J. C. Eckert

521 total citations
21 papers, 409 citations indexed

About

J. C. Eckert is a scholar working on Electronic, Optical and Magnetic Materials, Atomic and Molecular Physics, and Optics and Condensed Matter Physics. According to data from OpenAlex, J. C. Eckert has authored 21 papers receiving a total of 409 indexed citations (citations by other indexed papers that have themselves been cited), including 17 papers in Electronic, Optical and Magnetic Materials, 15 papers in Atomic and Molecular Physics, and Optics and 8 papers in Condensed Matter Physics. Recurrent topics in J. C. Eckert's work include Magnetic properties of thin films (11 papers), Magnetic Properties and Applications (8 papers) and Physics of Superconductivity and Magnetism (5 papers). J. C. Eckert is often cited by papers focused on Magnetic properties of thin films (11 papers), Magnetic Properties and Applications (8 papers) and Physics of Superconductivity and Magnetism (5 papers). J. C. Eckert collaborates with scholars based in United States and China. J. C. Eckert's co-authors include N. P. Ong, S. K. Khanna, R. B. Somoano, Jason W. Savage, J. W. Brill, J. G. Checkelsky, J. W. Brill, Jason W. Savage, Lan Wang and Koichiro Umemoto and has published in prestigious journals such as Physical Review Letters, Angewandte Chemie International Edition and Physical review. B, Condensed matter.

In The Last Decade

J. C. Eckert

20 papers receiving 388 citations

Peers — A (Enhanced Table)

Peers by citation overlap · career bar shows stage (early→late) cites · hero ref

Name h Career Trend Papers Cites
J. C. Eckert United States 9 316 169 167 148 111 21 409
I. R. Mukhamedshin Russia 10 245 0.8× 284 1.7× 186 1.1× 59 0.4× 66 0.6× 31 411
Shuji Ebisu Japan 14 390 1.2× 314 1.9× 302 1.8× 77 0.5× 119 1.1× 38 588
V. I. Kamenev Ukraine 13 485 1.5× 256 1.5× 267 1.6× 82 0.6× 68 0.6× 47 580
Q. Cai United States 9 246 0.8× 121 0.7× 166 1.0× 130 0.9× 58 0.5× 15 392
Makoto Maki Japan 14 296 0.9× 288 1.7× 177 1.1× 149 1.0× 92 0.8× 43 494
T.M. de Pascale Italy 5 146 0.5× 175 1.0× 175 1.0× 113 0.8× 118 1.1× 13 357
J. Ostoréro France 11 182 0.6× 89 0.5× 188 1.1× 130 0.9× 198 1.8× 53 374
S. Mathi Jaya India 13 275 0.9× 291 1.7× 276 1.7× 127 0.9× 90 0.8× 45 532
D. C. Khan India 10 351 1.1× 117 0.7× 358 2.1× 126 0.9× 130 1.2× 32 493
T. M. Pekarek United States 14 219 0.7× 152 0.9× 353 2.1× 158 1.1× 199 1.8× 48 484

Countries citing papers authored by J. C. Eckert

Since Specialization
Citations

This map shows the geographic impact of J. C. Eckert's research. It shows the number of citations coming from papers published by authors working in each country. You can also color the map by specialization and compare the number of citations received by J. C. Eckert with the expected number of citations based on a country's size and research output (numbers larger than one mean the country cites J. C. Eckert more than expected).

Fields of papers citing papers by J. C. Eckert

Since Specialization
Physical SciencesHealth SciencesLife SciencesSocial Sciences

This network shows the impact of papers produced by J. C. Eckert. Nodes represent research fields, and links connect fields that are likely to share authors. Colored nodes show fields that tend to cite the papers produced by J. C. Eckert. The network helps show where J. C. Eckert may publish in the future.

Co-authorship network of co-authors of J. C. Eckert

This figure shows the co-authorship network connecting the top 25 collaborators of J. C. Eckert. A scholar is included among the top collaborators of J. C. Eckert based on the total number of citations received by their joint publications. Widths of edges represent the number of papers authors have co-authored together. Node borders signify the number of papers an author published with J. C. Eckert. J. C. Eckert is excluded from the visualization to improve readability, since they are connected to all nodes in the network.

All Works

20 of 20 papers shown
1.
Owczarek, Magdalena, Minseong Lee, Shuanglong Liu, et al.. (2022). Near‐Room‐Temperature Magnetoelectric Coupling via Spin Crossover in an Iron(II) Complex. Angewandte Chemie. 134(52).
2.
Owczarek, Magdalena, Minseong Lee, Shuanglong Liu, et al.. (2022). Near‐Room‐Temperature Magnetoelectric Coupling via Spin Crossover in an Iron(II) Complex. Angewandte Chemie International Edition. 61(52). e202214335–e202214335. 16 indexed citations
3.
Ding, X. X., Bin Gao, Charles Dawson, et al.. (2019). Magnetic properties of double perovskite Ln2CoIrO6 (Ln=Eu, Tb, Ho): Hetero-tri-spin 3d5d4f systems. Physical review. B.. 99(1). 20 indexed citations
4.
Watson, Shannon, et al.. (2008). Thickness of the pinned layer as a controlling factor in domain wall formation during training in IrMn-based spin valves. Journal of Applied Physics. 103(7). 1 indexed citations
5.
Moyerman, S., J. C. Eckert, J. A. Borchers, et al.. (2006). Magnetic structure variations during giant magnetoresistance training in spin valves with picoscale antiferromagnetic layers. Journal of Applied Physics. 99(8). 8 indexed citations
6.
Moyerman, S., Will Gannett, J. A. Borchers, et al.. (2006). Ferromagnetic Relaxation in Spin Valves With Picoscale Antiferromagnetic Layers. IEEE Transactions on Magnetics. 42(10). 2630–2632. 1 indexed citations
7.
Wang, Lan, T. Y. Chen, C. L. Chien, et al.. (2006). Composition controlled spin polarization inCo1xFexS2: Electronic, magnetic, and thermodynamic properties. Physical Review B. 73(14). 37 indexed citations
8.
Wang, Lan, Koichiro Umemoto, Renata M. Wentzcovitch, et al.. (2005). Co1xFexS2: A Tunable Source of Highly Spin-Polarized Electrons. Physical Review Letters. 94(5). 56602–56602. 73 indexed citations
9.
Perdue, Katherine L., et al.. (2005). Exchange bias and giant magnetoresistance in spin valves with Angstro/spl uml/m-scale antiferromagnetic Layers at 5 K. IEEE Transactions on Magnetics. 41(10). 2706–2708. 5 indexed citations
10.
Stern, Nathaniel P., et al.. (2004). Stripe domains and magnetoresistance in thermally deposited nickel films. Journal of Magnetism and Magnetic Materials. 272-276. E1339–E1340. 7 indexed citations
11.
Snowden, D., et al.. (2004). Magnetic Resistivity Measurements in Nickel Films for CIW and CPW Domain Geometries. IEEE Transactions on Magnetics. 40(4). 2242–2244. 1 indexed citations
12.
Eckert, J. C., et al.. (2003). Properties of thin IrMn in exchange biased multilayers. Journal of Applied Physics. 93(10). 6608–6610. 7 indexed citations
13.
Eckert, J. C., et al.. (2002). Low temperature properties of spin valves with extremely thin IrMn. Journal of Applied Physics. 91(10). 8569–8571. 5 indexed citations
14.
Ong, N. P., et al.. (1986). Sliding Conductivity without Voltage Oscillations in Niobium Triselenide. Physical Review Letters. 56(11). 1206–1209. 6 indexed citations
15.
Ong, N. P., et al.. (1984). Quantized voltage jumps observed in the charge-density-wave conduction noise inTaS3. Physical review. B, Condensed matter. 30(5). 2902–2905. 16 indexed citations
16.
Verma, G., N. P. Ong, S. K. Khanna, J. C. Eckert, & Jason W. Savage. (1983). Microwave dielectric constant of tantulum trisulfide and niobium trisulfide. Physical review. B, Condensed matter. 28(2). 910–914. 4 indexed citations
17.
Ong, N. P., G. X. Tessema, G. Verma, et al.. (1982). Microwave and Hall Studies of TaS3 and NbS3. Molecular crystals and liquid crystals. 81(1). 41–47. 7 indexed citations
18.
Brill, J. W., N. P. Ong, J. C. Eckert, et al.. (1981). Impurity effect on the Fröhlich conductivity in NbSe3. Physical review. B, Condensed matter. 23(4). 1517–1526. 95 indexed citations
19.
Chaikin, P. M., W. W. Fuller, R.C. Lacoe, et al.. (1981). Thermopower of doped and damaged NbSe3. Solid State Communications. 39(4). 553–557. 22 indexed citations
20.
Ong, N. P., J. W. Brill, J. C. Eckert, et al.. (1979). Effect of Impurities on the Anomalous Transport Properties of NbSe3. Physical Review Letters. 42(12). 811–814. 75 indexed citations

Rankless uses publication and citation data sourced from OpenAlex, an open and comprehensive bibliographic database. While OpenAlex provides broad and valuable coverage of the global research landscape, it—like all bibliographic datasets—has inherent limitations. These include incomplete records, variations in author disambiguation, differences in journal indexing, and delays in data updates. As a result, some metrics and network relationships displayed in Rankless may not fully capture the entirety of a scholar's output or impact.

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