The effect of the zero-field splitting in  light-induced pulsed dipolar electron  paramagnetic resonance (EPR) spectroscopy

Scherer, Andreas; Yildirim, Berk; Drescher, Malte

doi:10.5194/mr-4-27-2023

Articles | Volume 4, issue 1

https://doi.org/10.5194/mr-4-27-2023

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

https://doi.org/10.5194/mr-4-27-2023

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

Articles | Volume 4, issue 1

Research article

|

08 Feb 2023

Research article |

| 08 Feb 2023

The effect of the zero-field splitting in light-induced pulsed dipolar electron paramagnetic resonance (EPR) spectroscopy

Andreas Scherer, Berk Yildirim, and Malte Drescher

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Apr 2023	54	11	0	65
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Jan 2024	26	8	2	36
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Dec 2024	24	4	1	29
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Feb 2025	31	5	0	36
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Apr 2025	22	8	0	30
May 2025	32	8	1	41
Jun 2025	68	46	0	114
Jul 2025	44	20	0	64
Aug 2025	32	14	0	46
Sep 2025	56	23	4	83
Oct 2025	39	22	2	63
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Dec 2025	80	19	3	102
Jan 2026	76	16	5	97
Feb 2026	81	24	5	110
Mar 2026	58	18	7	83
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Cumulative views and downloads (calculated since 10 Nov 2022)

Month	HTML	PDF	XML	Total
Nov 2022	174	57	12	243
Dec 2022	113	27	6	146
Jan 2023	82	23	4	109
Feb 2023	171	43	3	217
Mar 2023	59	15	0	74
Apr 2023	54	11	0	65
May 2023	32	15	3	50
Jun 2023	27	7	1	35
Jul 2023	22	19	1	42
Aug 2023	20	12	2	34
Sep 2023	29	11	1	41
Oct 2023	18	14	4	36
Nov 2023	26	6	1	33
Dec 2023	23	19	3	45
Jan 2024	26	8	2	36
Feb 2024	30	9	0	39
Mar 2024	22	19	1	42
Apr 2024	30	8	5	43
May 2024	33	13	1	47
Jun 2024	37	8	2	47
Jul 2024	27	6	3	36
Aug 2024	33	10	1	44
Sep 2024	23	4	2	29
Oct 2024	30	1	1	32
Nov 2024	15	8	0	23
Dec 2024	24	4	1	29
Jan 2025	17	15	1	33
Feb 2025	31	5	0	36
Mar 2025	26	7	4	37
Apr 2025	22	8	0	30
May 2025	32	8	1	41
Jun 2025	68	46	0	114
Jul 2025	44	20	0	64
Aug 2025	32	14	0	46
Sep 2025	56	23	4	83
Oct 2025	39	22	2	63
Nov 2025	66	36	2	104
Dec 2025	80	19	3	102
Jan 2026	76	16	5	97
Feb 2026	81	24	5	110
Mar 2026	58	18	7	83
Apr 2026	94	35	4	133
May 2026	94	33	2	129
Jun 2026	3	4	0	7

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Short summary

Light-induced pulsed dipolar EPR spectroscopy (PDS) is an emerging field that uses photoexcited triplet states to determine distance restraints in the nanometer range. To date, light-induced PDS data have been analyzed with methods developed for techniques that do not invoke light-induced triplets. Here, we provide a new theoretical description that takes the full nature of the triplet state into account and demonstrate that it leads to more accurate fits of experimental data.