Impact of silicon quantum dot super lattice and quantum well structure as intermediate layer on p‐i‐n silicon solar cells

Rahman, Mohammad Maksudur; Lee, Ming-Yi; Tsai, Yi-Chia; Higo, Akio; Sekhar, Halubai; Igarashi, Makoto; Syazwan, Mohd Erman; Hoshi, Yusuke; Sawano, Kentarou; Usami, Noritaka; Li, Yiming; Samukawa, Seiji

doi:10.1002/pip.2726

Cited by 20 publications

(7 citation statements)

References 34 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Improvements in the efficiency and performance of photovoltaic (PV) cells have been achieved by introducing new materials and concepts, such as organic (dye-sensitized), inorganic (Si QD) and hybrid (perovskite) solar cells. [1][2][3][4][5] Silicon-wafer-based solar cells have dominated the global market with a share exceeding 90% due to their abundant source material and well-known physical and chemical properties. 6) Crystalline silicon (c-Si) solar cells with thicknesses of 180-200 µm are now available in the market.…”

Section: Introductionmentioning

confidence: 99%

The impact of subsurface damage on the fracture strength of diamond-wire-sawn monocrystalline silicon wafers

Sekhar

Fukuda

Tanahashi

et al. 2018

Jpn. J. Appl. Phys.

Self Cite

View full text Add to dashboard Cite

We describe a multi-diamond-wire saw for cutting monocrystalline silicon bricks into thin (120 µm) and thick (200 µm) wafers and label as freshand worn-wire sides. While almost no difference was found in the fracture stress of the thick (200 µm) wafers cut from either side, the thin (120 µm) wafers showed a lower fracture stress in those from the fresh-wire side compared to the worn-wire side. This is a remarkable result when wafers are sawn with conventional diamond wire. On the contrary, wafers sawn with improved diamond wire (100d-M6/12) showed a higher fracture stress compared to those cut with conventional diamond wire (100d-M8/16), for both the fresh-and worn-wire sides. Observing the subsurface areas of wafers by micro-Raman spectroscopy, we succeeded in quantifying the defective silicon fraction as the Raman crystallinity factor (Φ c ). We found that wafers having a higher fracture strength had a larger Φ c .

show abstract

Section: Introductionmentioning

confidence: 99%

The impact of subsurface damage on the fracture strength of diamond-wire-sawn monocrystalline silicon wafers

Sekhar

Fukuda

Tanahashi

et al. 2018

Jpn. J. Appl. Phys.

Self Cite

View full text Add to dashboard Cite

show abstract

“…Improving cell efficiencies and reducing production costs are ongoing issues in the silicon (Si) photovoltaic (PV) industry and are being addressed by implementing innovative concepts and techniques. [1][2][3][4][5] Cutting Si bricks into wafers is the first step in the process of manufacturing Si solar modules. Wafer preparation costs including the sawing process accounts for approximately 30% of the total manufacturing cost.…”

Section: Introductionmentioning

confidence: 99%

The impact of saw mark direction on the fracture strength of thin (120 µm) monocrystalline silicon wafers for photovoltaic cells

Sekhar

Fukuda

Tanahashi

et al. 2018

Jpn. J. Appl. Phys.

Self Cite

View full text Add to dashboard Cite

Using a multi-diamond-wire saw, we cut monocrystalline silicon bricks into thin (120 µm) wafers, on which we observed saw marks and elongated pits with surface cracks. To address the fracture issues, we performed three-line bending tests with the load applied in the parallel and perpendicular direction to the saw mark direction. Under parallel loading, pits and accompanying cracks resulted in lower fracture strength than under perpendicular loading and the wafers were clearly separated into two groups: lower-strength wafers from the fresh-wire side and higher-strength wafers from the worn-wire side. Under perpendicular loading, the pits and surface cracks had less effect, resulting in higher strength. Using Raman spectroscopy, we confirmed that the wafers from the fresh-wire side had a higher fraction of slicing damage on the surface and subsurface region than those from the worn-wire side. This damage resulted in lower-strength wafers in the parallel loading test.

show abstract

“…Silicon quantum dots (Si QDs) have attracted a great deal of interest in the field of photovoltaic energy, solid‐state illumination, flat panel display, optoelectronic integration, and biological detection because they are stable, nontoxic, environmental friendly, and compatible with current Si‐based technology. In order to improve the optoelectronic performance, the luminescent efficiency of Si QDs needs to be further improved since bulk Si is a kind of indirect bandgap material.…”

Section: Introductionmentioning

confidence: 99%

Dual Management of Electrons and Photons to Get High‐Performance Light Emitting Devices Based on Si Nanowires and Si Quantum Dots with Al₂O₃‐Ag Hybrid Nanostructures

Lin

Liu

et al. 2018

Part & Part Syst Charact

View full text Add to dashboard Cite

Silicon quantum dot (Si QD)‐based light emitting devices are fabricated on Si nanowire (Si NW) arrays. Through inserting Al2O3‐Ag hybrid nanostructures (Al2O3‐Ag HNs) between Si NWs and Si QDs, both photoluminescence (PL) and electroluminescence (EL) are remarkably enhanced compared to the control sample. The PL enhancement can be mainly attributed to passivation effect of Al2O3 to p‐type Si NWs and enlarged absorption cross‐section due to the local surface plasmon resonance effect of Ag nanoparticles. The EL intensity is enhanced by 14.9‐fold at the same injection current under a lower applied voltage, which may result from the high injection efficiency of electrons and the promoted waveguide effect of nanowire structures with Al2O3‐Ag HNs. It is demonstrated that light emitting device performances can be well improved by careful management of both electrons and photons via controlling the interface conditions of Si NWs/Si QDs.

show abstract

Impact of silicon quantum dot super lattice and quantum well structure as intermediate layer on p‐i‐n silicon solar cells

Cited by 20 publications

References 34 publications

The impact of subsurface damage on the fracture strength of diamond-wire-sawn monocrystalline silicon wafers

The impact of subsurface damage on the fracture strength of diamond-wire-sawn monocrystalline silicon wafers

The impact of saw mark direction on the fracture strength of thin (120 µm) monocrystalline silicon wafers for photovoltaic cells

Dual Management of Electrons and Photons to Get High‐Performance Light Emitting Devices Based on Si Nanowires and Si Quantum Dots with Al₂O₃‐Ag Hybrid Nanostructures

Contact Info

Product

Resources

About

Impact of silicon quantum dot super lattice and quantum well structure as intermediate layer on p‐i‐n silicon solar cells

Cited by 20 publications

References 34 publications

The impact of subsurface damage on the fracture strength of diamond-wire-sawn monocrystalline silicon wafers

The impact of subsurface damage on the fracture strength of diamond-wire-sawn monocrystalline silicon wafers

The impact of saw mark direction on the fracture strength of thin (120 µm) monocrystalline silicon wafers for photovoltaic cells

Dual Management of Electrons and Photons to Get High‐Performance Light Emitting Devices Based on Si Nanowires and Si Quantum Dots with Al2O3‐Ag Hybrid Nanostructures

Contact Info

Product

Resources

About

Dual Management of Electrons and Photons to Get High‐Performance Light Emitting Devices Based on Si Nanowires and Si Quantum Dots with Al₂O₃‐Ag Hybrid Nanostructures