Ethacridine lactate additive engineering for defect passivation in HTL-free carbon electrode perovskite solar cells

Anita Achiamaa Bonsu; Wenyan Zhao; Cailong Zhang; Yumin Liu; Yanna Xu; Chuanjin Tian; Shaojian Fu; Chang-an Wang; Zhipeng Xie

doi:10.1007/s11706-026-0774-z

Front. Mater. Sci. ›› 2026, Vol. 20 ›› Issue (2) :260774 DOI: 10.1007/s11706-026-0774-z

RESEARCH ARTICLE

Ethacridine lactate additive engineering for defect passivation in HTL-free carbon electrode perovskite solar cells

Author information +

History +

PDF (4763KB)

Abstract

Hole-transport-layer (HTL)-free carbon electrode perovskite solar cells (C-PSCs) are promising candidates for low-cost photovoltaic applications, but their performance is still limited by defect-induced recombination and insufficient long-term stability. Herein, ethacridine lactate (EAL) is employed as a multifunctional additive in the perovskite precursor solution to regulate film quality and interfacial properties. Owing to the presence of a carboxyl group in the lactate anion and two amino groups in the ethacridine cation, EAL interacts with undercoordinated Pb²⁺ and dangling I⁻ species, which stabilizes the perovskite structure and promotes charge transport across the perovskite/carbon interface. Consequently, the EAL-modified films show improved morphology and reduced defect density, resulting in enhanced photovoltaic performance. The optimized device delivers a power conversion efficiency of 16.54% and retains 80% of its initial efficiency after 1200 h without encapsulation. This work highlights an effective additive-engineering strategy for achieving efficient and stable HTL-free carbon electrode PSCs.

Graphical abstract

Keywords

HTL-free carbon electrode perovskite solar cells / ethacridine lactate / additive engineering / defect passivation / stability

Cite this article

Download citation ▾

Anita Achiamaa Bonsu, Wenyan Zhao, Cailong Zhang, Yumin Liu, Yanna Xu, Chuanjin Tian, Shaojian Fu, Chang-an Wang, Zhipeng Xie. Ethacridine lactate additive engineering for defect passivation in HTL-free carbon electrode perovskite solar cells. Front. Mater. Sci., 2026, 20(2): 260774 DOI:10.1007/s11706-026-0774-z

登录浏览全文

4963

注册一个新账户忘记密码

References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	Stoppato A . Life cycle assessment of photovoltaic electricity generation.Energy, 2008, 33(2): 224–232

[2]	Placzek-Popko E . Top PV market solar cells 2016.Opto-Electronics Review, 2017, 25(2): 55–64

[3]	Green M A, Emery K, Hishikawa Y, et al. Solar cell efficiency tables (version 40).Progress in Photovoltaics: Research and Applications, 2012, 20(5): 606–614

[4]	Elumalai N K, Mahmud M A, Wang D, et al. Perovskite solar cells: progress and advancements.Energies, 2016, 9(11): 861

[5]	Zhang Y, Kirs A, Ambroz F, et al. Ambient fabrication of organic–inorganic hybrid perovskite solar cells.Small Methods, 2021, 5(1): 2000744

[6]	Kojima A, Teshima K, Shirai Y, et al. Organometal halide perovskites as visible-light sensitizers for photovoltaic cells.Journal of the American Chemical Society, 2009, 131(17): 6050–6051

[7]	National Laboratory of the Rockies . Best research-cell efficiencies.Chart from the website of the National Laboratory of the Rockies, 2026,

[8]	Lee J, Kang H, Kim G, et al. Achieving large-area planar perovskite solar cells by introducing an interfacial compatibilizer.Advanced Materials, 2017, 29(22): 1606363

[9]	Cheng Y, Li H W, Qing J, et al. The detrimental effect of excess mobile ions in planar CH₃NH₃PbI₃ perovskite solar cells.Journal of Materials Chemistry A: Materials for Energy and Sustainability, 2016, 4(33): 12748–12755

[10]	Zhang T K, Wang F, Kim H B, et al. Ion-modulated radical doping of spiro-OMeTAD for more efficient and stable perovskite solar cells.Science, 2022, 377(6605): 495–501

[11]	Zouhair S, Clegg C, Valitova I, et al. Carbon electrodes for perovskite photovoltaics: interfacial properties, meta-analysis, and prospects.Solar RRL, 2024, 8(6): 2300929

[12]	Pourjafari D, García-Peña N G, Padron-Hernandez W Y, et al. Functional materials for fabrication of carbon-based perovskite solar cells: ink formulation and its effect on solar cell performance.Materials, 2023, 16(11): 3917

[13]	Wang Y D, Li W R, Yin Y F, et al. Defective MWCNT enabled dual interface coupling for carbon-based perovskite solar cells with efficiency exceeding 22%.Advanced Functional Materials, 2022, 32(31): 2204831

[14]	Du T, Qiu S D, Zhou X, et al. Efficient, stable, and fully printed carbon-electrode perovskite solar cells enabled by hole-transporting bilayers.Joule, 2023, 7(8): 1920–1937

[15]	Bogachuk D, Zouhair S, Wojciechowski K, et al. Low-temperature carbon-based electrodes in perovskite solar cells.Energy & Environmental Science, 2020, 13(11): 3880–3916

[16]	Ju Z Y, Zhao W Y, Wu J H, et al. Multifunctional ionic liquid boosts the efficiency of hole transport layer-free carbon-based perovskite solar cells beyond 20%.FlexMat, 2026, 3(1): 78–92

[17]	Lei Y C, Zhang Y F, Huo J L, et al. Stability strategies and applications of iodide perovskites.Small, 2024, 20(29): 2311880

[18]	Elangovan N K, Kannadasan R, Beenarani B B, et al. Recent developments in perovskite materials, fabrication techniques, band gap engineering, and the stability of perovskite solar cells.Energy Reports, 2024, 11: 1171–1190

[19]	Gao D Y, Li R, Chen X H, et al. Managing interfacial defects and carriers by synergistic modulation of functional groups and spatial conformation for high-performance perovskite photovoltaics based on vacuum flash method.Advanced Materials, 2023, 35(23): 2301028

[20]	Liu Z Y, Liu T X, Li M, et al. Eliminating halogen vacancies enables efficient MACL-assisted formamidine perovskite solar cells.Advanced Science, 2024, 11(7): 2306280

[21]	Yuan Y B, Huang J S . Ion migration in organometal trihalide perovskite and its impact on photovoltaic efficiency and stability.Accounts of Chemical Research, 2016, 49(2): 286–293

[22]	Chen H N, Yang S H . Carbon-based perovskite solar cells without hole transport materials: the front runner to the market?.Advanced Materials, 2017, 29(24): 1603994

[23]	Li L C, Rao H S, Wu Z J, et al. Moisture induced secondary crystal growth boosting the efficiency of hole transport layer-free carbon-based perovskite solar cells beyond 19.5%.Advanced Functional Materials, 2024, 34(1): 2308428

[24]	Jiao B X, Che Z G, Quan Z W, et al. Highly efficient and stable perovskite solar cells: competitive crystallization strategy and synergistic passivation.Small, 2023, 19(35): 2301630

[25]	Zhao Y, Ma F, Qu Z H, et al. Inactive (PbI₂)₂RbCl stabilizes perovskite films for efficient solar cells.Science, 2022, 377(6605): 531–534

[26]	Shen S M, Zhao W Y, Liu Y M, et al. Carbon-based hole transport layer-free perovskite solar cells with an efficiency beyond 18% boosted by a methylammonium chloride additive.ACS Applied Materials & Interfaces, 2025, 17(8): 12189–12198

[27]	Li T X, Li W, Wang K, et al. Ambient air processed inverted inorganic perovskite solar cells with over 21% efficiency enabled by multifunctional ethacridine lactate.Angewandte Chemie International Edition, 2024, 63(36): e202407508

[28]	Zhang J F, Jiang X Q, Liu X T, et al. Maximizing merits of undesirable δ-FAPbI₃ by constructing yellow/black heterophase bilayer for efficient and stable perovskite photovoltaics.Advanced Functional Materials, 2022, 32(44): 2204642

[29]	Saliba M, Matsui T, Seo J Y, et al. Cesium-containing triple cation perovskite solar cells: improved stability, reproducibility and high efficiency.Energy & Environmental Science, 2016, 9(6): 1989–1997

[30]	Xiang J W, Cheng Y J, Zhang G D, et al. Efficient carbon-based hole-conductor-free printable mesoscopic perovskite solar cells via a multifunctional fluorinated molecule.Advanced Functional Materials, 2024, 34(38): 2402816

[31]	Abbas M, Xu X, Rauf M, et al. A comprehensive review on defects-induced voltage losses and strategies toward highly efficient and stable perovskite solar cells.Photonics, 2024, 11(1): 87