3D-printed Ag–AgCl electrodes for laboratory  measurements of self-potential

Rowan, Thomas S. L.; Karantoni, Vilelmini A.; Butler, Adrian P.; Jackson, Matthew D.

doi:10.5194/gi-12-259-2023

Articles | Volume 12, issue 2

https://doi.org/10.5194/gi-12-259-2023

© Author(s) 2023. This work is distributed under
the Creative Commons Attribution 4.0 License.

https://doi.org/10.5194/gi-12-259-2023

© Author(s) 2023. This work is distributed under
the Creative Commons Attribution 4.0 License.

Articles | Volume 12, issue 2

Research article

|

15 Dec 2023

Research article |

| 15 Dec 2023

3D-printed Ag–AgCl electrodes for laboratory measurements of self-potential

Thomas S. L. Rowan, Vilelmini A. Karantoni, Adrian P. Butler, and Matthew D. Jackson

Viewed

Total article views: 3,034 (including HTML, PDF, and XML)

HTML	PDF	XML	Total	Supplement	BibTeX	EndNote
1,922	964	148	3,034	156	142	208

HTML: 1,922
PDF: 964
XML: 148
Total: 3,034
Supplement: 156
BibTeX: 142
EndNote: 208

Views and downloads (calculated since 28 Feb 2023)

Month	HTML	PDF	XML	Total
Feb 2023	17	2	0	19
Mar 2023	107	26	9	142
Apr 2023	35	10	0	45
May 2023	10	7	0	17
Jun 2023	26	7	3	36
Jul 2023	17	16	6	39
Aug 2023	31	11	4	46
Sep 2023	14	17	1	32
Oct 2023	11	12	4	27
Nov 2023	5	1	6
Dec 2023	75	19	6	100
Jan 2024	50	10	2	62
Feb 2024	111	11	1	123
Mar 2024	53	5	3	61
Apr 2024	39	8	11	58
May 2024	35	26	7	68
Jun 2024	96	29	4	129
Jul 2024	35	20	4	59
Aug 2024	40	12	2	54
Sep 2024	38	6	2	46
Oct 2024	27	12	1	40
Nov 2024	25	11	0	36
Dec 2024	21	17	0	38
Jan 2025	33	16	8	57
Feb 2025	22	10	6	38
Mar 2025	38	22	3	63
Apr 2025	29	20	1	50
May 2025	42	20	1	63
Jun 2025	46	26	3	75
Jul 2025	44	25	2	71
Aug 2025	73	19	0	92
Sep 2025	125	38	6	169
Oct 2025	41	57	3	101
Nov 2025	107	64	2	173
Dec 2025	93	51	4	148
Jan 2026	77	66	9	152
Feb 2026	81	46	15	142
Mar 2026	67	81	6	154
Apr 2026	85	109	8	202
May 2026	1	0	1

Cumulative views and downloads (calculated since 28 Feb 2023)

Month	HTML	PDF	XML	Total
Feb 2023	17	2	0	19
Mar 2023	107	26	9	142
Apr 2023	35	10	0	45
May 2023	10	7	0	17
Jun 2023	26	7	3	36
Jul 2023	17	16	6	39
Aug 2023	31	11	4	46
Sep 2023	14	17	1	32
Oct 2023	11	12	4	27
Nov 2023	5	1	6
Dec 2023	75	19	6	100
Jan 2024	50	10	2	62
Feb 2024	111	11	1	123
Mar 2024	53	5	3	61
Apr 2024	39	8	11	58
May 2024	35	26	7	68
Jun 2024	96	29	4	129
Jul 2024	35	20	4	59
Aug 2024	40	12	2	54
Sep 2024	38	6	2	46
Oct 2024	27	12	1	40
Nov 2024	25	11	0	36
Dec 2024	21	17	0	38
Jan 2025	33	16	8	57
Feb 2025	22	10	6	38
Mar 2025	38	22	3	63
Apr 2025	29	20	1	50
May 2025	42	20	1	63
Jun 2025	46	26	3	75
Jul 2025	44	25	2	71
Aug 2025	73	19	0	92
Sep 2025	125	38	6	169
Oct 2025	41	57	3	101
Nov 2025	107	64	2	173
Dec 2025	93	51	4	148
Jan 2026	77	66	9	152
Feb 2026	81	46	15	142
Mar 2026	67	81	6	154
Apr 2026	85	109	8	202
May 2026	1	0	1

Viewed (geographical distribution)

Total article views: 3,034 (including HTML, PDF, and XML) Thereof 3,004 with geography defined and 30 with unknown origin.

Country	#	Views	%

1

1

Cited

Saved (final revised paper)

Latest update: 02 May 2026

Short summary

This paper presents a design for a 3D-printed rechargeable electrode that measures self-potential (SP) in different types of laboratory experiments. It is small, cheap, robust, and stable, and it offers the same performance as custom-machined laboratory standards. The use of 3D printing technology makes the electrode more versatile and cost-effective than traditional laboratory standards. Examples of its use under both low and high pressure have been included, as have 3D-printable designs.