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1. Allo: A Programming Model for Composable Accelerator Design

Author

Chen, Hongzheng, Zhang, Niansong, Xiang, Shaojie, Zeng, Zhichen, Dai, Mengjia, and Zhang, Zhiru

Subjects
Computer Science - Programming Languages, Computer Science - Hardware Architecture, Computer Science - Machine Learning
Abstract

Special-purpose hardware accelerators are increasingly pivotal for sustaining performance improvements in emerging applications, especially as the benefits of technology scaling continue to diminish. However, designers currently lack effective tools and methodologies to construct complex, high-performance accelerator architectures in a productive manner. Existing high-level synthesis (HLS) tools often require intrusive source-level changes to attain satisfactory quality of results. Despite the introduction of several new accelerator design languages (ADLs) aiming to enhance or replace HLS, their advantages are more evident in relatively simple applications with a single kernel. Existing ADLs prove less effective for realistic hierarchical designs with multiple kernels, even if the design hierarchy is flattened. In this paper, we introduce Allo, a composable programming model for efficient spatial accelerator design. Allo decouples hardware customizations, including compute, memory, communication, and data type from algorithm specification, and encapsulates them as a set of customization primitives. Allo preserves the hierarchical structure of an input program by combining customizations from different functions in a bottom-up, type-safe manner. This approach facilitates holistic optimizations that span across function boundaries. We conduct comprehensive experiments on commonly-used HLS benchmarks and several realistic deep learning models. Our evaluation shows that Allo can outperform state-of-the-art HLS tools and ADLs on all test cases in the PolyBench. For the GPT2 model, the inference latency of the Allo generated accelerator is 1.7x faster than the NVIDIA A100 GPU with 5.4x higher energy efficiency, demonstrating the capability of Allo to handle large-scale designs., Comment: Accepted to PLDI'24

Published
2024
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2. Understanding the Potential of FPGA-Based Spatial Acceleration for Large Language Model Inference

Author

Chen, Hongzheng, Zhang, Jiahao, Du, Yixiao, Xiang, Shaojie, Yue, Zichao, Zhang, Niansong, Cai, Yaohui, and Zhang, Zhiru

Subjects
Computer Science - Machine Learning, Computer Science - Artificial Intelligence, Computer Science - Hardware Architecture, Computer Science - Computation and Language
Abstract

Recent advancements in large language models (LLMs) boasting billions of parameters have generated a significant demand for efficient deployment in inference workloads. The majority of existing approaches rely on temporal architectures that reuse hardware units for different network layers and operators. However, these methods often encounter challenges in achieving low latency due to considerable memory access overhead. This paper investigates the feasibility and potential of model-specific spatial acceleration for LLM inference on FPGAs. Our approach involves the specialization of distinct hardware units for specific operators or layers, facilitating direct communication between them through a dataflow architecture while minimizing off-chip memory accesses. We introduce a comprehensive analytical model for estimating the performance of a spatial LLM accelerator, taking into account the on-chip compute and memory resources available on an FPGA. Through our analysis, we can determine the scenarios in which FPGA-based spatial acceleration can outperform its GPU-based counterpart. To enable more productive implementations of an LLM model on FPGAs, we further provide a library of high-level synthesis (HLS) kernels that are composable and reusable. This library will be made available as open-source. To validate the effectiveness of both our analytical model and HLS library, we have implemented BERT and GPT2 on an AMD Alveo U280 FPGA device. Experimental results demonstrate our approach can achieve up to 13.4x speedup when compared to previous FPGA-based accelerators for the BERT model. For GPT generative inference, we attain a 2.2x speedup compared to DFX, an FPGA overlay, in the prefill stage, while achieving a 1.9x speedup and a 5.7x improvement in energy efficiency compared to the NVIDIA A100 GPU in the decode stage., Comment: Accepted for publication in the FCCM'24 Journal Track and will appear in ACM Transactions on Reconfigurable Technology and Systems (TRETS)

Published
2023
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4. Slapo: A Schedule Language for Progressive Optimization of Large Deep Learning Model Training

Author

Chen, Hongzheng, Yu, Cody Hao, Zheng, Shuai, Zhang, Zhen, Zhang, Zhiru, and Wang, Yida

Subjects
Computer Science - Machine Learning
Abstract

Recent years have seen an increase in the development of large deep learning (DL) models, which makes training efficiency crucial. Common practice is struggling with the trade-off between usability and performance. On one hand, DL frameworks such as PyTorch use dynamic graphs to facilitate model developers at a price of sub-optimal model training performance. On the other hand, practitioners propose various approaches to improving the training efficiency by sacrificing some of the flexibility, ranging from making the graph static for more thorough optimization (e.g., XLA) to customizing optimization towards large-scale distributed training (e.g., DeepSpeed and Megatron-LM). In this paper, we aim to address the tension between usability and training efficiency through separation of concerns. Inspired by DL compilers that decouple the platform-specific optimizations of a tensor-level operator from its arithmetic definition, this paper proposes a schedule language, Slapo, to decouple model execution from definition. Specifically, Slapo works on a PyTorch model and uses a set of schedule primitives to convert the model for common model training optimizations such as high-performance kernels, effective 3D parallelism, and efficient activation checkpointing. Compared to existing optimization solutions, Slapo progressively optimizes the model "as-needed" through high-level primitives, and thus preserving programmability and debuggability for users to a large extent. Our evaluation results show that by scheduling the existing hand-crafted optimizations in a systematic way using Slapo, we are able to improve training throughput by up to 2.92x on a single machine with 8 NVIDIA V100 GPUs, and by up to 1.41x on multiple machines with up to 64 GPUs, when compared to the out-of-the-box performance of DeepSpeed and Megatron-LM., Comment: Accepted to ASPLOS'24

Published
2023

5. Structured Pruning is All You Need for Pruning CNNs at Initialization

Author

Cai, Yaohui, Hua, Weizhe, Chen, Hongzheng, Suh, G. Edward, De Sa, Christopher, and Zhang, Zhiru

Subjects
Computer Science - Computer Vision and Pattern Recognition
Abstract

Pruning is a popular technique for reducing the model size and computational cost of convolutional neural networks (CNNs). However, a slow retraining or fine-tuning procedure is often required to recover the accuracy loss caused by pruning. Recently, a new research direction on weight pruning, pruning-at-initialization (PAI), is proposed to directly prune CNNs before training so that fine-tuning or retraining can be avoided. While PAI has shown promising results in reducing the model size, existing approaches rely on fine-grained weight pruning which requires unstructured sparse matrix computation, making it difficult to achieve real speedup in practice unless the sparsity is very high. This work is the first to show that fine-grained weight pruning is in fact not necessary for PAI. Instead, the layerwise compression ratio is the main critical factor to determine the accuracy of a CNN model pruned at initialization. Based on this key observation, we propose PreCropping, a structured hardware-efficient model compression scheme. PreCropping directly compresses the model at the channel level following the layerwise compression ratio. Compared to weight pruning, the proposed scheme is regular and dense in both storage and computation without sacrificing accuracy. In addition, since PreCropping compresses CNNs at initialization, the computational and memory costs of CNNs are reduced for both training and inference on commodity hardware. We empirically demonstrate our approaches on several modern CNN architectures, including ResNet, ShuffleNet, and MobileNet for both CIFAR-10 and ImageNet.

Published
2022

6. BGL: GPU-Efficient GNN Training by Optimizing Graph Data I/O and Preprocessing

Author

Liu, Tianfeng, Chen, Yangrui, Li, Dan, Wu, Chuan, Zhu, Yibo, He, Jun, Peng, Yanghua, Chen, Hongzheng, Chen, Hongzhi, and Guo, Chuanxiong

Subjects
Computer Science - Machine Learning, Computer Science - Distributed, Parallel, and Cluster Computing
Abstract

Graph neural networks (GNNs) have extended the success of deep neural networks (DNNs) to non-Euclidean graph data, achieving ground-breaking performance on various tasks such as node classification and graph property prediction. Nonetheless, existing systems are inefficient to train large graphs with billions of nodes and edges with GPUs. The main bottlenecks are the process of preparing data for GPUs - subgraph sampling and feature retrieving. This paper proposes BGL, a distributed GNN training system designed to address the bottlenecks with a few key ideas. First, we propose a dynamic cache engine to minimize feature retrieving traffic. By a co-design of caching policy and the order of sampling, we find a sweet spot of low overhead and high cache hit ratio. Second, we improve the graph partition algorithm to reduce cross-partition communication during subgraph sampling. Finally, careful resource isolation reduces contention between different data preprocessing stages. Extensive experiments on various GNN models and large graph datasets show that BGL significantly outperforms existing GNN training systems by 20.68x on average., Comment: Under Review

Published
2021

10. Boosting photovoltaic performance of ternary organic solar cells by integrating a multi-functional guest acceptor

Author

Yin, Yuli, Zhan, Lingling, Liu, Ming, Yang, Chongqing, Guo, Fengyun, Liu, Yi, Gao, Shiyong, Zhao, Liancheng, Chen, Hongzheng, and Zhang, Yong

Subjects
Engineering, Macromolecular and Materials Chemistry, Materials Engineering, Chemical Sciences, Affordable and Clean Energy, electron acceptor, ternary organic solar cells, energy transfer, electronic alloy acceptors, 3D phase separation, CSD-46-All CSGB, Nanotechnology, Macromolecular and materials chemistry, Materials engineering
Abstract

Constructing ternary structure is one of the most effective design strategies to break the efficiency ceiling of traditional binary organic solar cells (OSCs). Here, a new Y-series non-fullerene acceptor (Y-T) featuring 1,3-diethyl-2-thiobarbituric acid (DTBA) end groups is developed as a third component for the classical PM6:Y6 binary system. The champion power conversion efficiency of ternary OSCs is increased from 15.64% to 17.37% via incorporating 10 wt% Y-T, with the simultaneously enhanced open-circuit voltage (Voc) of 0.865 V, a short-circuit current density (Jsc) of 26.90 mA/cm2, and a fill factor (FF) of 74.97%. The positive contribution of Y-T in the ternary blend can be ascribed to the improved spectroscopic complementarity and enhanced exciton utilization ratio due to the additional energy transfer process. Moreover, Y-T guest acceptor plays a critical role in adjusting the active layer morphology and facilitating three-dimension phase separation, resulting in a balanced charge transport and enhanced FF of ternary OSCs. This work provides insight into the molecular design of non-fullerene acceptor and suggest guidelines to rationally select guest component for ternary OSCs.

Published
2021

11. FracBNN: Accurate and FPGA-Efficient Binary Neural Networks with Fractional Activations

Author

Zhang, Yichi, Pan, Junhao, Liu, Xinheng, Chen, Hongzheng, Chen, Deming, and Zhang, Zhiru

Subjects
Computer Science - Machine Learning, Computer Science - Computer Vision and Pattern Recognition
Abstract

Binary neural networks (BNNs) have 1-bit weights and activations. Such networks are well suited for FPGAs, as their dominant computations are bitwise arithmetic and the memory requirement is also significantly reduced. However, compared to start-of-the-art compact convolutional neural network (CNN) models, BNNs tend to produce a much lower accuracy on realistic datasets such as ImageNet. In addition, the input layer of BNNs has gradually become a major compute bottleneck, because it is conventionally excluded from binarization to avoid a large accuracy loss. This work proposes FracBNN, which exploits fractional activations to substantially improve the accuracy of BNNs. Specifically, our approach employs a dual-precision activation scheme to compute features with up to two bits, using an additional sparse binary convolution. We further binarize the input layer using a novel thermometer encoding. Overall, FracBNN preserves the key benefits of conventional BNNs, where all convolutional layers are computed in pure binary MAC operations (BMACs). We design an efficient FPGA-based accelerator for our novel BNN model that supports the fractional activations. To evaluate the performance of FracBNN under a resource-constrained scenario, we implement the entire optimized network architecture on an embedded FPGA (Xilinx Ultra96v2). Our experiments on ImageNet show that FracBNN achieves an accuracy comparable to MobileNetV2, surpassing the best-known BNN design on FPGAs with an increase of 28.9% in top-1 accuracy and a 2.5x reduction in model size. FracBNN also outperforms a recently introduced BNN model with an increase of 2.4% in top-1 accuracy while using the same model size. On the embedded FPGA device, FracBNN demonstrates the ability of real-time image classification., Comment: Published at the 29th ACM/SIGDA International Symposium on Field-Programmable Gate Arrays (FPGA 2021)

Published
2020

15. Recent progress in organic solar cells (Part II device engineering)

Author

Liu, Yahui, Liu, Bowen, Ma, Chang-Qi, Huang, Fei, Feng, Guitao, Chen, Hongzheng, Hou, Jianhui, Yan, Lingpeng, Wei, Qingya, Luo, Qun, Bao, Qinye, Ma, Wei, Liu, Wei, Li, Weiwei, Wan, Xiangjian, Hu, Xiaotian, Han, Yanchun, Li, Yaowen, Zhou, Yinhua, Zou, Yingping, Chen, Yiwang, Liu, Yuqiang, Meng, Lei, Li, Yongfang, Chen, Yongsheng, Tang, Zheng, Hu, Zhicheng, Zhang, Zhi-Guo, and Bo, Zhishan

Published
2022
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19. The Multi‐Functional Third Acceptor Realizes the Synergistic Improvement in Photovoltaic Parameters and the High‐Ratio Tolerance of Ternary Organic Photovoltaics.

Author

Liu, Yuhao, Zhan, Lingling, Li, Zhongjie, Jiang, Hang, Qiu, Huayu, Sun, Xiaokang, Hu, Hanlin, Sun, Rui, Min, Jie, Yu, Jinyang, Fu, Weifei, Yin, Shouchun, and Chen, Hongzheng

Subjects
TERNARY system, PHOTOVOLTAIC power generation, HIGH voltages, HALOGENATION, CRYSTALLINITY
Abstract

The ternary strategy proves effective for breakthroughs in organic photovoltaics (OPVs). Elevating three photovoltaic parameters synergistically, especially the proportion‐insensitive third component, is crucial for efficient ternary devices. This work introduces a molecular design strategy by comprehensively analyzing asymmetric end groups, side‐chain engineering, and halogenation to explore the outstanding optoelectronic properties of the proportion‐insensitive third component in efficient ternary systems. Three asymmetric non‐fullerene acceptors (BTP‐SA1, BTP‐SA2, and BTP‐SA3) are synthesized based on the Y6 framework and incorporated as the third component into the D18:Y6 binary system. BTP‐SA3, featuring asymmetric terminal (difluoro‐indone and dichloride‐cyanoindone terminal), with branched alkyl side chains, exhibited high open‐circuit voltage (VOC), balanced crystallinity and compatibility, achieving synergistic enhancements in VOC (0.862 V), short circuit‐current density (JSC, 27.52 mA cm−2), fill fact (FF, 81.01%), and power convert efficiency (PCE, 19.19%). Device based on D18/Y6:BTP‐SA3 (layer‐by‐layer processed) reached a high efficiency of 19.36%, demonstrating a high tolerance for BTP‐SA3 (10–50%). This work provides novel insights into optimizing OPVs performances in multi‐component systems and designing components with enhanced tolerance. [ABSTRACT FROM AUTHOR]

Published
2024
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20. Understanding the Nonradiative Charge Recombination in Organic Photovoltaics: From Molecule to Device.

Author

Kong, Yibo, Chen, Hongzheng, and Zuo, Lijian

Subjects
*SINGLE molecules, *QUANTUM efficiency, *SOLAR cells, *PHOTOVOLTAIC power generation, *HETEROJUNCTIONS
Abstract

Organic photovoltaics (OPVs) have made significant strides with efficiencies now exceeding 20%, positioning them as potential competitors to inorganic solar technologies. One of the most critical challenges toward this goal is the severe open‐circuit voltage (Voc) loss caused by the nonradiative charge recombination (NRCR). Herein, this review comprehensively summarizes the NRCR mechanisms and suppression techniques of OPVs across various scales from molecule to device. Specifically, the origins of NRCR in a single molecule are first summarized, and molecular design principles toward high photoluminescence quantum yield are reviewed following the Marcus theory. Next, the effect of aggregation on NRCR is reviewed, as well as the molecular and processing strategies to modulate the film packing for NRCR suppression. Furthermore, the progresses in the avoidance of nonradiative loss pathways mediated by charge transfer states and triplet states in donor:acceptor bulk heterojunctions are tracked. Besides, the interfacial optimization and device structure design to maximize the electroluminescent quantum efficiency are presented. Finally, several potential pathways toward curtailing NRCR for high‐performance OPVs are outlined. Therefore, this review shows an insightful perspective to understand and mitigate the NRCR at multi‐scales, and is poised to provide a clear roadmap for the next breakthrough of OPVs. [ABSTRACT FROM AUTHOR]

Published
2024
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22. A Novel Thiazole‐Core Spacer Based Dion–Jacobson Perovskite with Type II Quantum Well Structure for Efficient Photovoltaics.

Author

Zhang, Lin, Zhang, Yiqing, Wu, Haotian, Wang, Fei, Yan, Kangrong, Zhou, Ying, Xu, Xiaoyi, Fu, Weifei, Hu, Hanlin, Wu, Gang, Du, Miao, and Chen, Hongzheng

Subjects
PEROVSKITE, MOLECULAR size, SOLAR cells, STRUCTURAL stability, ELECTRONIC structure
Abstract

2D Dion–Jacobson (DJ) perovskites show structural stability and tunability and are regarded as promising photovoltaic materials. The spacer cations play an important impact on exciton separation and charge transport of 2D perovskites. Herein, a novel spacer with thiazole as core, 2‐thiazolemethanammonium (AMT), owning characters of small molecular size, delocalized π‐electrons, and strong electron‐withdrawing ability, is introduced to construct 2D DJ perovskites. Owing to the strong orbital coupling between AMT spacer and inorganic layers, the AMT‐based perovskite exhibits type II quantum well structure, which is favorable for exciton separation. On contrary, such interaction does not appear in the DJ perovskite when aliphatic propyldiammonium (PDA), with a similar length, is used as spacer. The AMT spacer can also induce better crystallinity, resulting in reduced defect density and improved charge transport ability. The optimized device based on (AMT)MA3Pb4I13 exhibits a power conversion efficiency (PCE) of 19.69%, which is a record for 2D DJ perovskite solar cells (PSCs) (n ≤ 4). This work provides deep understanding of the impact of aromatic spacer on the electronic structure of 2D DJ perovskites and the corresponding photovoltaic performance and provides a new opportunity toward highly efficient and stable PSCs. [ABSTRACT FROM AUTHOR]

Published
2024
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23. Recent progress in organic solar cells (Part I material science)

Author

Liu, Yahui, Liu, Bowen, Ma, Chang-Qi, Huang, Fei, Feng, Guitao, Chen, Hongzheng, Hou, Jianhui, Yan, Lingpeng, Wei, Qingya, Luo, Qun, Bao, Qinye, Ma, Wei, Liu, Wei, Li, Weiwei, Wan, Xiangjian, Hu, Xiaotian, Han, Yanchun, Li, Yaowen, Zhou, Yinhua, Zou, Yingping, Chen, Yiwang, Li, Yongfang, Chen, Yongsheng, Tang, Zheng, Hu, Zhicheng, Zhang, Zhi-Guo, and Bo, Zhishan

Published
2022
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33. 16% efficiency all-polymer organic solar cells enabled by a finely tuned morphology via the design of ternary blend

Author

Liu, Tao, Yang, Tao, Ma, Ruijie, Zhan, Lingling, Luo, Zhenghui, Zhang, Guangye, Li, Yuan, Gao, Ke, Xiao, Yiqun, Yu, Jianwei, Zou, Xinhui, Sun, Huiliang, Zhang, Maojie, Dela Peña, Top Archie, Xing, Zengshan, Liu, Heng, Li, Xiaojun, Li, Gang, Huang, Jianhua, Duan, Chunhui, Wong, Kam Sing, Lu, Xinhui, Guo, Xugang, Gao, Feng, Chen, Hongzheng, Huang, Fei, Li, Yongfang, Li, Yuliang, Cao, Yong, Tang, Bo, and Yan, He

Published
2021
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35. Interfacial Modification of NiOx for Highly Efficient and Stable Inverted Perovskite Solar Cells.

Author

Zhou, Yu, Huang, Xiaozhen, Zhang, Jinsen, Zhang, Lin, Wu, Haotian, Zhou, Ying, Wang, Yao, Wang, Yang, Fu, Weifei, and Chen, Hongzheng

Subjects
SOLAR cells, TRIPHENYLAMINE, PEROVSKITE, INTERFACIAL reactions, NICKEL oxide, BENZOIC acid
Abstract

Nickel oxide is one of the most promising hole‐transporting materials in inverted perovskite solar cells (PSCs) but suffers from undesired reactions with perovskite which leads to limited device performance and stability. Self‐assembled monolayers (SAMs) are demonstrated to effectively optimize the NiOx/perovskite interface, but the significance of the compactness of the SAM at the interface is less investigated. Here, a series of methoxy‐substituted triphenylamine functionalized benzothiadiazole (TBT) based SAM molecules, TBT‐BA, TBT‐FBA, and TBT‐DBA, with benzoic acid, 2‐fluorobenzoic acid and isophthalic acids as anchoring groups are used to modify NiOx. TBT‐BA with the simplest structure is demonstrated to form the densest SAM on NiOx, thus optimized NiOx/SAM/perovskite interface is achieved with enhanced charge collection and suppressed interfacial reaction and recombination. TBT‐BA can also passivate the perovskite most effectively due to the highest binding energy toward perovskite, thus the corresponding inverted PSCs show the highest PCE of 24.8% and maintain 88.7% of the initial PCE after storage at 60 °C for 2635 h in the glovebox. The work provides important insights into designing SAM molecules for modification transporting layers for efficient and stable PSCs. [ABSTRACT FROM AUTHOR]

Published
2024
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40. Enhanced crystal network and charge transfer of non-fused ring electron acceptor via interchain interaction enable efficient and stable organic solar cells

Author

Ye, Shounuan, primary, Chen, Tianyi, additional, Yu, Jinyang, additional, Wang, Shanlu, additional, Li, Shuixing, additional, Wang, Jingxi, additional, Fu, Yuang, additional, Zhu, Yuxuan, additional, Wang, Mengting, additional, Lu, Xinhui, additional, Ma, Zaifei, additional, Li, Chang-Zhi, additional, Shi, Minmin, additional, and Chen, Hongzheng, additional

Published
2024
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42. Synergistically optimizing the optoelectronic properties and morphology using a photo-active solid additive for high-performance binary organic photovoltaics

Author

Wang, Mengting, primary, Chen, Tianyi, additional, Li, Yaokai, additional, Ding, Guanyu, additional, Chen, Zeng, additional, Li, Jikun, additional, Xu, Chang, additional, Wupur, Adiljan, additional, Xu, Chenran, additional, Fu, Yuang, additional, Xue, Jingwei, additional, Fu, Weifei, additional, Qiu, Weiming, additional, Yang, Xi, additional, Wang, Dawei, additional, Ma, Wei, additional, Lu, Xinhui, additional, Zhu, Haiming, additional, Chen, Xiankai, additional, Wang, Xiaoye, additional, Chen, Hongzheng, additional, and Zuo, Lijian, additional

Published
2024
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49. Stabilizing the resonance structure of nonfused-ring electron acceptors via a closed-loop carbazole side chain for efficient and stable organic solar cells.

Author

Xing, Ziyi, Wu, Xiaoling, Chen, Tianyi, Ye, Shounuan, Wang, Shanlu, Pan, Youwen, Li, Shuixing, Shi, Minmin, and Chen, Hongzheng

Abstract

For commercially applicable organic solar cells (OSCs), both high efficiency and stability are essential requirements. A long-existing hidden problem of electron acceptors is the carbon–carbon double bond, which favors efficiency but harms stability. To explore a potential solution, we herein designed two nonfused-ring electron acceptors (NFREAs) with the same molecular backbone but varying side chains, a closed-loop carbazole side chain for 3TTCz and an open-loop diphenylamine side chain for 3TTDPA. It was unveiled that photodegradation proceeded via the oxidation of the carbon–carbon double bond through the quinoid resonance structure, which would be promoted by the open-loop diphenylamine unit, but hindered by the closed-loop carbazole unit. As a result, device stability was significantly improved for the 3TTCz-based OSC. In addition, the carbazole unit also allowed higher crystallinity, better molecular orientation and less charge recombination, leading to an exceptionally high fill factor (FF) of 78.78% and a good power conversion efficiency (PCE) of 14.00% for the 3TTCz-based OSC, better than those of the 3TTDPA-based one (FF = 66.93%, PCE = 13.85%). This work provides a feasible approach for stabilizing the resonance structure of NFREAs, thus enabling efficient and stable OSCs. [ABSTRACT FROM AUTHOR]

Published
2024
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