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. 2025 Mar 11;5(5):2400508.
doi: 10.1002/smsc.202400508. eCollection 2025 May.

Methylhydrazine Lone-Pair Engineering for Polar Lead-Free Perovskite Enables Self-Powered X-Ray Detection

Ruiqing Li  1   2   3 Jianbo Wu  1 Zeng-Kui Zhu  1 Yaru Geng  1 Xinling Li  1 Yifei Wang  1 Bohui Xu  3   4 Zheshuai Lin  3   4 Junhua Luo  1   3
Affiliations

Methylhydrazine Lone-Pair Engineering for Polar Lead-Free Perovskite Enables Self-Powered X-Ray Detection

Ruiqing Li et al. Small Sci. .

Abstract

Lead-free A3Bi2I9-type perovskites demonstrate excellent performance in direct X-ray detection owing to their high bulk resistivity and reduced ion migration. However, the reported centrosymmetric A3Bi2I9 can only operate with external voltage, inevitably resulting in energy consumption and bulky monolithic circuits, limiting their further development. Herein, exploiting the methylhydrazine (MHy) cation with 2s 2 lone-pair electrons (LPEs), a chiral-polarity perovskite MHy3Bi2I9 are obtained and explored its self-powered X-ray detection properties. Where MHy forms the strong hydrogen bond interaction with the inorganic framework, resulting in the asymmetric Bi2I9 unit. Meanwhile, the 2s 2 LPEs contribute to generating MHy dipole moments, leading to spontaneous polarization. On the one hand, spontaneous polarization acts as a driving force to realize the X-ray-generated carriers' separation and transport to acquire self-powered detection ability. On the other hand, the reduced noise current and dark current under zero bias further increase the signal-to-noise ratio and lower the detection limit. Notably, the MHy3Bi2I9 single-crystal-based detector displays a considerable sensitivity (106 μC Gy-1 cm-2) and an ultralow detection limit (55 nGy s-1) in self-powered mode. Herein, new insights for constructing polar lead-free perovskite and realizing unprecedented A3Bi2I9-type self-powered X-ray detectors are provided.

Keywords: lead‐free; lone‐pair engineering; low detection limit; polar A3Bi2I9‐type perovskite; self‐powered X‐ray detection.

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Conflict of interest statement

The authors declare no conflict of interest.

Figures

Figure 1
Figure 1
a) The crystal structure of typical A‐cation (Cs, MA, and FA) in A3Bi2I9‐type perovskite. b) The MHy cation with 2s 2 lone‐pair electrons. The room‐temperature crystal structure of c) Cs3Bi2I9, d) MA3Bi2I9, and e) FA3Bi2I9, which crystalized in the centrosymmetric space group P63/mmc. f) Exploiting the MHy as A‐cation, MHy3Bi2I9 possesses a strong hydrogen bond interaction and crystalizes in the chiral‐polar space group P61 at room temperature. The dotted line refers to the hydrogen bond length between the adjacent layers.
Figure 2
Figure 2
a) The Hirshfeld surface of the Bi2I9 unit in MHy3Bi2I9. b,c) The fingerprint plots of MHy3Bi2I9 indicate the strong hydrogen bond interaction. The inorganic unit of d) MHy3Bi2I9, and e) Cs3Bi2I9, MA3Bi2I9, and FA3Bi2I9. The gray arrows represent the direction of the BiI6 dipole moment. The red arrow in MHy3Bi2I9 refers to the direction of Bi2I9 net dipole moment, which points to the c‐axis.
Figure 3
Figure 3
a) The 6‐fold roto‐inversion operation of MHy. H atoms are omitted for clarity. b) In the unit cell, the MHy dipole moment (light‐red arrow) contributes to the spontaneous polarization (P s, red arrow) along the c‐axis.
Figure 4
Figure 4
a) The thermogravimetric analysis experiment of MHy3Bi2I9. b) The second harmonic generation (SHG) test of MHy3Bi2I9 and KH2PO4. c) Piezoelectric measurement and the corresponding d 33 value. d) The temperature‐dependent pyroelectricity current and polarization curves.
Figure 5
Figure 5
a) The absorption coefficient of MHy3Bi2I9, Cs3Bi2I9, MA3Bi2I9, and Si as a function of X‐ray photon energy. b) Attenuation efficiency versus thickness curves of MHy3Bi2I9, Cs3Bi2I9, MA3Bi2I9, and Si. c) IV curves of MHy3Bi2I9 SC‐based detector in the dark and under X‐ray irradiation. d) The photo‐responses of the MHy3Bi2I9 SC‐based detector under increased X‐ray dose rate at 454 V mm−1 electric field (top) and 0 V bias (bottom). e) Under different external fields, the current density as a function of the X‐ray dose rate, and the slope of fitting lines corresponding to the sensitivity. f) The SNR of MHy3Bi2I9 SC‐based detector under 0 V and 454 V mm−1 electric field. g) The current response cycle of the detector under a low X‐ray dose rate to verify the reliability of the detection limit. h) The photocurrent of the detector under continuous X‐ray irradiation indicates its remarkable irradiation stability. i) The comparison of sensitivity and detection limit between MHy3Bi2I9 and other lead‐free detectors.
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