓(Ga)-68 /锗(Ge)-68发生器的固体靶产生最小杂质的辐射产物的方法
    • US08239159B2
    • 2012-08-07
    • US12569908
    • 2009-09-30
    • Ming-Hsin LiTing Shien DuhWuu-Jyn Lin
    • Ming-Hsin LiTing Shien DuhWuu-Jyn Lin
    • G06F15/00
    • G21G1/10G21G2001/0094
    • A method used to yield irradiation product with minimal impurity for the solid target for gallium (Ga)-68/germanium (Ge)-68 generator mainly consists of the procedures: first calculate the thickness d for the electroplated gallium (Ga)-69 on the solid target; and then through a graph of decay curves including 69Ga(p, 2n) 68Ge target thickness and incident energy with 5 different incident energy doses, derive the corresponding irradiation energy dose Yi for each group after decay; and through the graph including 69Ga(p,2n)68Ge incident energy and reaction cross-sectional area, derive the nuclear reaction cross-sectional area for each group for germanium(Ge)-68, gallium (Ga)-68, zinc (Zn)-65 and figure out the mean reaction area (MRA) from the reaction cross-sectional area of each group; and select the maximum germanium(Ge)-68 MRA value and the minimum gallium (Ga)-68 and zinc (Zn)-65 MRA values; and generate the required default irradiation energy for the MRA of each group.
    • 用于产生镓(Ga)-68 /锗(Ge)-68发生器的固体靶的杂质最小的辐射产物的方法主要包括以下步骤:首先计算电镀镓(Ga)-69的厚度d 坚实的目标; 然后通过包括69 Ga(p,2n)68Ge目标厚度和入射能量与5个不同入射能量剂量的衰减曲线图,得出每个组在衰变后的相应的照射能量剂量Yi; 通过包括69Ga(p,2n)68Ge入射能和反应截面积的图,得出锗(Ge)-68,镓(Ga)-68,锌(Zn)的每个组的核反应截面积 )-65,计算每组反应截面积的平均反应面积(MRA); 并选择最大锗(Ge)-68 MRA值和最小镓(Ga)-68和锌(Zn)-65 MRA值; 并为每组的MRA产生所需的默认照射能量。