pub

classification: volcanic:andesitic
physical-form: powder
status: unknown
description: Geological Survey of Japan silicate reference material; andesite; split 9, position 56
modified at 2020-05-15

Table 4. δ 65 Cu values of US Geological Survey (USGS) and Geological Survey of Japan (GSJ) silicate reference materials. Note that δ 65 Cu values are based on ERM-AE647. Makishima, Akio (2014)

1: BHVO-1 2: AGV-1 3: PCC-1 4: JB-1b 5: JB-2 6: JB-3 powder 7: JA-1 8: JA-2 9: JA-3 powder

(a) MC-ICPMS on MC-ICP-MS Finnigan, Neptune

Table 8. Grand average of Mo, Sb and W concentrations in basalt and andesite reference materials Akio Makishima & Eizo Nakamura (1999)

1: BCR-1 2: BHVO-1 3: JB-1b 4: JB-2 5: JB-3 powder 6: AGV-1 7: JA-1 8: JA-2 9: JA-3 powder

(a) Q-ICP-MS_procedures of Makishima and Nakamura (1997, 1999, 2006) on ICPMS Yokogawa PMS2000

Table 4-5. Analytical Results for Boron (μg g-1) in Standard Rocks and Allende Meteorites by ID-FI-ICPMS Akio Makishima et al. (1997)

1: PCC-1 2: BCR-1 3: AGV-1 4: JB-1b 5: JB-2 6: JB-3 powder 7: JA-1 8: JA-2 9: JA-3 powder 10: Allende-12

(a) B_procedures of Makishima et al. (1997) on ICPMS Yokogawa PMS2000

Table 4b. Analytical results for lithium in silicate reference materials by TIMS Takuya Moriguti et al. (2004)

1: PCC-1 2: JP-1 3: JB-2 4: JB-3 powder 5: JA-1 6: JA-2 7: JA-3 powder 8: JR-1 powder

(a) Li isotopes_procedures of Moriguti and Nakamura (1998) on TIMS Thermo-Fisher MAT261

Table 7.Chromium, Ni, Cu and Zn contents (μg g-1) in geological reference materials obtained by ID-HR-ICP-MS Makishima et al. (2002)

1: PCC-1 2: JP-1 3: BCR-1 4: BHVO-1 5: JB-1b 6: JB-2 7: JB-3 powder 8: AGV-1 9: JA-1 10: JA-2 11: JA-3 powder

(a) HR-ICPMS on HR-ICPMS Finningan, Element

Table 2. FeO (wt.%) of GSJ standard rocks Tetsuya Yokoyama & Eizo Nakamura (2002)

1: JB-1b 2: JB-2 3: JB-3 powder 4: JA-2 5: JA-3 6: JR-1 powder 7: JP-1

(a) Titration_procedures of Yokoyama and Nakamura (2002)

Table 4. Analytical Results for Sulfur (μg g-1) in Standard Reference Materials and in Smithsonian Reference Allende Powder by ID-FI-ICPMS Akio Makishima & Eizo Nakamura (2001)

1: PCC-1 2: JP-1 3: BCR-1 4: BHVO-1 5: JB-1b 6: JB-2 7: JB-3 powder 8: JA-1 9: JA-2 10: JA-3 powder 11: Allende (T)

(a) HR-ICPMS on HR-ICPMS Finningan, Element

Table 8.Analytical results for andesite reference materials in this study Makishima, Akio & Nakamura, E. (2006)

1: JA-1 2: JA-2 3: JA-3 powder 4: AGV-1

(a) ICPMS with isotope dilution and internal standardization on Q-ICPMS Agilent 7500cs

Table 5-6. Analytical results for Ge, As, Se and Te in silicate reference materials Akio Makishima & Eizo Nakamura (2009)

1: JB-2 2: JB-3 powder 3: JA-2 4: JA-3 powder 5: JP-1 6: BCR-2 7: BHVO-1 8: AGV-1

(a) ICPMS with isotope dilution and internal standardization on Q-ICPMS Agilent 7500cs

Table 6. Analytical results for andesite standard reference materials Lu et al. (2007)

1: JA-1 2: JA-2 3: JA-3 powder 4: AGV-1

(a) ICPMS with isotope dilution and internal standardization on Q-ICPMS Agilent 7500cs

Table 7. Concentrations of Zr, Nb, Hf and Ta in silicate reference materials Akio Makishima et al. (1999)

1: BCR-1 2: BHVO-1 3: JB-1b 4: JB-2 5: JB-3 powder 6: AGV-1 7: JA-1 8: JA-2 9: JA-3 powder

(a) Q-ICP-MS_procedures of Makishima and Nakamura (1997, 1999, 2006) on ICPMS Yokogawa PMS2000

Tables 6. Trace element concentrations in AGV-1, JA-1, JA-2 and JA-3 Akio Makishima & Eizo Nakamura (1997)

1: AGV-1 2: JA-1 3: JA-2 4: JA-3 powder

(a) Q-ICP-MS_procedures of Makishima and Nakamura (1997, 1999, 2006) on ICPMS Yokogawa PMS2000

Table 2 Sulfur concentrations for silicate reference materials and carbonaceous chondrites determined by ID-HR-MC-ICPMS and in references Makishima, Akio & Nakamura, Eizo (2012)

1: JB-2 2: JB-3 powder 3: JA-2 4: JA-3 powder 5: JP-1 6: BCR-2 7: BHVO-1 8: AGV-1 9: Murchison 10: Allende-12 11: Dar al Gani 521 12: Dar al Gani 194

(a) HR-ICPMS on ICPMS Thermo-Fisher Neptune

Table 2-3. 176Hf/177Hf in reference materials without and with spike and concentration if Hf (mg/g) in silicate reference materials Lu et al. (2007)

1: JB-1b 2: JB-2 3: JB-3 powder 4: BHVO-1 5: JA-1 6: JA-2 7: JA-3 powder 8: AGV-1 9: JP-1

(a) Hf isotopes_procedures of Lu et al. (2007) on MC-ICP-MS Finnigan, Neptune

Table 4a. Analytical results for lithium in silicate reference materials by ICP-MS Takuya Moriguti et al. (2004)

1: PCC-1 2: JP-1 3: JB-2 4: JB-3 powder 5: JA-1 6: JA-2 7: JA-3 powder 8: JR-1 powder

(a) Li isotopes_procedures of Moriguti and Nakamura (1998) on ICPMS Yokogawa PMS2000

Table 4. δ56Fe values of USGS and GSJ silicate reference materials and carbonaceous chondrites Akio Makishima (2013)

1: BHVO-1 2: AGV-1 3: PCC-1 4: JB-1b 5: JB-2 6: JB-3 powder 7: JA-1 8: JA-2 9: JA-3 powder 10: JP-1 11: Orgueil 12: Murchison 13: Allende (T)

(a) MC-ICPMS on ICPMS Thermo-Fisher Neptune

Table 3. Analytical results for Cd, In, Tl and Bi obtained in this study Akio Makishima et al. (2011)

1: JB-2 2: JB-3 powder 3: JA-1 4: JA-2 5: JA-3 powder 6: JP-1 7: BHVO-1 8: AGV-1 9: PCC-1 10: DTS-1

(a) Q-ICP-MS_procedures of Makishima and Nakamura (1997, 1999, 2006) on Q-ICPMS Agilent 7500cs

Table 4 TiO2 content in silicate reference materials obtained by ID-FI-HR-ICPMS Akio Makishima & Eizo Nakamura (2000)

1: BCR-1 2: BHVO-1 3: JB-1b 4: JB-2 5: JB-3 powder 6: AGV-1 7: JA-1 8: JA-2 9: JA-3 powder

(a) HR-ICPMS on HR-ICPMS Finningan, Element

Table 4 δ66Zn of silicate reference materials Akio Makishima & Eizo Nakamura (2013)

1: BHVO-1 2: AGV-1 3: PCC-1 4: JB-1b 5: JB-2 6: JB-3 powder 7: JA-1 8: JA-2 9: JA-3 powder 10: JP-1

(a) MC-ICPMS on ICPMS Thermo-Fisher Neptune

@article{20160921101920-406882,
 author={{JA-2}},
 title={Powder at \nolinkurl{/ISEI/main/XRF/}},
 journal={\href{http://dream.misasa.okayama-u.ac.jp/?q=20160921101920-406882}{DREAM}},
 volume={20},
 pages={20160921101920-406882},
 year={2016},
 url={http://dream.misasa.okayama-u.ac.jp/?q=20160921101920-406882},
}

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  <acquisition>
    <global_id>20191007144514-911634</global_id>
    <name>JA-2_B</name>
    <device>ICPMS Yokogawa PMS2000</device>
    <technique>B_procedures of  Makishima et al. (1997)</technique>
    <operator>Max</operator>
    <sample_global_id>20160921101920-406882</sample_global_id>
    <sample_name>JA-2</sample_name>
    <description></description>
    <chemistries>
      <analysis>
        <nickname>B</nickname>
        <value>31.3</value>
        <unit>ug/g</unit>
        <uncertainty/>
        <label/>
        <info/>
      </analysis>
    </chemistries>
  </acquisition>
  <acquisition>
    <global_id>20170302124505-267282</global_id>
    <name>ref-gl-ja2</name>
    <device>Q-ICPMS Agilent 7500cs</device>
    <technique>ICPMS with isotope dilution and internal standardization</technique>
    <operator></operator>
    <sample_global_id>20160921101920-406882</sample_global_id>
    <sample_name>JA-2</sample_name>
    <description></description>
    <chemistries>
      <analysis>
        <nickname>Sr</nickname>
        <value>237.0</value>
        <unit>ug/g</unit>
        <uncertainty/>
        <label/>
        <info/>
      </analysis>
      <analysis>
        <nickname>Y</nickname>
        <value>14.2</value>
        <unit>ug/g</unit>
        <uncertainty/>
        <label/>
        <info/>
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      <analysis>
        <nickname>Sn</nickname>
        <value>1.56</value>
        <unit>ug/g</unit>
        <uncertainty/>
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      </analysis>
      <analysis>
        <nickname>TiO2</nickname>
        <value>0.625</value>
        <unit>cg/g</unit>
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      <analysis>
        <nickname>Al2O3</nickname>
        <value>14.9</value>
        <unit>cg/g</unit>
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        <info/>
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      <analysis>
        <nickname>Fe2O3T</nickname>
        <value>5.67</value>
        <unit>cg/g</unit>
        <uncertainty/>
        <label/>
        <info/>
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      <analysis>
        <nickname>MnO</nickname>
        <value>0.103</value>
        <unit>cg/g</unit>
        <uncertainty/>
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        <info/>
      </analysis>
      <analysis>
        <nickname>MgO</nickname>
        <value>6.8</value>
        <unit>cg/g</unit>
        <uncertainty/>
        <label/>
        <info/>
      </analysis>
      <analysis>
        <nickname>CaO</nickname>
        <value>5.92</value>
        <unit>cg/g</unit>
        <uncertainty/>
        <label/>
        <info/>
      </analysis>
      <analysis>
        <nickname>Na2O</nickname>
        <value>3.0</value>
        <unit>cg/g</unit>
        <uncertainty/>
        <label/>
        <info/>
      </analysis>
      <analysis>
        <nickname>K2O</nickname>
        <value>1.81</value>
        <unit>cg/g</unit>
        <uncertainty/>
        <label/>
        <info/>
      </analysis>
      <analysis>
        <nickname>P2O5</nickname>
        <value>0.141</value>
        <unit>cg/g</unit>
        <uncertainty/>
        <label/>
        <info/>
      </analysis>
      <analysis>
        <nickname>Li</nickname>
        <value>27.6</value>
        <unit>ug/g</unit>
        <uncertainty/>
        <label/>
        <info/>
      </analysis>
      <analysis>
        <nickname>Be</nickname>
        <value>1.93</value>
        <unit>ug/g</unit>
        <uncertainty/>
        <label/>
        <info/>
      </analysis>
      <analysis>
        <nickname>B</nickname>
        <value>22.7</value>
        <unit>ug/g</unit>
        <uncertainty/>
        <label/>
        <info/>
      </analysis>
      <analysis>
        <nickname>Sc</nickname>
        <value>17.0</value>
        <unit>ug/g</unit>
        <uncertainty/>
        <label/>
        <info/>
      </analysis>
      <analysis>
        <nickname>V</nickname>
        <value>111.0</value>
        <unit>ug/g</unit>
        <uncertainty/>
        <label/>
        <info/>
      </analysis>
      <analysis>
        <nickname>Co</nickname>
        <value>25.2</value>
        <unit>ug/g</unit>
        <uncertainty/>
        <label/>
        <info/>
      </analysis>
      <analysis>
        <nickname>Ni</nickname>
        <value>123.0</value>
        <unit>ug/g</unit>
        <uncertainty/>
        <label/>
        <info/>
      </analysis>
      <analysis>
        <nickname>Cu</nickname>
        <value>27.7</value>
        <unit>ug/g</unit>
        <uncertainty/>
        <label/>
        <info/>
      </analysis>
      <analysis>
        <nickname>Zn</nickname>
        <value>61.8</value>
        <unit>ug/g</unit>
        <uncertainty/>
        <label/>
        <info/>
      </analysis>
      <analysis>
        <nickname>Ga</nickname>
        <value>16.2</value>
        <unit>ug/g</unit>
        <uncertainty/>
        <label/>
        <info/>
      </analysis>
      <analysis>
        <nickname>Nb</nickname>
        <value>8.31</value>
        <unit>ug/g</unit>
        <uncertainty/>
        <label/>
        <info/>
      </analysis>
      <analysis>
        <nickname>Mo</nickname>
        <value>0.59</value>
        <unit>ug/g</unit>
        <uncertainty/>
        <label/>
        <info/>
      </analysis>
      <analysis>
        <nickname>Rb</nickname>
        <value>66.6</value>
        <unit>ug/g</unit>
        <uncertainty/>
        <label/>
        <info/>
      </analysis>
      <analysis>
        <nickname>Zr</nickname>
        <value>106.0</value>
        <unit>ug/g</unit>
        <uncertainty/>
        <label/>
        <info/>
      </analysis>
      <analysis>
        <nickname>In</nickname>
        <value>0.0352</value>
        <unit>ug/g</unit>
        <uncertainty/>
        <label/>
        <info/>
      </analysis>
      <analysis>
        <nickname>Sb</nickname>
        <value>0.143</value>
        <unit>ug/g</unit>
        <uncertainty/>
        <label/>
        <info/>
      </analysis>
      <analysis>
        <nickname>Cs</nickname>
        <value>4.73</value>
        <unit>ug/g</unit>
        <uncertainty/>
        <label/>
        <info/>
      </analysis>
      <analysis>
        <nickname>Ba</nickname>
        <value>308.0</value>
        <unit>ug/g</unit>
        <uncertainty/>
        <label/>
        <info/>
      </analysis>
      <analysis>
        <nickname>La</nickname>
        <value>15.2</value>
        <unit>ug/g</unit>
        <uncertainty/>
        <label/>
        <info/>
      </analysis>
      <analysis>
        <nickname>Ce</nickname>
        <value>32.2</value>
        <unit>ug/g</unit>
        <uncertainty/>
        <label/>
        <info/>
      </analysis>
      <analysis>
        <nickname>Pr</nickname>
        <value>3.57</value>
        <unit>ug/g</unit>
        <uncertainty/>
        <label/>
        <info/>
      </analysis>
      <analysis>
        <nickname>Nd</nickname>
        <value>14.2</value>
        <unit>ug/g</unit>
        <uncertainty/>
        <label/>
        <info/>
      </analysis>
      <analysis>
        <nickname>Sm</nickname>
        <value>3.0</value>
        <unit>ug/g</unit>
        <uncertainty/>
        <label/>
        <info/>
      </analysis>
      <analysis>
        <nickname>Eu</nickname>
        <value>0.895</value>
        <unit>ug/g</unit>
        <uncertainty/>
        <label/>
        <info/>
      </analysis>
      <analysis>
        <nickname>Gd</nickname>
        <value>3.19</value>
        <unit>ug/g</unit>
        <uncertainty/>
        <label/>
        <info/>
      </analysis>
      <analysis>
        <nickname>Tb</nickname>
        <value>0.483</value>
        <unit>ug/g</unit>
        <uncertainty/>
        <label/>
        <info/>
      </analysis>
      <analysis>
        <nickname>Dy</nickname>
        <value>2.95</value>
        <unit>ug/g</unit>
        <uncertainty/>
        <label/>
        <info/>
      </analysis>
      <analysis>
        <nickname>Ho</nickname>
        <value>0.604</value>
        <unit>ug/g</unit>
        <uncertainty/>
        <label/>
        <info/>
      </analysis>
      <analysis>
        <nickname>Er</nickname>
        <value>1.72</value>
        <unit>ug/g</unit>
        <uncertainty/>
        <label/>
        <info/>
      </analysis>
      <analysis>
        <nickname>Tm</nickname>
        <value>0.249</value>
        <unit>ug/g</unit>
        <uncertainty/>
        <label/>
        <info/>
      </analysis>
      <analysis>
        <nickname>Yb</nickname>
        <value>1.65</value>
        <unit>ug/g</unit>
        <uncertainty/>
        <label/>
        <info/>
      </analysis>
      <analysis>
        <nickname>Lu</nickname>
        <value>0.251</value>
        <unit>ug/g</unit>
        <uncertainty/>
        <label/>
        <info/>
      </analysis>
      <analysis>
        <nickname>Hf</nickname>
        <value>2.92</value>
        <unit>ug/g</unit>
        <uncertainty/>
        <label/>
        <info/>
      </analysis>
      <analysis>
        <nickname>Ta</nickname>
        <value>0.592</value>
        <unit>ug/g</unit>
        <uncertainty/>
        <label/>
        <info/>
      </analysis>
      <analysis>
        <nickname>Tl</nickname>
        <value>0.34</value>
        <unit>ug/g</unit>
        <uncertainty/>
        <label/>
        <info/>
      </analysis>
      <analysis>
        <nickname>Pb</nickname>
        <value>18.9</value>
        <unit>ug/g</unit>
        <uncertainty/>
        <label/>
        <info/>
      </analysis>
      <analysis>
        <nickname>Bi</nickname>
        <value>0.0869</value>
        <unit>ug/g</unit>
        <uncertainty/>
        <label/>
        <info/>
      </analysis>
      <analysis>
        <nickname>Th</nickname>
        <value>5.03</value>
        <unit>ug/g</unit>
        <uncertainty/>
        <label/>
        <info/>
      </analysis>
      <analysis>
        <nickname>U</nickname>
        <value>2.31</value>
        <unit>ug/g</unit>
        <uncertainty/>
        <label/>
        <info/>
      </analysis>
    </chemistries>
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  <acquisition>
    <global_id>20191008091436-524410</global_id>
    <name>JA-2</name>
    <device>ICPMS Yokogawa PMS2000</device>
    <technique>Q-ICP-MS_procedures of Makishima and Nakamura (1997, 1999, 2006)</technique>
    <operator>Max</operator>
    <sample_global_id>20160921101920-406882</sample_global_id>
    <sample_name>JA-2</sample_name>
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    <chemistries>
      <analysis>
        <nickname>Rb</nickname>
        <value>75.2</value>
        <unit>ug/g</unit>
        <uncertainty/>
        <label/>
        <info/>
      </analysis>
      <analysis>
        <nickname>Sr</nickname>
        <value>247.0</value>
        <unit>ug/g</unit>
        <uncertainty/>
        <label/>
        <info/>
      </analysis>
      <analysis>
        <nickname>Y</nickname>
        <value>19.3</value>
        <unit>ug/g</unit>
        <uncertainty/>
        <label/>
        <info/>
      </analysis>
      <analysis>
        <nickname>Cs</nickname>
        <value>4.96</value>
        <unit>ug/g</unit>
        <uncertainty/>
        <label/>
        <info/>
      </analysis>
      <analysis>
        <nickname>Ba</nickname>
        <value>325.0</value>
        <unit>ug/g</unit>
        <uncertainty/>
        <label/>
        <info/>
      </analysis>
      <analysis>
        <nickname>Pb</nickname>
        <value>20.2</value>
        <unit>ug/g</unit>
        <uncertainty/>
        <label/>
        <info/>
      </analysis>
      <analysis>
        <nickname>Th</nickname>
        <value>5.38</value>
        <unit>ug/g</unit>
        <uncertainty/>
        <label/>
        <info/>
      </analysis>
      <analysis>
        <nickname>U</nickname>
        <value>2.5</value>
        <unit>ug/g</unit>
        <uncertainty/>
        <label/>
        <info/>
      </analysis>
      <analysis>
        <nickname>La</nickname>
        <value>16.4</value>
        <unit>ug/g</unit>
        <uncertainty/>
        <label/>
        <info/>
      </analysis>
      <analysis>
        <nickname>Ce</nickname>
        <value>34.4</value>
        <unit>ug/g</unit>
        <uncertainty/>
        <label/>
        <info/>
      </analysis>
      <analysis>
        <nickname>Pr</nickname>
        <value>3.88</value>
        <unit>ug/g</unit>
        <uncertainty/>
        <label/>
        <info/>
      </analysis>
      <analysis>
        <nickname>Nd</nickname>
        <value>15.1</value>
        <unit>ug/g</unit>
        <uncertainty/>
        <label/>
        <info/>
      </analysis>
      <analysis>
        <nickname>Sm</nickname>
        <value>3.22</value>
        <unit>ug/g</unit>
        <uncertainty/>
        <label/>
        <info/>
      </analysis>
      <analysis>
        <nickname>Eu</nickname>
        <value>0.956</value>
        <unit>ug/g</unit>
        <uncertainty/>
        <label/>
        <info/>
      </analysis>
      <analysis>
        <nickname>Gd</nickname>
        <value>3.07</value>
        <unit>ug/g</unit>
        <uncertainty/>
        <label/>
        <info/>
      </analysis>
      <analysis>
        <nickname>Tb</nickname>
        <value>0.499</value>
        <unit>ug/g</unit>
        <uncertainty/>
        <label/>
        <info/>
      </analysis>
      <analysis>
        <nickname>Dy</nickname>
        <value>3.07</value>
        <unit>ug/g</unit>
        <uncertainty/>
        <label/>
        <info/>
      </analysis>
      <analysis>
        <nickname>Ho</nickname>
        <value>0.651</value>
        <unit>ug/g</unit>
        <uncertainty/>
        <label/>
        <info/>
      </analysis>
      <analysis>
        <nickname>Er</nickname>
        <value>1.74</value>
        <unit>ug/g</unit>
        <uncertainty/>
        <label/>
        <info/>
      </analysis>
      <analysis>
        <nickname>Tm</nickname>
        <value>0.268</value>
        <unit>ug/g</unit>
        <uncertainty/>
        <label/>
        <info/>
      </analysis>
      <analysis>
        <nickname>Yb</nickname>
        <value>1.77</value>
        <unit>ug/g</unit>
        <uncertainty/>
        <label/>
        <info/>
      </analysis>
      <analysis>
        <nickname>Lu</nickname>
        <value>0.269</value>
        <unit>ug/g</unit>
        <uncertainty/>
        <label/>
        <info/>
      </analysis>
    </chemistries>
  </acquisition>
  <acquisition>
    <global_id>20191008134323-855159</global_id>
    <name>JA-2_TiO2</name>
    <device>HR-ICPMS Finningan, Element</device>
    <technique>HR-ICPMS</technique>
    <operator>Max</operator>
    <sample_global_id>20160921101920-406882</sample_global_id>
    <sample_name>JA-2</sample_name>
    <description/>
    <chemistries>
      <analysis>
        <nickname>TiO2</nickname>
        <value>0.679</value>
        <unit>%</unit>
        <uncertainty/>
        <label/>
        <info/>
      </analysis>
    </chemistries>
  </acquisition>
  <acquisition>
    <global_id>20191008113359-519411</global_id>
    <name>JA-2_W-Sb-Mo</name>
    <device>ICPMS Yokogawa PMS2000</device>
    <technique>Q-ICP-MS_procedures of Makishima and Nakamura (1997, 1999, 2006)</technique>
    <operator>Max</operator>
    <sample_global_id>20160921101920-406882</sample_global_id>
    <sample_name>JA-2</sample_name>
    <description></description>
    <chemistries>
      <analysis>
        <nickname>Mo</nickname>
        <value>0.545</value>
        <unit>ug/g</unit>
        <uncertainty/>
        <label/>
        <info/>
      </analysis>
      <analysis>
        <nickname>Sb</nickname>
        <value>0.136</value>
        <unit>ug/g</unit>
        <uncertainty/>
        <label/>
        <info/>
      </analysis>
      <analysis>
        <nickname>W</nickname>
        <value>1.11</value>
        <unit>ug/g</unit>
        <uncertainty/>
        <label/>
        <info/>
      </analysis>
    </chemistries>
  </acquisition>
  <acquisition>
    <global_id>20191009142209-700394</global_id>
    <name>JA-2_FeO</name>
    <device/>
    <technique>Titration_procedures of Yokoyama and Nakamura (2002)</technique>
    <operator></operator>
    <sample_global_id>20160921101920-406882</sample_global_id>
    <sample_name>JA-2</sample_name>
    <description></description>
    <chemistries>
      <analysis>
        <nickname>FeO</nickname>
        <value>3.75</value>
        <unit>%</unit>
        <uncertainty>0.01</uncertainty>
        <label/>
        <info/>
      </analysis>
    </chemistries>
  </acquisition>
  <acquisition>
    <global_id>20191023150858-176091</global_id>
    <name>JA-2_Hf</name>
    <device>MC-ICP-MS Finnigan, Neptune</device>
    <technique>Hf isotopes_procedures of Lu et al. (2007)</technique>
    <operator>Lucy</operator>
    <sample_global_id>20160921101920-406882</sample_global_id>
    <sample_name>JA-2</sample_name>
    <description></description>
    <chemistries>
      <analysis>
        <nickname>Hf</nickname>
        <value>2.96</value>
        <unit>ppm</unit>
        <uncertainty/>
        <label/>
        <info/>
      </analysis>
      <analysis>
        <nickname>Hf176zHf177</nickname>
        <value>0.282873</value>
        <unit></unit>
        <uncertainty/>
        <label/>
        <info/>
      </analysis>
    </chemistries>
  </acquisition>
  <acquisition>
    <global_id>20191015113423-922117</global_id>
    <name>JA-2_Li</name>
    <device>ICPMS Yokogawa PMS2000</device>
    <technique>Li isotopes_procedures of Moriguti and Nakamura (1998)</technique>
    <operator>Moriguti</operator>
    <sample_global_id>20160921101920-406882</sample_global_id>
    <sample_name>JA-2</sample_name>
    <description></description>
    <chemistries>
      <analysis>
        <nickname>Li</nickname>
        <value>29.5</value>
        <unit>ug/g</unit>
        <uncertainty/>
        <label/>
        <info/>
      </analysis>
    </chemistries>
  </acquisition>
  <acquisition>
    <global_id>20191002151232-741861</global_id>
    <name>JA-2_Bi-Tl-In-Cd</name>
    <device>Q-ICPMS Agilent 7500cs</device>
    <technique>Q-ICP-MS_procedures of Makishima and Nakamura (1997, 1999, 2006)</technique>
    <operator>Max</operator>
    <sample_global_id>20160921101920-406882</sample_global_id>
    <sample_name>JA-2</sample_name>
    <description></description>
    <chemistries>
      <analysis>
        <nickname>Cd</nickname>
        <value>0.073</value>
        <unit>ug/g</unit>
        <uncertainty/>
        <label/>
        <info/>
      </analysis>
      <analysis>
        <nickname>In</nickname>
        <value>0.035</value>
        <unit>ug/g</unit>
        <uncertainty/>
        <label/>
        <info/>
      </analysis>
      <analysis>
        <nickname>Tl</nickname>
        <value>0.354</value>
        <unit>ug/g</unit>
        <uncertainty/>
        <label/>
        <info/>
      </analysis>
      <analysis>
        <nickname>Bi</nickname>
        <value>0.083</value>
        <unit>ug/g</unit>
        <uncertainty/>
        <label/>
        <info/>
      </analysis>
    </chemistries>
  </acquisition>
  <acquisition>
    <global_id>20191003102338-715180</global_id>
    <name>JA-2_d66Zn</name>
    <device>ICPMS Thermo-Fisher Neptune</device>
    <technique>MC-ICPMS</technique>
    <operator>Max</operator>
    <sample_global_id>20160921101920-406882</sample_global_id>
    <sample_name>JA-2</sample_name>
    <description></description>
    <chemistries>
      <analysis>
        <nickname>d66Zn</nickname>
        <value>-0.33</value>
        <unit>permil</unit>
        <uncertainty/>
        <label/>
        <info/>
      </analysis>
    </chemistries>
  </acquisition>
  <acquisition>
    <global_id>20191003113551-996303</global_id>
    <name>JA-2_d56Fe</name>
    <device>ICPMS Thermo-Fisher Neptune</device>
    <technique>MC-ICPMS</technique>
    <operator>Max</operator>
    <sample_global_id>20160921101920-406882</sample_global_id>
    <sample_name>JA-2</sample_name>
    <description></description>
    <chemistries>
      <analysis>
        <nickname>d56Fe</nickname>
        <value>-0.02</value>
        <unit>permil</unit>
        <uncertainty/>
        <label/>
        <info/>
      </analysis>
    </chemistries>
  </acquisition>
  <acquisition>
    <global_id>20191004111800-368724</global_id>
    <name>JA-2_Ge-As-Se-Te</name>
    <device>Q-ICPMS Agilent 7500cs</device>
    <technique>ICPMS with isotope dilution and internal standardization</technique>
    <operator>Max</operator>
    <sample_global_id>20160921101920-406882</sample_global_id>
    <sample_name>JA-2</sample_name>
    <description/>
    <chemistries>
      <analysis>
        <nickname>Ge</nickname>
        <value>1.09</value>
        <unit>ug/g</unit>
        <uncertainty/>
        <label/>
        <info/>
      </analysis>
      <analysis>
        <nickname>As</nickname>
        <value>0.698</value>
        <unit>ug/g</unit>
        <uncertainty/>
        <label/>
        <info/>
      </analysis>
      <analysis>
        <nickname>Se</nickname>
        <value>0.0047</value>
        <unit>ug/g</unit>
        <uncertainty/>
        <label/>
        <info/>
      </analysis>
      <analysis>
        <nickname>Te</nickname>
        <value>0.00078</value>
        <unit>ug/g</unit>
        <uncertainty/>
        <label/>
        <info/>
      </analysis>
    </chemistries>
  </acquisition>
  <acquisition>
    <global_id>20191008105613-466522</global_id>
    <name>JA-2_Ta-Hf-Nb-Zr</name>
    <device>ICPMS Yokogawa PMS2000</device>
    <technique>Q-ICP-MS_procedures of Makishima and Nakamura (1997, 1999, 2006)</technique>
    <operator>Max</operator>
    <sample_global_id>20160921101920-406882</sample_global_id>
    <sample_name>JA-2</sample_name>
    <description></description>
    <chemistries>
      <analysis>
        <nickname>Zr</nickname>
        <value>113.0</value>
        <unit>ug/g</unit>
        <uncertainty/>
        <label/>
        <info/>
      </analysis>
      <analysis>
        <nickname>Nb</nickname>
        <value>8.65</value>
        <unit>ug/g</unit>
        <uncertainty/>
        <label/>
        <info/>
      </analysis>
      <analysis>
        <nickname>Hf</nickname>
        <value>2.91</value>
        <unit>ug/g</unit>
        <uncertainty/>
        <label/>
        <info/>
      </analysis>
      <analysis>
        <nickname>Ta</nickname>
        <value>0.645</value>
        <unit>ug/g</unit>
        <uncertainty/>
        <label/>
        <info/>
      </analysis>
    </chemistries>
  </acquisition>
  <acquisition>
    <global_id>20191008141043-668614</global_id>
    <name>JA-2_S</name>
    <device>HR-ICPMS Finningan, Element</device>
    <technique>HR-ICPMS</technique>
    <operator>Max</operator>
    <sample_global_id>20160921101920-406882</sample_global_id>
    <sample_name>JA-2</sample_name>
    <description/>
    <chemistries>
      <analysis>
        <nickname>S</nickname>
        <value>6.76</value>
        <unit>ug/g</unit>
        <uncertainty/>
        <label/>
        <info/>
      </analysis>
    </chemistries>
  </acquisition>
  <acquisition>
    <global_id>20191009100320-146206</global_id>
    <name>JA-2_Cr-Ni-Cu-Zn</name>
    <device>HR-ICPMS Finningan, Element</device>
    <technique>HR-ICPMS</technique>
    <operator>Max</operator>
    <sample_global_id>20160921101920-406882</sample_global_id>
    <sample_name>JA-2</sample_name>
    <description/>
    <chemistries>
      <analysis>
        <nickname>Cr</nickname>
        <value>417.0</value>
        <unit>ug/g</unit>
        <uncertainty/>
        <label/>
        <info/>
      </analysis>
      <analysis>
        <nickname>Ni</nickname>
        <value>135.0</value>
        <unit>ug/g</unit>
        <uncertainty/>
        <label/>
        <info/>
      </analysis>
      <analysis>
        <nickname>Cu</nickname>
        <value>28.1</value>
        <unit>ug/g</unit>
        <uncertainty/>
        <label/>
        <info/>
      </analysis>
      <analysis>
        <nickname>Zn</nickname>
        <value>65.0</value>
        <unit>ug/g</unit>
        <uncertainty/>
        <label/>
        <info/>
      </analysis>
    </chemistries>
  </acquisition>
  <acquisition>
    <global_id>20191219094725-577526</global_id>
    <name>JA-2</name>
    <device>MC-ICP-MS Finnigan, Neptune</device>
    <technique>MC-ICPMS</technique>
    <operator/>
    <sample_global_id>20160921101920-406882</sample_global_id>
    <sample_name>JA-2</sample_name>
    <description/>
    <chemistries>
      <analysis>
        <nickname>d65Cu</nickname>
        <value>-0.33</value>
        <unit>permil</unit>
        <uncertainty/>
        <label/>
        <info/>
      </analysis>
    </chemistries>
  </acquisition>
  <acquisition>
    <global_id>20191223153355-398443</global_id>
    <name>JA-2_S (Max, 2012)</name>
    <device>ICPMS Thermo-Fisher Neptune</device>
    <technique>HR-ICPMS</technique>
    <operator></operator>
    <sample_global_id>20160921101920-406882</sample_global_id>
    <sample_name>JA-2</sample_name>
    <description></description>
    <chemistries>
      <analysis>
        <nickname>S</nickname>
        <value>6.61</value>
        <unit>ug/g</unit>
        <uncertainty>2.0</uncertainty>
        <label/>
        <info/>
      </analysis>
    </chemistries>
  </acquisition>
  <acquisition>
    <global_id>20200210104926-254428</global_id>
    <name>JA-2_Li</name>
    <device>TIMS Thermo-Fisher MAT261</device>
    <technique>Li isotopes_procedures of Moriguti and Nakamura (1998)</technique>
    <operator></operator>
    <sample_global_id>20160921101920-406882</sample_global_id>
    <sample_name>JA-2</sample_name>
    <description></description>
    <chemistries>
      <analysis>
        <nickname>Li</nickname>
        <value>28.7</value>
        <unit>ug/g</unit>
        <uncertainty/>
        <label/>
        <info/>
      </analysis>
    </chemistries>
  </acquisition>
</acquisitions>

place quantity

ISEI/main/XRF almost 4 years

2016-09-21 10:19 2020-07-22 22:57

description:

name	device	global-id
JA-2_B pub 1	ICPMS Yokogawa PMS2000	20191007144514-911634
ref-gl-ja2 pub 51	Q-ICPMS Agilent 7500cs	20170302124505-267282
JA-2 pub 22	ICPMS Yokogawa PMS2000	20191008091436-524410
JA-2_TiO2 pub 1	HR-ICPMS Finningan, Element	20191008134323-855159
JA-2_W-Sb-Mo pub 3	ICPMS Yokogawa PMS2000	20191008113359-519411
JA-2_FeO pub 1		20191009142209-700394
JA-2_Hf pub 2	MC-ICP-MS Finnigan, Neptune	20191023150858-176091
JA-2_Li pub 1	ICPMS Yokogawa PMS2000	20191015113423-922117
JA-2_Bi-Tl-In-Cd pub 4	Q-ICPMS Agilent 7500cs	20191002151232-741861
JA-2_d66Zn pub 1	ICPMS Thermo-Fisher Neptune	20191003102338-715180
JA-2_d56Fe pub 1	ICPMS Thermo-Fisher Neptune	20191003113551-996303
JA-2_Ge-As-Se-Te pub 4	Q-ICPMS Agilent 7500cs	20191004111800-368724
JA-2_Ta-Hf-Nb-Zr pub 4	ICPMS Yokogawa PMS2000	20191008105613-466522
JA-2_S pub 1	HR-ICPMS Finningan, Element	20191008141043-668614
JA-2_Cr-Ni-Cu-Zn pub 4	HR-ICPMS Finningan, Element	20191009100320-146206
JA-2 pub 1	MC-ICP-MS Finnigan, Neptune	20191219094725-577526
JA-2_S (Max, 2012) pub 1	ICPMS Thermo-Fisher Neptune	20191223153355-398443
JA-2_Li pub 1	TIMS Thermo-Fisher MAT261	20200210104926-254428

	name		global-id
	Akio Makishima & Eizo Nakamura (1999) Determination of molybdenum, antimony and tungsten at sub microgram per gram levels in geological materials by ID-FI-ICP-MS, Geostandards Newsletter, 23, 137-148, doi:10.1111/j.1751-908X.1999.tb00569.x. Table 8. Grand average of Mo, Sb and W concentrations in basalt and andesite reference materials		20191008113809-636908
	Makishima, Akio & Nakamura, Eizo (2012) High-resolution MC-ICPMS employing amplifers with a 10 12 ohm resistor for bulk sulfur determination in biological and geological samples, Journal of Analytical Atomic Spectrometry, 27, 891-895, doi:10.1039/c2ja10337k. Table 2 Sulfur concentrations for silicate reference materials and carbonaceous chondrites determined by ID-HR-MC-ICPMS and in references		20191223144532-884161
	Takuya Moriguti et al. (2004) Determination of Lithium Contents in silicates by Isotope Dilution ICP-MS and Its Evaluation by Isotope Dilution Thermal Ionisation Mass Spectrometry, Geostandars and geoanalytical research, 28, 371-382, doi:10.1111/j.1751-908X.2004.tb00756.x. Table 4b. Analytical results for lithium in silicate reference materials by TIMS Table 4a. Analytical results for lithium in silicate reference materials by ICP-MS		20191015111023-845326
	Akio Makishima & Eizo Nakamura (2001) Determination of total sulfur at microgram per gram levels in geological materials by oxidation of sulfur into sulfate with in situ generation of bromine using isotope dilution high resolution ICPMS, Analytical Chemistry, 73, 2547 – 2553, doi:10.1021/ac001550i. Table 4. Analytical Results for Sulfur (μg g-1) in Standard Reference Materials and in Smithsonian Reference Allende Powder by ID-FI-ICPMS		20191008140313-242128
	Makishima, Akio & Nakamura, E. (2006) Determination of Major, Minor and Trace Elements in Silicate Samples by ICP-QMS and ICP-SFMS Applying Isotope Dilution-Internal Standardisation (ID-IS) and Multi-Stage Internal Standardisation, Geostandards and Geoanalytical Research, 30, 245--271, doi:10.1111/j.1751-908X.2006.tb01066.x. Table 8.Analytical results for andesite reference materials in this study		20160819190828-080638
	Tetsuya Yokoyama & Eizo Nakamura (2002) Precise determination of ferrous iron in silicate rocks, Geochimica et Cosmochimica Acta, 66, 1085-1093, doi:10.1016/S0016-7037(01)00809-2. Table 2. FeO (wt.%) of GSJ standard rocks		20181025122944-742474
	Akio Makishima (2013) A Simple and Fast Separation Method of Fe Employing Extraction Resin for Isotope Ratio Determination by Multicollector ICP-MS, International Journal of Analytical Mass Spectrometry and Chromatography, 1, 95-102, doi:10.4236/ijamsc.2013.12012. Table 4. δ56Fe values of USGS and GSJ silicate reference materials and carbonaceous chondrites		20191003111344-518696
	Akio Makishima et al. (2011) Simultaneous Determination of Cd, In, Tl and Bi by Isotope Dilution‐Internal Standardisation ICP‐QMS with Corrections Using Externally Measured MoO+/Mo+ Ratios , Geostandards and Geoanalytical Research, 35, 57 - 67, doi:10.1111/j.1751-908X.2010.00054.x. Table 3. Analytical results for Cd, In, Tl and Bi obtained in this study		20191002142745-877448
	Akio Makishima & Eizo Nakamura (2000) Determination of titanium at microgram per gram levels in milligramamounts of silicate materials by isotope dilution highresolution inductively coupled plasma mass spectrometry with flow injection, Journal of Analytical Atomic Spectrometry, 15, 263-267, doi:10.1039/A909020G. Table 4 TiO2 content in silicate reference materials obtained by ID-FI-HR-ICPMS		20191008132017-029409
	Akio Makishima et al. (1997) Determination of boron in silicate samples by direct aspiration of sample HF solutions into ICPMS, Analytical Chemistry, 69, 3754-3759, doi:10.1021/ac970383s. Table 4-5. Analytical Results for Boron (μg g-1) in Standard Rocks and Allende Meteorites by ID-FI-ICPMS		20191007135405-842418
	Lu et al. (2007) Purification of Hf in silicate materials using extraction chromatographic resin, and its application to precise determination of <sup>176</sup>Hf/<sup>177</sup>Hf by MC-ICP-MS with <sup>179</sup>Hf spike, Journal of Analytical Atomic Spectrometry, 22, 69-76, doi:10.1039/b610197f. Table 2-3. 176Hf/177Hf in reference materials without and with spike and concentration if Hf (mg/g) in silicate reference materials		20100403101828330.admin
	Akio Makishima & Eizo Nakamura (2009) Determination of Ge, As, Se and Te in Silicate Samples Using Isotope Dilution‐Internal Standardisation Octopole Reaction Cell ICP‐QMS by Normal Sample Nebulisation, Geostandards and Geoanalytical Research, 33, 369-384, doi:10.1111/j.1751-908X.2009.00014.x. Table 5-6. Analytical results for Ge, As, Se and Te in silicate reference materials		20191004104221-721601
	Lu et al. (2007) Coprecipitation of Ti, Mo, Sn and Sb with fluorides and application to determination of B, Ti, Zr, Nb, Mo, Sn, Sb, Hf and Ta by ICP-MS, Chemical Geology, 236, 13-26, doi:10.1016/j.chemgeo.2006.08.007. Table 6. Analytical results for andesite standard reference materials		20100403101828279.admin
	Makishima et al. (2002) Determination of Chromium, Nickel, Copper and Zinc in Milligram Samples of Geological Materials Using Isotope Dilution High Resolution Inductively Coupled Plasma-Mass Spectrometry, Geostandards Newsletter, 26, 41-51, doi:10.1111/j.1751-908X.2002.tb00622.x. Table 7.Chromium, Ni, Cu and Zn contents (μg g-1) in geological reference materials obtained by ID-HR-ICP-MS		20191009093919-635097
	Akio Makishima & Eizo Nakamura (1997) Suppression of matrix effects in ICP-MS by high power operationof ICP: Application to precise determination of Rb, Sr, Y, Cs, Ba, REE, Pb, Th and U at ng g(-1) levels in milligram silicate samples, Geostandards Newsletter, 21, 307-319, doi:10.1111/j.1751-908X.1997.tb00678.x. Tables 6. Trace element concentrations in AGV-1, JA-1, JA-2 and JA-3		20191007145555-553597
	Makishima, Akio (2014) Cu Purification Using an Extraction Resin for Determination of Isotope Ratios by Multicollector ICP-MS, Chromatography, 1, 96-107, doi:10.3390/chromatography1030096. Table 4. δ 65 Cu values of US Geological Survey (USGS) and Geological Survey of Japan (GSJ) silicate reference materials. Note that δ 65 Cu values are based on ERM-AE647.		20191218151715-692732
	Akio Makishima & Eizo Nakamura (2013) Low-blank chemistry for Zn stable isotope ratio determination using extraction chromatographic resin and double spike-multiple collector-ICP-MS , Journal of Analytical Atomic Spectrometry, 28, 127-133, doi:10.1039/c2ja30271c. Table 4 δ66Zn of silicate reference materials		20191003095232-210545
	Akio Makishima et al. (1999) Determination of Zirconium, Niobium, Hafnium and Tantalum at ng g‐1 Levels in Geological Materials by Direct Nebulisation of Sample HF Solution into FI‐ICP‐MS, Geostandards Newsletter, 23, 7-20, doi:10.1111/j.1751-908X.1999.tb00555.x. Table 7. Concentrations of Zr, Nb, Hf and Ta in silicate reference materials		20191008101034-927445

		name		spots	global-id
		tixhr887022129.jpeg pub		0	20160921101927-173444