Optimization of inverted tandem organic solar cells
Identifieur interne : 000760 ( Chine/Analysis ); précédent : 000759; suivant : 000761Optimization of inverted tandem organic solar cells
Auteurs : RBID : Pascal:11-0160896Descripteurs français
- Pascal (Inist)
- Optimisation, Cellule solaire tandem, Cellule solaire organique, Hétérojonction, Couche active, Couche ITO, Addition étain, Cathode, Anode, Epaisseur, Couche tampon, Exciton, Trempe, Variance, Distribution champ, Absorption lumière, Conversion énergie, Taux conversion, Courant court circuit, Tension circuit ouvert, Facteur remplissage, Thiophène dérivé polymère, Acide butyrique, Ester, Composé du fullerène, Oxyde de molybdène, Oxyde d'indium, MoO3, ITO, Photovoltaïque organique.
English descriptors
- KwdEn :
- Active layer, Anode, Buffer layer, Butyric acid, Cathode, Conversion rate, Energy conversion, Ester, Exciton, Field distribution, Fill factor, Fullerene compounds, Heterojunction, ITO layers, Indium oxide, Light absorption, Molybdenum oxide, Open circuit voltage, Optimization, Organic photovoltaics, Organic solar cells, Quenching, Short circuit currents, Tandem solar cell, Thickness, Thiophene derivative polymer, Tin addition, Variance.
Abstract
Inverted tandem organic solar cells, consisting of two bulk heterojunction sub-cells with identical poly(3-hexylthiophene) (P3HT) and 1-(3-methoxycarbonyl)-propyl-1-phenyl-(6,6)C61 (PCBM) active layer and a MoO3/Ag/Al/Ca intermediate layer, have been presented and optimized. Indium tin oxide (ITO) modified by Ca acts as a cathode for electron collection and Ag is used as the anode for hole collection for the tandem device. A proper thickness of Ca (3 nm) forms a continuous layer, working as a cathode for the top sub-cell. MoO3 as the anode buffer layer prevents exciton quenching and charge loss at the anode side, which could result in increase in interfacial resistance. The variance of sub-cell thickness adjusts the optical field distribution in the entire device, facilitating light absorption and good current matching in both sub-cells. The optimal inverted tandem device achieves a maximum power conversion efficiency of 2.89% with a short-circuit current density of 4.19 mA/cm2, an open-circuit voltage of 1.17 V, and a fill factor of 59.0% under simulated 100 mW/cm2 (AM 1.5G) solar irradiation. .
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Pascal:11-0160896Le document en format XML
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<term>Anode</term>
<term>Buffer layer</term>
<term>Butyric acid</term>
<term>Cathode</term>
<term>Conversion rate</term>
<term>Energy conversion</term>
<term>Ester</term>
<term>Exciton</term>
<term>Field distribution</term>
<term>Fill factor</term>
<term>Fullerene compounds</term>
<term>Heterojunction</term>
<term>ITO layers</term>
<term>Indium oxide</term>
<term>Light absorption</term>
<term>Molybdenum oxide</term>
<term>Open circuit voltage</term>
<term>Optimization</term>
<term>Organic photovoltaics</term>
<term>Organic solar cells</term>
<term>Quenching</term>
<term>Short circuit currents</term>
<term>Tandem solar cell</term>
<term>Thickness</term>
<term>Thiophene derivative polymer</term>
<term>Tin addition</term>
<term>Variance</term>
</keywords>
<keywords scheme="Pascal" xml:lang="fr"><term>Optimisation</term>
<term>Cellule solaire tandem</term>
<term>Cellule solaire organique</term>
<term>Hétérojonction</term>
<term>Couche active</term>
<term>Couche ITO</term>
<term>Addition étain</term>
<term>Cathode</term>
<term>Anode</term>
<term>Epaisseur</term>
<term>Couche tampon</term>
<term>Exciton</term>
<term>Trempe</term>
<term>Variance</term>
<term>Distribution champ</term>
<term>Absorption lumière</term>
<term>Conversion énergie</term>
<term>Taux conversion</term>
<term>Courant court circuit</term>
<term>Tension circuit ouvert</term>
<term>Facteur remplissage</term>
<term>Thiophène dérivé polymère</term>
<term>Acide butyrique</term>
<term>Ester</term>
<term>Composé du fullerène</term>
<term>Oxyde de molybdène</term>
<term>Oxyde d'indium</term>
<term>MoO3</term>
<term>ITO</term>
<term>Photovoltaïque organique</term>
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<front><div type="abstract" xml:lang="en">Inverted tandem organic solar cells, consisting of two bulk heterojunction sub-cells with identical poly(3-hexylthiophene) (P3HT) and 1-(3-methoxycarbonyl)-propyl-1-phenyl-(6,6)C<sub>61</sub>
(PCBM) active layer and a MoO<sub>3</sub>
/Ag/Al/Ca intermediate layer, have been presented and optimized. Indium tin oxide (ITO) modified by Ca acts as a cathode for electron collection and Ag is used as the anode for hole collection for the tandem device. A proper thickness of Ca (3 nm) forms a continuous layer, working as a cathode for the top sub-cell. MoO<sub>3</sub>
as the anode buffer layer prevents exciton quenching and charge loss at the anode side, which could result in increase in interfacial resistance. The variance of sub-cell thickness adjusts the optical field distribution in the entire device, facilitating light absorption and good current matching in both sub-cells. The optimal inverted tandem device achieves a maximum power conversion efficiency of 2.89% with a short-circuit current density of 4.19 mA/cm<sup>2</sup>
, an open-circuit voltage of 1.17 V, and a fill factor of 59.0% under simulated 100 mW/cm<sup>2</sup>
(AM 1.5G) solar irradiation. .</div>
</front>
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<sZ>8 aut.</sZ>
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<fA14 i1="05"><s1>Department of Applied Physics, College of Science, Tianjin University</s1>
<s2>Tianjin 300072</s2>
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(PCBM) active layer and a MoO<sub>3</sub>
/Ag/Al/Ca intermediate layer, have been presented and optimized. Indium tin oxide (ITO) modified by Ca acts as a cathode for electron collection and Ag is used as the anode for hole collection for the tandem device. A proper thickness of Ca (3 nm) forms a continuous layer, working as a cathode for the top sub-cell. MoO<sub>3</sub>
as the anode buffer layer prevents exciton quenching and charge loss at the anode side, which could result in increase in interfacial resistance. The variance of sub-cell thickness adjusts the optical field distribution in the entire device, facilitating light absorption and good current matching in both sub-cells. The optimal inverted tandem device achieves a maximum power conversion efficiency of 2.89% with a short-circuit current density of 4.19 mA/cm<sup>2</sup>
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<s5>06</s5>
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<s5>10</s5>
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<s5>10</s5>
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<s5>10</s5>
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<s5>11</s5>
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<s5>11</s5>
</fC03>
<fC03 i1="12" i2="X" l="FRE"><s0>Exciton</s0>
<s5>12</s5>
</fC03>
<fC03 i1="12" i2="X" l="ENG"><s0>Exciton</s0>
<s5>12</s5>
</fC03>
<fC03 i1="12" i2="X" l="SPA"><s0>Excitón</s0>
<s5>12</s5>
</fC03>
<fC03 i1="13" i2="X" l="FRE"><s0>Trempe</s0>
<s5>13</s5>
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<fC03 i1="13" i2="X" l="ENG"><s0>Quenching</s0>
<s5>13</s5>
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<fC03 i1="14" i2="X" l="ENG"><s0>Variance</s0>
<s5>14</s5>
</fC03>
<fC03 i1="14" i2="X" l="SPA"><s0>Variancia</s0>
<s5>14</s5>
</fC03>
<fC03 i1="15" i2="X" l="FRE"><s0>Distribution champ</s0>
<s5>15</s5>
</fC03>
<fC03 i1="15" i2="X" l="ENG"><s0>Field distribution</s0>
<s5>15</s5>
</fC03>
<fC03 i1="15" i2="X" l="SPA"><s0>Distribución campo</s0>
<s5>15</s5>
</fC03>
<fC03 i1="16" i2="X" l="FRE"><s0>Absorption lumière</s0>
<s5>16</s5>
</fC03>
<fC03 i1="16" i2="X" l="ENG"><s0>Light absorption</s0>
<s5>16</s5>
</fC03>
<fC03 i1="16" i2="X" l="SPA"><s0>Absorción luz</s0>
<s5>16</s5>
</fC03>
<fC03 i1="17" i2="X" l="FRE"><s0>Conversion énergie</s0>
<s5>17</s5>
</fC03>
<fC03 i1="17" i2="X" l="ENG"><s0>Energy conversion</s0>
<s5>17</s5>
</fC03>
<fC03 i1="17" i2="X" l="SPA"><s0>Conversión energética</s0>
<s5>17</s5>
</fC03>
<fC03 i1="18" i2="X" l="FRE"><s0>Taux conversion</s0>
<s5>18</s5>
</fC03>
<fC03 i1="18" i2="X" l="ENG"><s0>Conversion rate</s0>
<s5>18</s5>
</fC03>
<fC03 i1="18" i2="X" l="SPA"><s0>Factor conversión</s0>
<s5>18</s5>
</fC03>
<fC03 i1="19" i2="3" l="FRE"><s0>Courant court circuit</s0>
<s5>19</s5>
</fC03>
<fC03 i1="19" i2="3" l="ENG"><s0>Short circuit currents</s0>
<s5>19</s5>
</fC03>
<fC03 i1="20" i2="3" l="FRE"><s0>Tension circuit ouvert</s0>
<s5>20</s5>
</fC03>
<fC03 i1="20" i2="3" l="ENG"><s0>Open circuit voltage</s0>
<s5>20</s5>
</fC03>
<fC03 i1="21" i2="3" l="FRE"><s0>Facteur remplissage</s0>
<s5>21</s5>
</fC03>
<fC03 i1="21" i2="3" l="ENG"><s0>Fill factor</s0>
<s5>21</s5>
</fC03>
<fC03 i1="22" i2="X" l="FRE"><s0>Thiophène dérivé polymère</s0>
<s2>NK</s2>
<s5>22</s5>
</fC03>
<fC03 i1="22" i2="X" l="ENG"><s0>Thiophene derivative polymer</s0>
<s2>NK</s2>
<s5>22</s5>
</fC03>
<fC03 i1="22" i2="X" l="SPA"><s0>Tiofeno derivado polímero</s0>
<s2>NK</s2>
<s5>22</s5>
</fC03>
<fC03 i1="23" i2="X" l="FRE"><s0>Acide butyrique</s0>
<s2>NK</s2>
<s5>23</s5>
</fC03>
<fC03 i1="23" i2="X" l="ENG"><s0>Butyric acid</s0>
<s2>NK</s2>
<s5>23</s5>
</fC03>
<fC03 i1="23" i2="X" l="SPA"><s0>Butírico ácido</s0>
<s2>NK</s2>
<s5>23</s5>
</fC03>
<fC03 i1="24" i2="X" l="FRE"><s0>Ester</s0>
<s5>24</s5>
</fC03>
<fC03 i1="24" i2="X" l="ENG"><s0>Ester</s0>
<s5>24</s5>
</fC03>
<fC03 i1="24" i2="X" l="SPA"><s0>Ester</s0>
<s5>24</s5>
</fC03>
<fC03 i1="25" i2="3" l="FRE"><s0>Composé du fullerène</s0>
<s5>25</s5>
</fC03>
<fC03 i1="25" i2="3" l="ENG"><s0>Fullerene compounds</s0>
<s5>25</s5>
</fC03>
<fC03 i1="26" i2="X" l="FRE"><s0>Oxyde de molybdène</s0>
<s5>26</s5>
</fC03>
<fC03 i1="26" i2="X" l="ENG"><s0>Molybdenum oxide</s0>
<s5>26</s5>
</fC03>
<fC03 i1="26" i2="X" l="SPA"><s0>Molibdeno óxido</s0>
<s5>26</s5>
</fC03>
<fC03 i1="27" i2="X" l="FRE"><s0>Oxyde d'indium</s0>
<s5>27</s5>
</fC03>
<fC03 i1="27" i2="X" l="ENG"><s0>Indium oxide</s0>
<s5>27</s5>
</fC03>
<fC03 i1="27" i2="X" l="SPA"><s0>Indio óxido</s0>
<s5>27</s5>
</fC03>
<fC03 i1="28" i2="X" l="FRE"><s0>MoO3</s0>
<s4>INC</s4>
<s5>82</s5>
</fC03>
<fC03 i1="29" i2="X" l="FRE"><s0>ITO</s0>
<s4>INC</s4>
<s5>83</s5>
</fC03>
<fC03 i1="30" i2="X" l="FRE"><s0>Photovoltaïque organique</s0>
<s4>CD</s4>
<s5>96</s5>
</fC03>
<fC03 i1="30" i2="X" l="ENG"><s0>Organic photovoltaics</s0>
<s4>CD</s4>
<s5>96</s5>
</fC03>
<fN21><s1>101</s1>
</fN21>
</pA>
</standard>
</inist>
</record>
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