Fig. 2 Magnetic field induced transitions in the lowest temperature (1

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Fig. 2 Magnetic field induced transitions in the lowest temperature (1 Fig. 2 Magnetic field induced transitions in the lowest temperature (1.5 K) after quenching. Magnetic field induced transitions in the lowest temperature (1.5 K) after quenching. (A) Magnetic field dependence of integrated intensity of the magnetic reflections measured in the H || ki configuration after quenching at 0.2 T with increasing and decreasing fields and (B) measured with increasing magnetic field after reaching the square SkL state in zero field. (C) Field dependence of average values of peak position in q measured in the H || ki configuration at 1.5 K. Filled and open symbols denote data measured with increasing and decreasing field, respectively. Gray data points in (B) are the data shown in (A). (D) Hall resistivity data redrawn from fig. S3a in the Supplementary Materials of the study by Oike et al. (23). Expected square SkL contribution in Hall resistivity is highlighted in pink. Slight discrepancies in transition fields are due to differences in temperature and demagnetizing effect. (E to H) Azimuthal angle profiles of the annular-averaged intensities measured at (E) 0.2 T, (F) 0.08 T, and (G) 0 T with decreasing field and at (H) 0.2 T with increasing field from 0 T. (I to P) The SANS patterns measured in the H || ki and H ⊥ ki configurations at the selected magnetic fields. In (K), (L), and (O), the intensities (I) are multiplied by factors of 3, 3, and 10, respectively, to enhance clarity. Taro Nakajima et al. Sci Adv 2017;3:e1602562 Copyright © 2017, The Authors