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摘要

随着可穿戴电子产品要求提升, 无毒的有机钙钛矿铁电体成为潜在候选材料. 本工作应用第一性原理计算系统研究了无铅有机钙钛矿 A-NH ₄-(PF ₆) ₃( A= MDABCO, CNDABCO, ODABCO, NODABCO, SHDABCO)的电子态密度、自发极化、弹性特性和压电效应. 通过分子动力学和结合能计算发现, 有机钙钛矿在室温下具有稳定性且预测其在实验上易于合成. 对电子态密度研究发现, A-NH ₄-(PF ₆) ₃的价带主要来自F元素的贡献, 价带顶和导带底分别来自取代基团中的元素和N元素的贡献, 因此有利于电子-空穴对的分离. 依据Born稳定性判据, 有机钙钛矿具有稳定的机械性质. 除此之外, A位有机阳离子的取代基团可以改变材料中氢键的数量, 对总铁电极化的贡献有着明显影响. 最后通过压电性能计算, 揭示了有机钙钛矿具有良好的压电效果, 该效应源于材料引入的有机阳离子增加的材料的柔性. 计算结果为后续实验提供了理论基础.

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Abstract

Organic ferroelectrics are desirable for the applications in the field of wearable electronics due to their eco-friendly process-ability, mechanical flexibility, low processing temperatures, and lightweight. In this work, we use five organic groups as substitution for organic cation and study the effects of organic cations on the structural stability, electronic structure, mechanical properties and spontaneous polarization of metal-free perovskite A-NH ₄-(PF ₆) ₃( A= MDABCO, CNDABCO, ODABCO, NODABCO, SHDABCO) through first-principles calculations. Firstly, the stabilities of the five materials are calculated by molecular dynamics simulations, and the energy values of all systems are negative and stable after 500 fs, which demonstrates the stabilities of the five materials at 300 K. The electronic structure calculation shows that the organic perovskite materials have wide band gap with a value of about 7.05 eV. The valence band maximum (VBM) and Cconduction band minimum (CBM) are occupied by different elements, which is conductive to the separation of electrons and holes. We find that organic cations have an important contribution to the spontaneous polarization of materials, with a contribution rate over 50%. The presence of hydrogen atoms in the substituting groups (MDABCO, ODABCO) enhances the hydrogen bond interaction between the organic cations and ${\rm PF}_6^- $ and increases the displacement of the organic cation, resulting in an increase in the contribution of the polarization of the organic cation to the total polarization. In addition, we observe large piezoelectric strain components, the calculated value of d ₃₃is 36.5 pC/N for CNDABCO-NH ₄-(PF ₆) ₃, 32.3 pC/N for SHNDABCO-NH ₄-(PF ₆) ₃, which is larger than the known value of d ₃₃of MDABCO-NH ₄-I ₃(14pC/N). The calculated value of d ₁₄is 57.5 pC/N for ODABCO-NH ₄-(PF ₆) ₃, 27.5 pC/N for NODABCO-NH ₄-(PF ₆) ₃. These components are at a high level among known organic perovskite materials and comparable to many known inorganic crystals. The large value of d ₁₄is found to be closely related to the large value of elastic compliance tensor s ₄₄. The analysis of Young’s modulus and bulk’s modulus shows that these organic perovskite materials have good ductility. These results indicate that these organic materials are excellent candidates for future environmentally friendly piezoelectric materials.

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作者及机构信息

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通信作者:刘卫芳,wfliu@tju.edu.cn

基金项目:国家自然科学基金(批准号: 51572193)资助的课题.

Authors and contacts

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Corresponding author:Liu Wei-Fang,wfliu@tju.edu.cn

Funds:Project support by the National Natural Science Foundation of China (Grant No. 51572193).

文章全文: translate this paragraph

参考文献

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施引文献

下载: 全尺寸图片幻灯片

Material	Method	a/Å	α/(°)	V/Å³
MDABCO-NP₃	PBE	7.89(0.57%)	84.91(0.06%)	485.51
	PBE+D3	7.73(–1.46%)	84.55(–0.36%)	478.25
	Exp	7.84	84.86	496.46
SHDABCO-NP₃	PBE	7.93	83.84	489.86
SHDABCO-NP₃	PBE+D3	7.74	83.18	483.46
NODABCO-NP₃	PBE	7.95	83.74	493.15
NODABCO-NP₃	PBE+D3	7.84	81.25	485.65
ODABCO-NP₃	PBE	7.85	85.2	478.75
ODABCO-NP₃	PBE+D3	7.75	83.65	475.21
CNDABCO-NP₃	PBE	10.58	85.21	477.19
CNDABCO-NP₃	PBE+D3	9.28	83.48	486.48

下载: 导出CSV

Materials	P_A	P_S	P_A/P_S
SHDABCO-NP₃	2.4	3.8	0.64
NODABCO-NP₃	2.6	4.2	0.63
ODABCO-NP₃	4.3	6.0	0.71
MDABCO-NP₃	4.3	6.3	0.68
CNDABCO-NP₃	5.7	9.4	0.61

下载: 导出CSV

Materials	C₁₁	C₃₃	C₄₄	C₁₂	C₁₃	C₁₄	C₂₅	B	G	E	B/G	ν
MDABCO-NP₃	32.9	15.9	8.2	15.9	16.3	0.8	0.1	21.4	8.2	21.8	2.6	0.3
ODABCO-NP₃	21.9	7.2	6.7	7.2	14.4	0.2	0.4	18.4	3.6	10.2	2.8	0.3
CNDABCO-NP₃	35.2	19.4	6.6	19.4	22.8	0.6	1.3	25.7	6.7	18.4	4.0	0.4
SHDABCO-NP₃	32.4	21.8	8.6	21.8	24.1	4.8	4.4	25.9	7.3	20.1	4.1	0.4
NODABCO-NP₃	36.2	19.7	4.4	19.7	19.7	0.3	0.4	25.0	5.9	16.5	4.5	0.4

下载: 导出CSV

Materials	d₃₃/(pC·N^–1)
ZnS^[41]	3.2
LiNbO₃, LN^[42]	6.0
CdS^[43]	10.3
ZnO^[44]	12.4
MDABCO-NI₃^[19]	14.4
CNDABCO-NP₃	36.5
SHDABCO-NP₃	32.3

下载: 导出CSV

Materials	d₁₄/(pC·N^–1)
NaClO₃^[45]	1.7
La₃Ga_5.5Ta_0.5O₁₄, LGT^[46]	5.0
GaN^[47]	6.4
AlN^[47]	9.7
Ca₃TaGa₃Si₂O₁₄, CTGS^[48]	24.3
MDABCO-NP₃	6.3
NODABCO-NP₃	27.5
ODABCO-NP₃	57.5

下载: 导出CSV

Materials	d₁₁	d₂₂	d₃₃	d₁₄	d₁₅	d₃₁
MDABCO-NP₃	–2.9	–2.6	2.0	–6.3	–1.0	3.0
ODABCO-NP₃	–5.5	–0.9	7.4	–57.5	–28.9	0.9
CNDABCO-NP₃	–1.3	–2.7	36.5	–7.9	–1.6	17.0
SHDABCO-NP₃	–18.2	–20.9	32.3	–10.6	–41.6	27.2
NODABCO-NP₃	–0.8	–0.4	7.1	27.5	–21.8	6.18

下载: 导出CSV

Materials	e₁₁	e₂₂	e₃₃	e₁₄	e₁₅	e₃₁
MDABCO-NP₃	–3.5	–3.0	2.4	4.5	–0.6	4.9
ODABCO-NP₃	–2.1	–0.5	3.5	8.1	–1.7	9.9
CNDABCO-NP₃	–1.9	–4.7	34.7	4.7	–0.8	9.7
SHDABCO-NP₃	–5.2	–6.6	7.3	4.3	–21.9	6.5
NODABCO-NP₃	–1.6	–0.5	10.5	8.9	–10.7	16.8

下载: 导出CSV

Materials	s₁₁	s₃₃	s₄₄	s₁₂	s₁₃	s₁₄	s₂₅
MDABCO-NP₃	48.8	49.8	130.3	–16.8	–16.7	3.2	0.6
ODABCO-NP₃	38.4	57.2	247.3	–9.0	–17.6	18	45.5
CNDABCO-NP₃	56.9	85.4	157.3	–8.8	–35.7	–5.5	13.3
SHDABCO-NP₃	124.7	142.4	218.9	–37.0	–79.2	–60.1	5.0
NODABCO-NP₃	46.8	51.2	199.0	–16.6	–17.2	17.1	19.9

下载: 导出CSV

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