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Journal Articles
Accepted Manuscript
Publisher: ASME
Article Type: Research-Article
ASME J of Nuclear Rad Sci.
Paper No: NERS-24-1017
Published Online: October 4, 2024
Journal Articles
Publisher: ASME
Article Type: Research-Article
ASME J of Nuclear Rad Sci. April 2025, 11(2): 021603.
Paper No: NERS-23-1112
Published Online: October 3, 2024
Image
in Investigation of Metal–H 2 O Systems at Elevated Temperatures: Part III: Solubility Data and New Zr Pourbaix Diagrams at 298.15 K and 373.15 K
> Journal of Nuclear Engineering and Radiation Science
Published Online: October 3, 2024
Fig. 1 Hydrolysis distribution plot of Zr(IV) species at 25 °C More about this image found in Hydrolysis distribution plot of Zr(IV) species at 25 °C
Image
in Investigation of Metal–H 2 O Systems at Elevated Temperatures: Part III: Solubility Data and New Zr Pourbaix Diagrams at 298.15 K and 373.15 K
> Journal of Nuclear Engineering and Radiation Science
Published Online: October 3, 2024
Fig. 2 Hydrolysis distribution plot of Sn(IV) and Sn(II) species at 25 °C More about this image found in Hydrolysis distribution plot of Sn(IV) and Sn(II) species at 25 °C
Image
in Investigation of Metal–H 2 O Systems at Elevated Temperatures: Part III: Solubility Data and New Zr Pourbaix Diagrams at 298.15 K and 373.15 K
> Journal of Nuclear Engineering and Radiation Science
Published Online: October 3, 2024
Fig. 3 Hydrolysis distribution plot of Cr species at 25 °C More about this image found in Hydrolysis distribution plot of Cr species at 25 °C
Image
in Investigation of Metal–H 2 O Systems at Elevated Temperatures: Part III: Solubility Data and New Zr Pourbaix Diagrams at 298.15 K and 373.15 K
> Journal of Nuclear Engineering and Radiation Science
Published Online: October 3, 2024
Fig. 4 Diagram ( a ) and picture ( b ) of reaction vessel used. The numbering schemes are identical in ( a ) and ( b ). (1) Elevated temperature ORP and p H electrodes; (2) pressure gauge; (3) 316 SS blind flanges with rubber gasket; (4) K-type thermocouple; and (5) band heating jacket. More about this image found in Diagram ( a ) and picture ( b ) of reaction vessel used. The numbering sche...
Image
in Investigation of Metal–H 2 O Systems at Elevated Temperatures: Part III: Solubility Data and New Zr Pourbaix Diagrams at 298.15 K and 373.15 K
> Journal of Nuclear Engineering and Radiation Science
Published Online: October 3, 2024
Fig. 5 Pourbaix diagram for zirconium at 25 °C and 10 −6 M More about this image found in Pourbaix diagram for zirconium at 25 °C and 10 −6 M
Image
in Investigation of Metal–H 2 O Systems at Elevated Temperatures: Part III: Solubility Data and New Zr Pourbaix Diagrams at 298.15 K and 373.15 K
> Journal of Nuclear Engineering and Radiation Science
Published Online: October 3, 2024
Fig. 6 Pourbaix diagram for zirconium at 100 °C and 10 −6 M More about this image found in Pourbaix diagram for zirconium at 100 °C and 10 −6 M
Image
in Investigation of Metal–H 2 O Systems at Elevated Temperatures: Part III: Solubility Data and New Zr Pourbaix Diagrams at 298.15 K and 373.15 K
> Journal of Nuclear Engineering and Radiation Science
Published Online: October 3, 2024
Fig. 7 Pourbaix diagram relevant to Zircaloy-4 at 25 °C and 10 −6 M More about this image found in Pourbaix diagram relevant to Zircaloy-4 at 25 °C and 10 −6 M
Image
in Investigation of Metal–H 2 O Systems at Elevated Temperatures: Part III: Solubility Data and New Zr Pourbaix Diagrams at 298.15 K and 373.15 K
> Journal of Nuclear Engineering and Radiation Science
Published Online: October 3, 2024
Fig. 8 Pourbaix diagram relevant to Zircaloy-4 at 100 °C and 10 −6 M More about this image found in Pourbaix diagram relevant to Zircaloy-4 at 100 °C and 10 −6 M
Image
in Investigation of Metal–H 2 O Systems at Elevated Temperatures: Part III: Solubility Data and New Zr Pourbaix Diagrams at 298.15 K and 373.15 K
> Journal of Nuclear Engineering and Radiation Science
Published Online: October 3, 2024
Fig. 9 The ICP-MS measurements for Zircaloy-4 More about this image found in The ICP-MS measurements for Zircaloy-4
Journal Articles
Publisher: ASME
Article Type: Research-Article
ASME J of Nuclear Rad Sci. April 2025, 11(2): 021602.
Paper No: NERS-23-1111
Published Online: September 30, 2024
Journal Articles
Publisher: ASME
Article Type: Research-Article
ASME J of Nuclear Rad Sci. April 2025, 11(2): 021601.
Paper No: NERS-23-1110
Published Online: September 30, 2024
Image
in Investigation of Metal–H 2 O Systems at Elevated Temperatures: Part I. Development of a Solubility Apparatus Specialized for Super-Ambient Conditions
> Journal of Nuclear Engineering and Radiation Science
Published Online: September 30, 2024
Fig. 1 Distribution of zinc hydrolysis species as a function of pH at 25 °C and 85 °C [ 2 ] More about this image found in Distribution of zinc hydrolysis species as a function of pH at 25 °C and 85...
Image
in Investigation of Metal–H 2 O Systems at Elevated Temperatures: Part I. Development of a Solubility Apparatus Specialized for Super-Ambient Conditions
> Journal of Nuclear Engineering and Radiation Science
Published Online: September 30, 2024
Fig. 2 Schematic diagram of the batch reaction vessel used for the solubility measurements: 1. Teflon-lined vessel body; 2. and 3. 316 SS blind flanges; 4. band heater; 5. K-type thermocouple; 6. and 7. elevated temperature pH and ORP electrodes; and 8. pressure gauge [ 2 ] More about this image found in Schematic diagram of the batch reaction vessel used for the solubility meas...
Image
in Investigation of Metal–H 2 O Systems at Elevated Temperatures: Part I. Development of a Solubility Apparatus Specialized for Super-Ambient Conditions
> Journal of Nuclear Engineering and Radiation Science
Published Online: September 30, 2024
Fig. 3 The zinc oxide solubility evolution in four pH environments measured over 8 h at 85 °C as determined by flame AAS and ICP-OES [ 2 ] More about this image found in The zinc oxide solubility evolution in four pH environments measured over 8...
Image
in Investigation of Metal-H 2 O Systems at Elevated Temperatures: Part II. SnO 2(s) Solubility Data and New Sn Pourbaix Diagrams at 298.15 K and 358.15 K
> Journal of Nuclear Engineering and Radiation Science
Published Online: September 30, 2024
Fig. 1 Distribution of tin(IV) hydrolysis species as a function of p H at 25 °C More about this image found in Distribution of tin(IV) hydrolysis species as a function of p H at 25 °C
Image
in Investigation of Metal-H 2 O Systems at Elevated Temperatures: Part II. SnO 2(s) Solubility Data and New Sn Pourbaix Diagrams at 298.15 K and 358.15 K
> Journal of Nuclear Engineering and Radiation Science
Published Online: September 30, 2024
Fig. 2 Schematic diagram of the reaction vessel for elevated temperature solubility measurements: 1. Teflon-lined vessel body; 2. and 3. 316 SS blind flanges; 4. band heater; 5. K-type thermocouple; 6. and 7. elevated temperature p H and ORP electrodes; and 8. pressure gauge. More about this image found in Schematic diagram of the reaction vessel for elevated temperature solubilit...
Image
in Investigation of Metal-H 2 O Systems at Elevated Temperatures: Part II. SnO 2(s) Solubility Data and New Sn Pourbaix Diagrams at 298.15 K and 358.15 K
> Journal of Nuclear Engineering and Radiation Science
Published Online: September 30, 2024
Fig. 3 Raman spectra of a tin(IV) oxide sample recovered after an 85 °C solubility experiment in a p H 3.03 (CH 3 COOH) medium More about this image found in Raman spectra of a tin(IV) oxide sample recovered after an 85 °C solubility...
Image
in Investigation of Metal-H 2 O Systems at Elevated Temperatures: Part II. SnO 2(s) Solubility Data and New Sn Pourbaix Diagrams at 298.15 K and 358.15 K
> Journal of Nuclear Engineering and Radiation Science
Published Online: September 30, 2024
Fig. 4 Tin(IV) oxide solubility in acidic and alkaline p H ranges over a period of 48 h at 25 °C determined by ICP-OES More about this image found in Tin(IV) oxide solubility in acidic and alkaline p H ranges over a period o...
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