2,4-dichloropyrimidine-5-carbonitrile - ≥97% , CAS No.3177-24-0

CAS: 3177-24-0 Cat. No.: D176113 Peso molecular: 173.98 Número EC: 688-595-9
Disponible para pedir
GRADE & PURITY ≥97%
Synonyms
AC-3018 | 2,4-Dichloro-5-cyanopyrimidine;2,4-Dichloropyrimidine-5-carbonitrile | Ironphthalocyanine | SCHEMBL9043 | GS-6550 | STL556395 | AM807231 | DTXSID10554569 | Z1198222315 | BBL102592 | FT-0648536 | AKOS005255838 | SY003577 | 2,4-dichloro-pyrimidine
Storage
Store at -20°C,Argon charged
Shipped In
Ice chest + Ice pads
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Size
Estado
Price
Qty
250mg
D176113-250mg
8

9,90US$

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1g
D176113-1g
3

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19,90US$
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5g
D176113-5g
1

31,90US$

47,90US$
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10g
D176113-10g
8-12 wks(?) Production requires sourcing of materials. We appreciate your patience and understanding.

52,90US$

79,90US$
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25g
D176113-25g
3

131,90US$

197,90US$
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Why this grade

≥97% for sensitive chromatographic and analytical workflows requiring minimal baseline interference.

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Storage & shipping

Store at -20°C,Argon charged Ships Ice chest + Ice pads Check lot-specific COA for exact specifications.

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Quality documents

SDS, COA, datasheet, and spec sheet available for download. Lot-specific COA accessible via lot number lookup.

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Literature proof

Cited in 44 peer-reviewed publications across chromatography, organic synthesis, and cross-coupling reactions.

Specifications

Sinónimos
AC-3018 | 2, 4-Dichloro-5-cyanopyrimidine;2, 4-Dichloropyrimidine-5-carbonitrile | Ironphthalocyanine | SCHEMBL9043 | GS-6550 | STL556395 | AM807231 | DTXSID10554569 | Z1198222315 | BBL102592 | FT-0648536 | AKOS005255838 | SY003577 | 2, 4-dichloro-pyrimidine
Especificaciones y pureza
≥97%
Condiciones de almacenamiento de almacenamiento
Store at -20°C, Argon charged
Enviado en
Ice chest + Ice pads
Este producto requiere envío en cadena de frío. Los servicios terrestres y otros servicios económicos no están disponibles.
Pureza
≥97%
Nombres e identificadores
Pubchem Sid488198577
Sonrisas canónicasC1=C(C(=NC(=N1)Cl)Cl)C#N
IUPAC Name2,4-dichloropyrimidine-5-carbonitrile
InChIKeyKMHSUNDEGHRBNV-UHFFFAOYSA-N
INCHI1S/C5HCl2N3/c6-4-3(1-8)2-9-5(7)10-4/h2H
Isómeros SMILES C1=C(C(=NC(=N1)Cl)Cl)C#N
Peso molecular 173.98
Reaxy-Rn 512190
Reaxys-RN_link_address https://www.reaxys.com/reaxys/secured/hopinto.do?context=S&query=IDE.XRN=512190&ln=

Documentation

📋 Safety Data Sheet (SDS)

Comprehensive hazard, handling, storage, and regulatory compliance document.

Download SDS →

✅ Certificate of Analysis (COA)

Lot-specific quality data. Enter your lot number to retrieve the exact COA.

Look up COA →

📊 Datasheet

Quick-reference summary of product specifications and applications.

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🔬 Specification Sheet

Full quality attributes and acceptance criteria for this grade.

View spec sheet →

Advanced Data

Taxonomic Classification

Taxonomy Tree

KingdomOrganic compounds
SuperclassOrganoheterocyclic compounds
ClaseDiazines
SubclassPyrimidines and pyrimidine derivatives
Intermediate Tree Nodes Halopyrimidines
Direct Parent2-halopyrimidines
Alternative Parents Aryl chlorides  Heteroaromatic compounds  Nitriles  Azacyclic compounds  Organochlorides  Hydrocarbon derivatives  
Molecular FrameworkAromatic heteromonocyclic compounds
Substituents 2-halopyrimidine - Aryl halide - Aryl chloride - Heteroaromatic compound - Azacycle - Nitrile - Carbonitrile - Organic nitrogen compound - Cyanide - Hydrocarbon derivative - Organonitrogen compound - Organochloride - Organohalogen compound - Aromatic heteromonocyclic compound
DescripciónThis compound belongs to the class of organic compounds known as 2-halopyrimidines. These are aromatic compounds containing a pyrimidine ring substituted at the 2-position with a halogen atom.
External Descriptors Not available
Estructura 3D
Modelo de Estructura Química Interactiva





Certificados (CoA, COO, BSE/TSE y tabla de análisis)
C of A & Other Certificates(BSE/TSE, COO):
Analytical Chart:

Find and download the COA for your product by matching the lot number on the packaging.

9 results found

Lot NumberCertificate TypeFechaArticulo
C2328339Certificate of AnalysisJan 19, 2026 D176113
C2328356Certificate of AnalysisJan 19, 2026 D176113
C2328497Certificate of AnalysisJan 19, 2026 D176113
C2328504Certificate of AnalysisJan 19, 2026 D176113
C2328512Certificate of AnalysisJan 19, 2026 D176113
C2328520Certificate of AnalysisJan 19, 2026 D176113
C2328616Certificate of AnalysisJan 19, 2026 D176113
C2328607Certificate of AnalysisJan 07, 2023 D176113
C2328618Certificate of AnalysisJan 07, 2023 D176113
Propiedades químicas y físicas
Peso molecular173.980 g/mol
XLogP31.800
Hydrogen Bond Donor Count0
Hydrogen Bond Acceptor Count3
Rotatable Bond Count0
Exact Mass172.955 Da
Monoisotopic Mass172.955 Da
Topological Polar Surface Area49.600 Ų
Heavy Atom Count10
Formal Charge0
Complexity164.000
Isotope Atom Count0
Defined Atom Stereocenter Count0
Undefined Atom Stereocenter Count0
Defined Bond Stereocenter Count0
Undefined Bond Stereocenter Count0
The total count of all stereochemical bonds0
Covalently-Bonded Unit Count1
Citations of This Product
Referencias
1. Zhang Rong, Li Chuan, Cui Huilin, Wang Yanbo, Zhang Shaoce, Li Pei, Hou Yue, Guo Ying, Liang Guojin, Huang Zhaodong, Peng Chao, Zhi Chunyi.  (2023)  Electrochemical nitrate reduction in acid enables high-efficiency ammonia synthesis and high-voltage pollutes-based fuel cells.  Nature Communications,  14  (1): (1-11).  [PMID:38052852] [10.1038/s41467-023-43897-6]
2. Qiusheng Zhou, Min Min, Minmin Song, Shiqiang Cui, Nan Ding, Mingyuan Wang, Shuangying Lei, Chuanyin Xiong, Xinwen Peng.  (2023)  In Situ Construction of Zinc-Mediated Fe, N-Codoped Hollow Carbon Nanocages with Boosted Oxygen Reduction for Zn–Air Batteries.  Small,      [PMID:38037480] [10.1002/smll.202307943]
3. Ziquan Chen, Yihan Ye, Tao Peng, Chenxin Wu, Haiyang Li, Xiulian Pan, Xinhe Bao.  (2023)  Iron-Single Sites Confined by Graphene Lattice for Ammonia Synthesis under Mild Conditions.  ACS Catalysis,      [PMID:] [10.1021/acscatal.3c03108]
4. Wang Sun, Junyan Liu, Xiaoqian Zha, Guorong Sun, Yang Wang.  (2023)  Triple microenvironment modulation of zeolite imidazolate framework (ZIF) nanocages for boosting dopamine electrocatalysis.  JOURNAL OF COLLOID AND INTERFACE SCIENCE,      [PMID:37832230] [10.1016/j.jcis.2023.10.022]
5. Keheng Pan, Xin Tang, Guangfei Qu, Huimin Tang, Kunling Wei, Jiaxin Lv.  (2023)  Mesoporous Silica/Iron Phthalocyanine Light-Driven Nanomaterials for Efficient Removal of Pb2+ Ions from Wastewater.  ACS Applied Nano Materials,      [PMID:] [10.1021/acsanm.3c01499]
6. Yanwen Chen, Liu Zhao, Baoshuai Zhang, Yuqing Guan, Cheng Yao, Xuan Xu.  (2023)  Fe–N hollow mesoporous carbon spheres with high oxidase-like activity for sensitive detection of alkaline phosphatase.  ANALYST,  148  (12): (2825-2833).  [PMID:37227369] [10.1039/D3AN00475A]
7. Linwei Zhang, Xudong Jiao, Guangjing He, Zhaodi Shen, Wei Wang.  (2023)  Iron phthalocyanine decorated porous biomass-derived carbon as highly effective electrocatalyst for oxygen reduction reaction.  Journal of Environmental Chemical Engineering,      [PMID:] [10.1016/j.jece.2023.109676]
8. Lanlan Tian, Yuanlin Xie, Jing Lu, Qiang Hu, Yongneng Xiao, Tiefeng Liu, Bekchanov Davronbek, Xiaoquan Zhu, Xintai Su.  (2022)  Self-assembled 3D Fe3O4/N-Doped graphene aerogel composite for large and fast lithium storage with an excellent cycle performance.  JOURNAL OF ELECTROANALYTICAL CHEMISTRY,      [PMID:] [10.1016/j.jelechem.2022.116763]
9. Cheng Han, Xiaodeng Zhang, Qiuhong Sun, Dandan Chen, Tingting Miao, Kongzhao Su, Qipeng Li, Shaoming Huang, Jinjie Qian.  (2022)  Phthalocyanine-induced iron active species in metal–organic framework-derived porous carbon for efficient alkaline zinc–air batteries.  Inorganic Chemistry Frontiers,  (11): (2557-2567).  [PMID:] [10.1039/D2QI00394E]
10. Yiyang Lin, Kang Liu, Kejun Chen, Yan Xu, Hongmei Li, Junhua Hu, Ying-Rui Lu, Ting-Shan Chan, Xiaoqing Qiu, Junwei Fu, Min Liu.  (2021)  Tuning Charge Distribution of FeN4 via External N for Enhanced Oxygen Reduction Reaction.  ACS Catalysis,      [PMID:] [10.1021/acscatal.0c04966]
11. Meiying Yu, Yunfei Li, Wulin Yang, Xiaole Yuan, Nan Li, Weihua He, Yujie Feng, Jia Liu.  (2020)  Enhanced electrocatalytic activity and antifouling performance by iron phthalocyanine doped filtration membrane cathode.  CHEMICAL ENGINEERING JOURNAL,      [PMID:] [10.1016/j.cej.2020.127536]
12. Ningjie Du, Ying Liu, Qiuju Li, Wei Miao, Dandan Wang, Shun Mao.  (2020)  Peroxydisulfate activation by atomically-dispersed Fe-Nx on N-doped carbon: Mechanism of singlet oxygen evolution for nonradical degradation of aqueous contaminants.  CHEMICAL ENGINEERING JOURNAL,      [PMID:] [10.1016/j.cej.2020.127545]
13. Lili Yao, Shengjie Gao, Shuai Liu, Yulong Bi, Rongrong Wang, Hao Qu, Yuen Wu, Yu Mao, Lei Zheng.  (2020)  Single-Atom Enzyme-Functionalized Solution-Gated Graphene Transistor for Real-Time Detection of Mercury Ion.  ACS Applied Materials & Interfaces,      [PMID:31933362] [10.1021/acsami.9b19434]
14. Xu Jing, Zhao Lele, Hou Wenlong, Guo Huiyun, Zhang Haiquan.  (2018)  Dependence of morphology, substrate and thickness of iron phthalocyanine thin films on the photocatalytic degradation of rhodamine B dye.  CHEMICAL PAPERS,  72  (9): (2327-2337).  [PMID:] [10.1007/s11696-018-0453-3]
15. Feijin Zhou, Wenying Cui, Chenggang Liu, Cheng Yao, Chan Song.  (2024)  2D-rGO-supported FePc bifunctional nanozyme with enhanced catalytic activity for thiosulfate detection and rhodamine B degradation.  Environmental Science-Nano,  11  (7): (3104-3113).  [PMID:] [10.1039/D4EN00119B]
16. Qiusheng Zhou, Shiqiang Cui, Minmin Song, Xianying He, Linfang Lu, Dongliang Liu, Chuanyin Xiong.  (2025)  Alloying Confined Regulation of Nanoparticles in a Hierarchically Directed Porous Carbon for Zinc–Air Batteries.  INORGANIC CHEMISTRY,      [PMID:39909724] [10.1021/acs.inorgchem.4c04944]
17. Chonghong Shu, Wenlin Zhang, Jiayu Zhan, Fengshou Yu.  (2024)  Anchoring covalent organic polymers on supports with tunable functional groups boosting the oxygen reduction performance under pH-universal conditions.  JOURNAL OF COLLOID AND INTERFACE SCIENCE,      [PMID:38330664] [10.1016/j.jcis.2024.01.218]
18. Qiulan Huang, Ruiqin Ren, Jia Li, Muhammad Waqas, Pan Chen, Xiaotian Liu, Dujuan Huang, Zhongyun Yang, Xinglan Peng, Du-Hong Chen, Youjun Fan, Wei Chen.  (2024)  Co, Fe decorated N, S co-doped porous carbon enables high stability for the oxygen reduction reaction.  Catalysis Science & Technology,  14  (3): (667-672).  [PMID:] [10.1039/D3CY01323E]
19. Yueling Yu, Yanming Liu, Xingzhu Zhang, Bowen lv, Yuanlu Xu, Xinfei Fan.  (2025)  Co-enhancing volatile organic compound degradation and steam generation in solar interfacial evaporation by integrating with electro-Fenton.  WATER RESEARCH,      [PMID:40015009] [10.1016/j.watres.2025.123348]
20. Lianzhong Shen, Lin Wang, Yu Ye, Zhouwei Li, Qizhou Dai.  (2024)  Creation of intrinsic defects on ZIF-8 particles to facilitate electrochemical reduction of CO2 over Fe single-atom catalyst.  CHEMICAL ENGINEERING JOURNAL,      [PMID:] [10.1016/j.cej.2024.153073]
21. Shanyong Chen, Tao Luo, Xiaoqing Li, Kejun Chen, Qiyou Wang, Junwei Fu, Kang Liu, Chao Ma, Ying-Rui Lu, Hongmei Li, Kishan S. Menghrajani, Changxu Liu, Stefan A. Maier, Ting-Shan Chan, Min Liu.  (2024)  Design of reaction-driven active configuration for enhanced CO2 electroreduction.  Nano Energy,      [PMID:] [10.1016/j.nanoen.2024.109873]
22. Yi Qin, Cheng-Hao Chuang, Xiaojing Liu, Xian Liang, Linfeng Xie, Kuan Wang, Chih-Wen Pao, Ying-Rui Lu, Yang Liu, Yawei Chen, Zhanwu Lei, Pengfei Yan, Liang Wu, Shuhong Jiao, Qing Li, Ruiguo Cao.  (2024)  DNA-Anchored Single-Molecule Iron Phthalocyanine As an Efficient Electrocatalyst for Alkaline Fuel Cells.  ACS Catalysis,      [PMID:] [10.1021/acscatal.4c00795]
23. Zhen Lv, Juan Miao, Xuefeng Wei, Xinquan Zhou, Ning Zhang, Hang Xu, Shuge Peng.  (2025)  Graphene oxide enhanced Iron‑carbon aerogel electrodes for heterogeneous electro-Fenton oxidation of phenol.  JOURNAL OF ELECTROANALYTICAL CHEMISTRY,      [PMID:] [10.1016/j.jelechem.2025.119084]
24. Xuyuan Nie, Guang Li, Linzhe Lü, Lifei Ji, Jian Yang, Yan-Xia Jiang, Binwei Zhang, Zidong Wei, Shi-Gang Sun.  (2024)  In Situ Fourier Transform Infrared Spectroscopy CO-Probe Method for Evaluating the Surface Electronic Structure of Metal Catalysts.  Journal of Physical Chemistry C,      [PMID:] [10.1021/acs.jpcc.4c05670]
25. Junfeng Wang, Sihua Pan, Wang Sun, Yang Wang.  (2024)  Ingenious microenvironment regulation of a metal–organic framework (MOF) nanoreactor for electrochemical detection of chlorogenic acid.  NEW JOURNAL OF CHEMISTRY,  48  (4): (1792-1799).  [PMID:] [10.1039/D3NJ05061K]
26. Ge Li, Chunxiao Jin, Baodong Wang, Ziran Ma, Pan Gao, Shuwei Zhou, Renqin Chang, Yuxue Yue, Jia Zhao.  (2024)  Ionic-liquid-induced phthalocyanine monolayer electrocatalyst for efficient nitrogen reduction reaction.  APPLIED CATALYSIS A-GENERAL,      [PMID:] [10.1016/j.apcata.2024.119562]
27. Linghan Lan, Yuan He, Qin Peng, Jun Li, Yao Ge, Xuhui Jiang, Xun Zhu, Qiang Liao.  (2024)  Minimizing liquid/solid interfacial energy boosts Fe−N doping inside hollow carbon sphere for oxygen reduction in membrane-less direct formate fuel cell.  Sustainable Energy Technologies and Assessments,      [PMID:] [10.1016/j.seta.2024.103957]
28. Quanxiong Lu, Jiajia Tai, Xianliang Song.  (2024)  Preparation of cathode catalysts for efficient direct lignin fuel cells by nitrogen doping reduction of oxidized graphene with phthalocyanine iron and Kraft lignin.  JOURNAL OF COLLOID AND INTERFACE SCIENCE,      [PMID:39128292] [10.1016/j.jcis.2024.08.002]
29. Xilin Zhang, Rui Zheng, Qingfang Chang, Zhongjun Ma, Zongxian Yang.  (2024)  Regulating the frontier orbital of iron phthalocyanine by nitrogen doped carbon nanosheets for improving oxygen reduction activity.  Nanoscale,      [PMID:38546764] [10.1039/D4NR00377B]
30. Liruhua Zhang, Zhixiang Chen, Yuxiang Wu, Tao Yang, Ling Bing Kong, Qingxia Liu.  (2024)  Self-assembled iron (II) phthalocyanine modified oxygen vacancy-rich WO3 nanofibers with unique S-scheme heterojunctions for efficient tetracycline hydrochloride degradation and CO2 reduction.  JOURNAL OF MOLECULAR STRUCTURE,      [PMID:] [10.1016/j.molstruc.2024.139411]
31. Shide Wu, Yifei Zhang, Dan Ping, Yapeng Li, Wan Li, Shuqing Liu, Di Wu, Shiwen Wang, Xuzhao Yang, Guanglu Han, Dongjie Guo, Shaoming Fang.  (2024)  Synergistic effect of iron phthalocyanine and ultrafine cobalt nanoparticles for efficient CO2 electroreduction to syngas.  CARBON,      [PMID:] [10.1016/j.carbon.2024.119428]
32. Huazhang Guo, Jithu Raj, Zeming Wang, Tianyu Zhang, Kang Wang, Lili Lin, Weidong Hou, Jiye Zhang, Minghong Wu, Jingjie Wu, Liang Wang.  (2024)  Synergistic Effects of Amine Functional Groups and Enriched-Atomic-Iron Sites in Carbon Dots for Industrial-Current–Density CO2 Electroreduction.  Small,  20  (32): (2311132).  [PMID:38511553] [10.1002/smll.202311132]
33. Wenyi Wang, Han Ren, Junhan Guo, Sidi Wang, Jia Wang, Yuanyuan Wang, Wencong Sun, Long Tang, Xueqin Wang.  (2024)  Synergistically enhanced atomically dispersed Fe-Nx sites on carbon nanotubes by heteroatom S to boost electrochemical oxygen reduction for microbial fuel cell.  JOURNAL OF POWER SOURCES,      [PMID:] [10.1016/j.jpowsour.2024.235960]
34. Jieying Wan, Hao Zhang, Ji Yang, Jiageng Zheng, Zhongkang Han, Wentao Yuan, Bingru Lan, Xiaodong Li.  (2024)  Synergy between Fe and Mo single atom catalysts for ammonia electrosynthesis.  APPLIED CATALYSIS B-ENVIRONMENTAL,      [PMID:] [10.1016/j.apcatb.2024.123816]
35. Dan Ping, Qingshuo Zhang, Weitao Liu, Shide Wu, Jing Gao, Haoyi Zhang, Shiwen Wang, Huajun Qiu, Shaoming Fang.  (2025)  Spatially separated single atom/nanaoparticle dual sites on porous carbon for synergistic electrochemical CO2 reduction to syngas.  CARBON,      [PMID:] [10.1016/j.carbon.2025.120653]
36. Chen Kejun, Liu Kang, An Pengda, Li Huangjingwei, Lin Yiyang, Hu Junhua, Jia Chuankun, Fu Junwei, Li Hongmei, Liu Hui, Lin Zhang, Li Wenzhang, Li Jiahang, Lu Ying-Rui, Chan Ting-Shan, Zhang Ning, Liu Min.  (2020)  Iron phthalocyanine with coordination induced electronic localization to boost oxygen reduction reaction.  Nature Communications,  11  (1): (1-8).  [PMID:32820168] [10.1038/s41467-020-18062-y]
37. Ghazala Ashraf, Haonan Wang, Khalil Ahmed, Huiwen Xiong, Jilie Kong, Xueen Fang.  (2025)  Microneedle-Integrated FePc–MOF–MXene Nanozyme Patch for In Vivo L-Cysteine Monitoring.  ADVANCED MATERIALS,      [PMID:40405623] [10.1002/adma.202502804]
38. Lingzhe Meng, Shuwen Niu, Zhengyu Wei, Xue Qin, Faheem Naseem, Wei Wei.  (2025)  Accelerated proton-coupled electron transfer kinetics of iron phthalocyanine for oxygen reduction via heteropoly blue clusters.  APPLIED CATALYSIS B-ENVIRONMENTAL,      [PMID:] [10.1016/j.apcatb.2025.125080]
39. Yashu Li, Nan Wang, Lu Zhao, Xuanhe Liu, Lin Wang, Chengcheng Xie, Jing Li.  (2025)  Cinnamomum-Longepaniculatum-Leaves-Based Fe-N Doped Porous Carbon as an Effective Oxygen Reduction Catalyst.  MOLECULES,  30  (8): (1708).  [PMID:40333641] [10.3390/molecules30081708]
40. Lianzhong Shen, Lin Wang, Zhouwei Li, Yu Ye, Qizhou Dai.  (2025)  Modification of single atomic Fe-N4 catalytic site with sulfur to promote CO2 electroreduction.  CARBON,      [PMID:] [10.1016/j.carbon.2025.120388]
41. Chen Yang, Quanxiong Lu, Xianbo Jia, Yujia Ma, Xianliang Song.  (2025)  Efficient non-precious metal catalysts based on FePc-C60 for direct lignin fuel cells.  JOURNAL OF ELECTROANALYTICAL CHEMISTRY,      [PMID:] [10.1016/j.jelechem.2025.119614]
42. Li Guang, Yin Shu-Hu, Ji Li-Fei, Nie Xu-Yuan, Zhu Ting, Cheng Xiao-Yang, Xu Jun, Huang Rui, Jiang Yan-Xia, Zhang Bin-Wei, Sun Shi-Gang.  (2025)  Universal electrochemical quantification of active site density in transition metal nitrogen carbon electrocatalysts.  Nature Communications,  16  (1): (10626).  [PMID:41309541] [10.1038/s41467-025-65614-1]
43. Yuan Ma, Yongli Li, Lan Jiang, Xin Kong, Xin You, Liang Liu, Rui Bao, Zhenhua Ge, Hao Cui, Feng Liu, Jianhong Yi.  (2026)  Dynamic Cu–Fe Dual Sites Steering Tandem e–/H+ Delivery for Efficient NH3 Electrosynthesis in Acid.  ACS Applied Materials & Interfaces,      [PMID:41511040] [10.1021/acsami.5c21213]
44. Qiusheng Zhou, Li Song, Minmin Song, Linfang Lu, Weihao Pan, Xianying He, Chenxu Zhao, Ziyu Zhao, Chuanyin Xiong.  (2026)  High-performance multi-component synergistic hydrogel electrolyte with enhanced ion transport for flexible zinc–air batteries and wearable sensors.  GREEN CHEMISTRY,      [PMID:] [10.1039/D5GC05884H]
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