| 1.
Polymer solar cells with enhanced fill factors
[1250]
|
| 2.
New Benzo[1,2-d:4,5-d ']bis([1,2,3]thiadiazole) (iso-BBT)-Based Po..
[1161]
|
| 3.
Imide- and Amide-Functionalized Polymer Semiconductors
[1154]
|
| 4.
Material insights and challenges for non-fullerene organic solar c..
[1153]
|
| 5.
A monothiophene unit incorporating both fluoro and ester substitut..
[736]
|
| 6.
Monolithic perovskite/organic tandem solar cells with 23.6% effici..
[569]
|
| 7.
A solution-processed n-type conducting polymer with ultrahigh cond..
[465]
|
| 8.
16% efficiency all-polymer organic solar cells enabled by a finely..
[462]
|
| 9.
Dialkoxybithiazole: A New Building Block for Head-to-Head Polymer ..
[421]
|
| 10.
共轭分子材料的功能化及应用
[396]
|
| 11.
Vertical organic electrochemical transistors for complementary cir..
[356]
|
| 12.
Marked Consequences of Systematic Oligothiophene Catenation in Thi..
[333]
|
| 13.
Optimization of solvent swelling for efficient organic solar cells..
[274]
|
| 14.
Two compatible polymer donors contribute synergistically for terna..
[270]
|
| 15.
Precisely Controlling the Position of Bromine on the End Group Ena..
[238]
|
| 16.
Triimide-Functionalized n-Type Polymer Semiconductors Enabling All..
[202]
|
| 17.
Quinoxaline-Based Wide Band Gap Polymers for Efficient Nonfulleren..
[187]
|
| 18.
High Short-Circuit Current Density via Integrating the Perovskite ..
[182]
|
| 19.
Dopant-Free Small-Molecule Hole-Transporting Material for Inverted..
[181]
|
| 20.
Bichalcogenophene Imide-Based Homopolymers: Chalcogen-Atom Effects..
[181]
|
| 21.
Teaching an Old Anchoring Group New Tricks: Enabling Low-Cost, Eco..
[174]
|
| 22.
Alkynyl-Functionalized Head-to-Head Linkage Containing Bithiophene..
[170]
|
| 23.
High-Performance All-Polymer Solar Cells Enabled by n-Type Polymer..
[170]
|
| 24.
Imide-Functionalized Heteroarene-Based n-Type Terpolymers Incorpor..
[169]
|
| 25.
Effects of Bithiophene Imide Fusion on the Device Performance of O..
[168]
|
| 26.
High-Performance n-Type Polymer Semiconductors: Applications, Rece..
[167]
|
| 27.
Backbone Conformation Tuning of Carboxylate-Functionalized Wide Ba..
[166]
|
| 28.
N-type conjugated polymer as efficient electron transport layer fo..
[166]
|
| 29.
Engineering of dendritic dopant-free hole transport molecules: ena..
[165]
|
| 30.
A Narrow-Bandgap n-Type Polymer Semiconductor Enabling Efficient A..
[156]
|
| 31.
Phthalimide-Based High Mobility Polymer Semiconductors for Efficie..
[154]
|
| 32.
1,4-Di(3-alkoxy-2-thienyI)-2,5-difluorophenylene: A Building Block..
[151]
|
| 33.
Head-to-Head Linked Dialkylbifuran-Based Polymer Semiconductors fo..
[150]
|
| 34.
Medium band-gap non-fullerene acceptors based on a benzothiophene ..
[150]
|
| 35.
π-Extended Naphthalene Diimide Derivatives for n-Type Semiconduct..
[148]
|
| 36.
Cyano-Substituted Head-to-Head Polythiophenes: Enabling High-Perfo..
[146]
|
| 37.
Polymer semiconductors incorporating head-to-head linked 4-alkoxy-..
[141]
|
| 38.
Backbone Coplanarity Tuning of 1,4-Di(3-alkoxy-2-thienyl)-2,5-difl..
[139]
|
| 39.
Facile Synthesis of Polycyclic Aromatic Hydrocarbon (PAH)-Based Ac..
[137]
|
| 40.
Transition metal-catalysed molecular n-doping of organic semicondu..
[137]
|
| 41.
Side-Chain Engineering of Donor-Acceptor Conjugated Small Molecule..
[136]
|
| 42.
Reducing energy lossviatuning energy levels of polymer acceptors f..
[136]
|
| 43.
Fluorinated End Group Enables High-Performance All-Polymer Solar C..
[133]
|
| 44.
Cyano-substituted benzochalcogenadiazole-based polymer semiconduct..
[132]
|
| 45.
Bis(benzofurano)pyrrole and hybrid thienopyrrole derivatives for o..
[132]
|
| 46.
Intramolecular Noncovalent Interaction-Enabled Dopant-Free Hole-Tr..
[132]
|
| 47.
Conjugated Polymer-Assisted Grain Boundary Passivation for Efficie..
[131]
|
| 48.
A Terpolymer Acceptor Enabling All-Polymer Solar Cells with a Broa..
[131]
|
| 49.
Head-to-Head Linkage Containing Dialkoxybithiophene-Based Polymeri..
[127]
|
| 50.
Fused Bithiophene Imide Oligomer and Diketopyrrolopyrrole Copolyme..
[127]
|
| 51.
Ladder-Type Heteroarene-Based Organic Semiconductors
[126]
|
| 52.
Isomerization enabling near-infrared electron acceptors
[125]
|
| 53.
Additive-Free Non-Fullerene Organic Solar Cells
[124]
|
| 54.
Distannylated Bithiophene Imide: Enabling High-Performance n-Type ..
[124]
|
| 55.
Core Fusion Engineering of Hole-Transporting Materials for Efficie..
[124]
|
| 56.
Efficient Perovskite Solar Cells with a Novel Aggregation-Induced ..
[123]
|
| 57.
Imide-functionalized acceptor-acceptor copolymers as efficient ele..
[122]
|
| 58.
Highly Efficient Ternary All-Polymer Solar Cells with Enhanced Sta..
[121]
|
| 59.
Overcoming Coulomb Interaction Improves Free-Charge Generation and..
[120]
|
| 60.
Cyano-Functionalized Bithiophene Imide-Based n-Type Polymer Semico..
[120]
|
| 61.
Stable Organic Diradicals Based on Fused Quinoidal Oligothiophene ..
[119]
|
| 62.
Soft Porous Blade Printing of Nonfullerene Organic Solar Cells
[117]
|
| 63.
Fine-tuning head-to-head bithiophene-difluorobenzothiadiazole poly..
[116]
|
| 64.
Electron-deficient diketone unit engineering for non-fused ring ac..
[116]
|
| 65.
Highly stretchable organic electrochemical transistors with strain..
[115]
|
| 66.
Design, synthesis, and applications of high-performance polymer se..
[114]
|
| 67.
High-Performance All-Polymer Solar Cells Enabled by an n-Type Poly..
[113]
|
| 68.
Boosting Efficiency and Stability of Organic Solar Cells Using Ult..
[113]
|
| 69.
Side-Chain Optimization of Phthalimide-Bithiophene Copolymers for ..
[112]
|
| 70.
Terpolymer acceptors based on bithiophene imide for all-polymer so..
[111]
|
| 71.
A Cost-Effective D-A-D Type Hole-Transport Material Enabling 20% E..
[111]
|
| 72.
Imide-Functionalized Thiazole-Based Polymer Semiconductors: Synthe..
[110]
|
| 73.
Integrated Ideal-Bandgap Perovskite/Bulk-Heterojunction Solar Cell..
[110]
|
| 74.
Fluorine-Substituted Dithienylbenzodiimide-Based n-Type Polymer Se..
[109]
|
| 75.
Ultranarrow Bandgap Naphthalenediimide-Dialkylbifuran-Based Copoly..
[109]
|
| 76.
Improved photovoltaic performance of a nonfullerene acceptor based..
[108]
|
| 77.
Engineering Intrinsic Flexibility in Polycrystalline Molecular Sem..
[108]
|
| 78.
Effects of the Electron-Deficient Third Components in n-Type Terpo..
[108]
|
| 79.
Phthalimide-Based Wide Bandgap Donor Polymers for Efficient Non-Fu..
[107]
|
| 80.
Self-assembled donor-acceptor hole contacts for inverted perovskit..
[107]
|
| 81.
Conformation-Tuning Effect of Asymmetric Small Molecule Acceptors ..
[105]
|
| 82.
2,1,3-Benzothiadiazole-5,6-dicarboxylicimide-Based Polymer Semicon..
[104]
|
| 83.
Directional Carrier Polarity Tunability in Ambipolar Organic Trans..
[104]
|
| 84.
Materials Design via Optimized Intramolecular Noncovalent Interact..
[103]
|
| 85.
A Narrow-Bandgap n-Type Polymer with an Acceptor-Acceptor Backbone..
[103]
|
| 86.
A low-cost and green-solvent-processable hole-transport material e..
[103]
|
| 87.
Fused Bithiophene Imide Dimer-Based n-Type Polymers for High-Perfo..
[102]
|
| 88.
A New Wide Bandgap Donor Polymer for Efficient Nonfullerene Organi..
[101]
|
| 89.
Efficient and stable organic solar cells enabled by multicomponent..
[101]
|
| 90.
Thiazolothienyl imide-based wide bandgap copolymers for efficient ..
[100]
|
| 91.
Naphthodithiophene-Based Semiconducting Materials for Applications..
[100]
|
| 92.
Side-Chain Engineering on Y-Series Acceptors with Chlorinated End ..
[100]
|
| 93.
Achieving highly efficient all-polymer solar cells by green-solven..
[100]
|
| 94.
26 mA cm−2 JSC achieved in the integrated solar cells
[98]
|
| 95.
Side chain engineering of polymer acceptors for all-polymer solar ..
[98]
|
| 96.
Two Compatible Polymer Donors Enabling Ternary Organic Solar Cells..
[98]
|
| 97.
Regioregular Narrow-Bandgap n-Type Polymers with High Electron Mob..
[97]
|
| 98.
Fluorinated Head-to-Head Dialkoxybithiophene: A New Electron-Donat..
[95]
|
| 99.
酰亚胺基高分子半导体及其有机太阳能电池
[94]
|
| 100.
Thiazole Imide-Based All-Acceptor Homopolymer: Achieving High-Perf..
[93]
|
