Atomic Layer Deposition of Vanadium Oxide as Hole‐Selective Contact for Crystalline Silicon Solar Cells

Yang, Xinbo; Xu, Hang; Liu, Wenzhu; Bi, Qunyu; Xu, Lujia; Kang, Jingxuan; Hedhili, Mohamed N.; Sun, Baoquan; Zhang, Xiaohong; Wolf, Stefaan De

doi:10.1002/aelm.202000467

Cited by 77 publications

(87 citation statements)

References 52 publications

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“…Therefore, extensive efforts have been devoted to the improvement of silicon solar cells with dopant‐free passivating contacts. [ 4–9 ] By replacing a‐Si:H(p) with a 4 nm thick hole‐collecting and transparent molybdenum oxide (MoO x ) layer, a remarkable solar cell efficiency of 23.5% was recently demonstrated. [ 10 ] The integration of an a‐Si:H(i)/LiF x /Al electron selective contact at the rear side, instead of a‐Si:H(i)/ a‐Si:H(n)/ITO/Ag, [ 11 ] enabled the development of a fully dopant‐free silicon solar cell without any doped a‐Si:H layers or diffused p–n junctions.…”

Section: Introductionmentioning

confidence: 99%

Dopant‐Free Bifacial Silicon Solar Cells

et al. 2021

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Herein, challenges in the fabrication of full dopant‐free bifacial silicon solar cells are discussed and efficient devices utilizing a MoO3/ indium tin oxide (ITO)/Ag hole‐selective contact and ZnO/LiFx/Al electron‐selective contacts with up to 79% short‐circuit current bifaciality are demonstrated. The ZnO/LiFx/Al rear electron contact features a full‐area ZnO antireflective coating and a LiFx/Al finger contact, allowing sunlight absorption from the back side, thus producing more overall power. The ZnO/LiFx/Al electron contacts with a thinner ZnO layer and a larger contact fraction display a better selectivity and a lower resistance loss. When considering rear‐side irradiance of 0.15 sun, the dopant‐free bifacial solar cell with 60 nm ZnO and 50% LiFx/Al metal contact fraction achieves a 3% estimated output power density improvement compared with its monofacial counterpart (21.0 mW cm−2 compared to 20.3 mW cm−2) using the full‐area back contact. Both the efficiency and bifaciality factor of this dopant‐free device are still significantly lower than those of state‐of‐the‐art devices relying on doped‐silicon‐based layers. The required improvement for this technology to become industry‐relevant is discussed.

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Section: Introductionmentioning

confidence: 99%

Dopant‐Free Bifacial Silicon Solar Cells

et al. 2021

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“…Transition metal oxides (TMOs) have been widely used as hole or electron selective transporting layers in crystalline silicon (c‐Si) solar cells to reduce the Fermi‐level pinning effect and to extract holes or free electrons in silicon at metal/silicon interface. [ 1–5 ] TMOs with high work functions (generally over 5.0 eV), such as MoO x , [ 6–10 ] VO x , [ 11,12 ] and WO x , [ 13 ] are applied as hole‐selective transporting layers. In contrast, TMOs with low work functions (generally below 4.0 eV), such as TiO x [ 14 ] and MgO x , [ 15,16 ] are applied as electron‐selective transporting layers.…”

Section: Introductionmentioning

confidence: 99%

Solution‐Processed Copper‐Doped Chromium Oxide with Tunable Oxygen Vacancy for Crystalline Silicon Solar Cells Hole‐Selective Contacts

Peng

Lin

et al. 2021

Solar RRL

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Compared with vacuum evaporation, metal oxides deposited by solution process exhibit advantages, for example, dopants can be easily incorporated in a wide range and the contents are easy to be regulated by changing the composition of precursors. Herein, solution‐processed p‐type copper‐doped chromium oxide (Cu:CrOx) films with tunable oxygen vacancy are demonstrated via a postannealing process. The synthetic and postannealing temperature have a significant impact on the chromium cation oxidation state in the Cu:CrOx films, leading to the variation of work function for the oxide films. By adjusting the work function of Cu:CrOx films, a low contact resistivity of 95 mΩ cm2 can be realized for the Ag/Cu:CrOx/p‐Si contact. Finally, the optimized Cu:CrOx films are used as the hole transporting layer in c‐Si solar cells, showing an increased power conversion efficiency from 15.2% (without Cu:CrOx) to 16.9% (with Cu:CrOx). The results show an effective stage to use p‐type metal oxides as a hole‐selective layer in c‐Si solar cells.

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“…Specifically, low‐workfunction metal oxides, nitrides, and 2D materials, such as TiO 2 , TaO x , ZnO, TaN x , TiN, and MXenes have been reported as electron‐selective layers (ESLs), and high‐workfunction MoO x and VO x have been developed as hole‐selective layers (HSLs) for c‐Si solar cells. [ 5,10–22 ] The band energetics of these thin films play a crucial role in achieving carrier selectivity of the contacts. Generally, the work function of the ESL in an electron‐selective contact is required to be close to or lower than the conduction band minimum (CBM) of c‐Si (≈4.05 eV, relative to the vacuum level).…”

Section: Introductionmentioning

confidence: 99%

Electron‐Selective ‍Lithium Contacts for Crystalline Silicon Solar Cells

Kang

Yang

Liu

et al. 2021

Adv Materials Inter

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Separating photogenerated charge carriers by carrier‐selective heterostructure contacts rather than by doped homojunctions is a promising pathway to approach the theoretical power conversion efficiency (PCE) limit of crystalline silicon (c‐Si) solar cells. An electron‐selective, hole‐blocking lithium contact for c‐Si solar cells is presented by simple thermal evaporation of air‐stable Li3N powder. It is found that this lithium contact introduces only a minimal Schottky‐barrier height for electron transport at its interface with lightly doped n‐type c‐Si surfaces, resulting in a low contact resistivity of 12.8 mΩ cm2. By implementing a full‐area electron‐selective lithium contact, an n‐type c‐Si solar cell with a PCE of 19% is achieved, representing a 4% absolute PCE improvement over reference devices with an aluminum contact. The choices of electron‐selective contact materials for photovoltaic devices, using simple, scalable fabrication methods are extended.

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Atomic Layer Deposition of Vanadium Oxide as Hole‐Selective Contact for Crystalline Silicon Solar Cells

Cited by 77 publications

References 52 publications

Dopant‐Free Bifacial Silicon Solar Cells

Dopant‐Free Bifacial Silicon Solar Cells

Solution‐Processed Copper‐Doped Chromium Oxide with Tunable Oxygen Vacancy for Crystalline Silicon Solar Cells Hole‐Selective Contacts

Electron‐Selective ‍Lithium Contacts for Crystalline Silicon Solar Cells

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