CuInS2-Poly(3-(ethyl-4-butanoate)thiophene) nanocomposite solar cells: Preparation by an in situ formation route, performance and stability issues
Identifieur interne : 003245 ( Main/Repository ); précédent : 003244; suivant : 003246CuInS2-Poly(3-(ethyl-4-butanoate)thiophene) nanocomposite solar cells: Preparation by an in situ formation route, performance and stability issues
Auteurs : RBID : Pascal:11-0249594Descripteurs français
- Pascal (Inist)
- Nanomatériau, Cellule solaire, In situ, Evaluation performance, Thiourée, Polymère conjugué, Addition étain, Chauffage, Nanoparticule, Diffusion RX, Microscopie électronique transmission, Couche active, Composé ternaire, Sulfure de cuivre, Sulfure d'indium, Thiophène, Nanocomposite, Cuivre, Indium, Matériau revêtu, Verre, Oxyde d'indium, Zinc, CuInS2, ITO.
- Wicri :
English descriptors
- KwdEn :
- Active layer, Coated material, Conjugated polymer, Copper, Copper sulfide, Glass, Heating, In situ, Indium, Indium oxide, Indium sulfide, Nanocomposite, Nanoparticle, Nanostructured materials, Performance evaluation, Solar cell, Ternary compound, Thiophene, Thiourea, Tin addition, Transmission electron microscopy, X ray scattering, Zinc.
Abstract
In this contribution we present an in situ method for the preparation of CulnS2-poly(3-(ethyl-4-butanoate)thiophene) (P3EBT) nanocomposite layers and their application in nanocomposite solar cells. A precursor solution containing copper and indium salts, thiourea and the conjugated polymer was prepared in pyridine, which was coated onto glass/ITO substrates followed by a heating step at 180°C. The heating step induced the formation of the CuInS2 nanoparticles homogeneously dispersed in the conjugated polymer matrix. The formation of the nanocomposite was investigated in situ by X-ray scattering techniques and TEM methods showing that nano-scaled CuInS2 was formed. By addition of small amounts of zinc salt to the precursor solution, zinc containing CuInS2 (ZCIS) was formed. ZCIS- P3EBT active layers exhibited higher Voc than CuInS2-P3EBT layers and showed efficiencies of about 0.4%. Additionally the stability of the solar cells was tested over a time scale of 172 h.
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-Poly(3-(ethyl-4-butanoate)thiophene) nanocomposite solar cells: Preparation by an in situ formation route, performance and stability issues</title>
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<date when="2011">2011</date>
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<seriesStmt><idno type="ISSN">0927-0248</idno>
<title level="j" type="abbreviated">Sol. energy mater. sol. cells</title>
<title level="j" type="main">Solar energy materials and solar cells</title>
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<profileDesc><textClass><keywords scheme="KwdEn" xml:lang="en"><term>Active layer</term>
<term>Coated material</term>
<term>Conjugated polymer</term>
<term>Copper</term>
<term>Copper sulfide</term>
<term>Glass</term>
<term>Heating</term>
<term>In situ</term>
<term>Indium</term>
<term>Indium oxide</term>
<term>Indium sulfide</term>
<term>Nanocomposite</term>
<term>Nanoparticle</term>
<term>Nanostructured materials</term>
<term>Performance evaluation</term>
<term>Solar cell</term>
<term>Ternary compound</term>
<term>Thiophene</term>
<term>Thiourea</term>
<term>Tin addition</term>
<term>Transmission electron microscopy</term>
<term>X ray scattering</term>
<term>Zinc</term>
</keywords>
<keywords scheme="Pascal" xml:lang="fr"><term>Nanomatériau</term>
<term>Cellule solaire</term>
<term>In situ</term>
<term>Evaluation performance</term>
<term>Thiourée</term>
<term>Polymère conjugué</term>
<term>Addition étain</term>
<term>Chauffage</term>
<term>Nanoparticule</term>
<term>Diffusion RX</term>
<term>Microscopie électronique transmission</term>
<term>Couche active</term>
<term>Composé ternaire</term>
<term>Sulfure de cuivre</term>
<term>Sulfure d'indium</term>
<term>Thiophène</term>
<term>Nanocomposite</term>
<term>Cuivre</term>
<term>Indium</term>
<term>Matériau revêtu</term>
<term>Verre</term>
<term>Oxyde d'indium</term>
<term>Zinc</term>
<term>CuInS2</term>
<term>ITO</term>
</keywords>
<keywords scheme="Wicri" type="concept" xml:lang="fr"><term>Chauffage</term>
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<front><div type="abstract" xml:lang="en">In this contribution we present an in situ method for the preparation of CulnS<sub>2</sub>
-poly(3-(ethyl-4-butanoate)thiophene) (P3EBT) nanocomposite layers and their application in nanocomposite solar cells. A precursor solution containing copper and indium salts, thiourea and the conjugated polymer was prepared in pyridine, which was coated onto glass/ITO substrates followed by a heating step at 180°C. The heating step induced the formation of the CuInS<sub>2</sub>
nanoparticles homogeneously dispersed in the conjugated polymer matrix. The formation of the nanocomposite was investigated in situ by X-ray scattering techniques and TEM methods showing that nano-scaled CuInS<sub>2</sub>
was formed. By addition of small amounts of zinc salt to the precursor solution, zinc containing CuInS<sub>2</sub>
(ZCIS) was formed. ZCIS- P3EBT active layers exhibited higher V<sub>oc</sub>
than CuInS<sub>2</sub>
-P3EBT layers and showed efficiencies of about 0.4%. Additionally the stability of the solar cells was tested over a time scale of 172 h.</div>
</front>
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<fA08 i1="01" i2="1" l="ENG"><s1>CuInS<sub>2</sub>
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<fC01 i1="01" l="ENG"><s0>In this contribution we present an in situ method for the preparation of CulnS<sub>2</sub>
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nanoparticles homogeneously dispersed in the conjugated polymer matrix. The formation of the nanocomposite was investigated in situ by X-ray scattering techniques and TEM methods showing that nano-scaled CuInS<sub>2</sub>
was formed. By addition of small amounts of zinc salt to the precursor solution, zinc containing CuInS<sub>2</sub>
(ZCIS) was formed. ZCIS- P3EBT active layers exhibited higher V<sub>oc</sub>
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<s5>06</s5>
</fC03>
<fC03 i1="06" i2="X" l="ENG"><s0>Conjugated polymer</s0>
<s5>06</s5>
</fC03>
<fC03 i1="06" i2="X" l="SPA"><s0>Polímero conjugado</s0>
<s5>06</s5>
</fC03>
<fC03 i1="07" i2="X" l="FRE"><s0>Addition étain</s0>
<s5>07</s5>
</fC03>
<fC03 i1="07" i2="X" l="ENG"><s0>Tin addition</s0>
<s5>07</s5>
</fC03>
<fC03 i1="07" i2="X" l="SPA"><s0>Adición estaño</s0>
<s5>07</s5>
</fC03>
<fC03 i1="08" i2="X" l="FRE"><s0>Chauffage</s0>
<s5>08</s5>
</fC03>
<fC03 i1="08" i2="X" l="ENG"><s0>Heating</s0>
<s5>08</s5>
</fC03>
<fC03 i1="08" i2="X" l="SPA"><s0>Calefacción</s0>
<s5>08</s5>
</fC03>
<fC03 i1="09" i2="X" l="FRE"><s0>Nanoparticule</s0>
<s5>09</s5>
</fC03>
<fC03 i1="09" i2="X" l="ENG"><s0>Nanoparticle</s0>
<s5>09</s5>
</fC03>
<fC03 i1="09" i2="X" l="SPA"><s0>Nanopartícula</s0>
<s5>09</s5>
</fC03>
<fC03 i1="10" i2="X" l="FRE"><s0>Diffusion RX</s0>
<s5>10</s5>
</fC03>
<fC03 i1="10" i2="X" l="ENG"><s0>X ray scattering</s0>
<s5>10</s5>
</fC03>
<fC03 i1="10" i2="X" l="SPA"><s0>Difusión rayo X</s0>
<s5>10</s5>
</fC03>
<fC03 i1="11" i2="X" l="FRE"><s0>Microscopie électronique transmission</s0>
<s5>11</s5>
</fC03>
<fC03 i1="11" i2="X" l="ENG"><s0>Transmission electron microscopy</s0>
<s5>11</s5>
</fC03>
<fC03 i1="11" i2="X" l="SPA"><s0>Microscopía electrónica transmisión</s0>
<s5>11</s5>
</fC03>
<fC03 i1="12" i2="X" l="FRE"><s0>Couche active</s0>
<s5>12</s5>
</fC03>
<fC03 i1="12" i2="X" l="ENG"><s0>Active layer</s0>
<s5>12</s5>
</fC03>
<fC03 i1="12" i2="X" l="SPA"><s0>Capa activa</s0>
<s5>12</s5>
</fC03>
<fC03 i1="13" i2="X" l="FRE"><s0>Composé ternaire</s0>
<s5>22</s5>
</fC03>
<fC03 i1="13" i2="X" l="ENG"><s0>Ternary compound</s0>
<s5>22</s5>
</fC03>
<fC03 i1="13" i2="X" l="SPA"><s0>Compuesto ternario</s0>
<s5>22</s5>
</fC03>
<fC03 i1="14" i2="X" l="FRE"><s0>Sulfure de cuivre</s0>
<s5>23</s5>
</fC03>
<fC03 i1="14" i2="X" l="ENG"><s0>Copper sulfide</s0>
<s5>23</s5>
</fC03>
<fC03 i1="14" i2="X" l="SPA"><s0>Cobre sulfuro</s0>
<s5>23</s5>
</fC03>
<fC03 i1="15" i2="X" l="FRE"><s0>Sulfure d'indium</s0>
<s5>24</s5>
</fC03>
<fC03 i1="15" i2="X" l="ENG"><s0>Indium sulfide</s0>
<s5>24</s5>
</fC03>
<fC03 i1="15" i2="X" l="SPA"><s0>Indio sulfuro</s0>
<s5>24</s5>
</fC03>
<fC03 i1="16" i2="X" l="FRE"><s0>Thiophène</s0>
<s2>NK</s2>
<s5>25</s5>
</fC03>
<fC03 i1="16" i2="X" l="ENG"><s0>Thiophene</s0>
<s2>NK</s2>
<s5>25</s5>
</fC03>
<fC03 i1="16" i2="X" l="SPA"><s0>Tiofeno</s0>
<s2>NK</s2>
<s5>25</s5>
</fC03>
<fC03 i1="17" i2="X" l="FRE"><s0>Nanocomposite</s0>
<s5>26</s5>
</fC03>
<fC03 i1="17" i2="X" l="ENG"><s0>Nanocomposite</s0>
<s5>26</s5>
</fC03>
<fC03 i1="17" i2="X" l="SPA"><s0>Nanocompuesto</s0>
<s5>26</s5>
</fC03>
<fC03 i1="18" i2="X" l="FRE"><s0>Cuivre</s0>
<s2>NC</s2>
<s5>27</s5>
</fC03>
<fC03 i1="18" i2="X" l="ENG"><s0>Copper</s0>
<s2>NC</s2>
<s5>27</s5>
</fC03>
<fC03 i1="18" i2="X" l="SPA"><s0>Cobre</s0>
<s2>NC</s2>
<s5>27</s5>
</fC03>
<fC03 i1="19" i2="X" l="FRE"><s0>Indium</s0>
<s2>NC</s2>
<s5>28</s5>
</fC03>
<fC03 i1="19" i2="X" l="ENG"><s0>Indium</s0>
<s2>NC</s2>
<s5>28</s5>
</fC03>
<fC03 i1="19" i2="X" l="SPA"><s0>Indio</s0>
<s2>NC</s2>
<s5>28</s5>
</fC03>
<fC03 i1="20" i2="X" l="FRE"><s0>Matériau revêtu</s0>
<s5>29</s5>
</fC03>
<fC03 i1="20" i2="X" l="ENG"><s0>Coated material</s0>
<s5>29</s5>
</fC03>
<fC03 i1="20" i2="X" l="SPA"><s0>Material revestido</s0>
<s5>29</s5>
</fC03>
<fC03 i1="21" i2="X" l="FRE"><s0>Verre</s0>
<s5>30</s5>
</fC03>
<fC03 i1="21" i2="X" l="ENG"><s0>Glass</s0>
<s5>30</s5>
</fC03>
<fC03 i1="21" i2="X" l="SPA"><s0>Vidrio</s0>
<s5>30</s5>
</fC03>
<fC03 i1="22" i2="X" l="FRE"><s0>Oxyde d'indium</s0>
<s5>31</s5>
</fC03>
<fC03 i1="22" i2="X" l="ENG"><s0>Indium oxide</s0>
<s5>31</s5>
</fC03>
<fC03 i1="22" i2="X" l="SPA"><s0>Indio óxido</s0>
<s5>31</s5>
</fC03>
<fC03 i1="23" i2="X" l="FRE"><s0>Zinc</s0>
<s2>NC</s2>
<s5>32</s5>
</fC03>
<fC03 i1="23" i2="X" l="ENG"><s0>Zinc</s0>
<s2>NC</s2>
<s5>32</s5>
</fC03>
<fC03 i1="23" i2="X" l="SPA"><s0>Zinc</s0>
<s2>NC</s2>
<s5>32</s5>
</fC03>
<fC03 i1="24" i2="X" l="FRE"><s0>CuInS2</s0>
<s4>INC</s4>
<s5>82</s5>
</fC03>
<fC03 i1="25" i2="X" l="FRE"><s0>ITO</s0>
<s4>INC</s4>
<s5>83</s5>
</fC03>
<fN21><s1>171</s1>
</fN21>
<fN44 i1="01"><s1>OTO</s1>
</fN44>
<fN82><s1>OTO</s1>
</fN82>
</pA>
<pR><fA30 i1="01" i2="1" l="ENG"><s1>ISOS International Summit on Organic Photovoltaic Stability (OPV) Stability</s1>
<s2>3</s2>
<s3>Roskilde DNK</s3>
<s4>2010-04-19</s4>
</fA30>
</pR>
</standard>
</inist>
</record>
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