Phosphorus incorporation during Si(001):P gas-source molecular beam epitaxy: Effects on growth kinetics and surface morphology

Cho, B.; Bareño, Javier; Foo, Y. L.; Hong, Sung Je; Spila, T.; Petrov, I.; Greene, J. E.

doi:10.1063/1.2925798

Cited by 21 publications

(21 citation statements)

References 30 publications

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“…A NW array supports no additional coupled mode because of the low quality factor of a single NW cavity. Therefore, if the light absorption in a single NW is appropriately tuned by tailoring the NW's morphology or composition [8,[14][15][16][17][18], a NW array composed of these single NWs will possess the same absorption features as that of a single NW. This demonstrates the importance of optical design at the single-NW level.…”

Section: Close-packed Nw Array With Various Cross-sectional Morphologiesmentioning

confidence: 99%

“…Nanowires (NWs) are well-suited for a variety of optoelectronic applications [1][2][3][4][5][6][7][8][9][10][11][12][13] in part because their morphology [8,14,15] and composition [16][17][18] can be finely tuned during synthesis rather than post hoc as in top-down fabrication. In addition, NWs can have diameters less than the wavelength of light, allowing for large scattering to physical cross section [19,20] and localized optical resonances [7,8].…”

Section: Introductionmentioning

confidence: 99%

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Laterally assembled nanowires for ultrathin broadband solar absorbers

Song¹,

Kempa²,

Park³

et al. 2014

Opt. Express

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We studied optical resonances in laterally oriented Si nanowire arrays by conducting finite-difference time-domain simulations. Localized Fabry-Perot and whispering-gallery modes are supported within the cross section of each nanowire in the array and result in broadband light absorption. Comparison of a nanowire array with a single nanowire shows that the current density (J(SC)) is preserved for a range of nanowire morphologies. The J(SC) of a nanowire array depends on the spacing of its constituent nanowires, which indicates that both diffraction and optical antenna effects contribute to light absorption. Furthermore, a vertically stacked nanowire array exhibits significantly enhanced light absorption because of the emergence of coupled cavity-waveguide modes and the mitigation of a screening effect. With the assumption of unity internal quantum efficiency, the J(SC) of an 800-nm-thick cross-stacked nanowire array is 14.0 mA/cm², which yields a ~60% enhancement compared with an equivalent bulk film absorber. These numerical results underpin a rational design strategy for ultrathin solar absorbers based on assembled nanowire cavities.

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Section: Close-packed Nw Array With Various Cross-sectional Morphologiesmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Laterally assembled nanowires for ultrathin broadband solar absorbers

Song¹,

Kempa²,

Park³

et al. 2014

Opt. Express

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“…89 Polarization-resolved EQE spectra for devices fabricated from such rectangular NWs reveal several new features. In the TE spectrum of the 260 nm diameter NW ( Figure 11A, black straight), a peak centered at 570 nm shows a nearly-unity EQE amplitude, whereas bulk Si would require ~3.3 µm of material to produce the same EQE value at this wavelength.…”

Section: Section 4)mentioning

confidence: 99%

Semiconductor nanowires: a platform for exploring limits and concepts for nano-enabled solar cells

Kempa

Day

Kim

et al. 2013

Energy Environ. Sci.

203

133

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Abstract:Over the past decade extensive studies of single semiconductor nanowire and nanowire array photovoltaic devices have explored the potential of these materials as platforms for a new generation of efficient and cost-effective solar cells. This feature review discusses strategies for implementation of semiconductor nanowires in solar energy applications, including advances in complex nanowire synthesis and characterization, fundamental insights from characterization of devices, utilization and control of the unique optical properties of nanowires, and new strategies for assembly and scaling of nanowires into diverse arrays that serve as a new paradigm for advanced solar cells. 2 Table of Contents Entry:Advanced synthetic control over the electronic and optical properties of semiconductor nanowires enables testing new paradigms for advanced solar cells. Broader Context Box:The solar power received by the earth dwarfs global power demands by several orders-ofmagnitude. Photovoltaics convert light to electrical energy and have the potential to partially replace current energy technologies that rely on carbon-based fuels. At present, however, a lack of infrastructure and the high costs of photovoltaics prevent this. New ideas and materials are being explored to develop next-generation solar cells that could operate more efficiently and cheaply. Nanowires have emerged as one promising platform to explore such new concepts.Their small dimensions allow for efficient charge separation and light absorption properties unique as compared to bulk materials. Furthermore, the synthesis and fabrication of nanowire devices differs significantly from traditional wafer-based technologies, thus presenting new opportunities such as use of less abundant materials or cheaper substrates. Here, we discuss the benefits and remaining challenges of nanowires for PV and review progress towards understanding and optimizing the electrical and optical performance of nanowire devices. We focus on single nanowire studies that can define limits for what is achievable when multiple nanowires are assembled. Challenges and initial progress towards scaling are presented, and, for the first time, we articulate unique capabilities of solar cells derived from multiple, distinct NWs. 6

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“…The reaction of phosphine with silicon (001) has been extensively studied using numerous experimental techniques including STM 8,9,[14][15][16][17][18][19] , temperature programmed desorption [20][21][22][23][24][25] , low energy electron diffraction 20,24 , and several kinds of spectroscopy 9, 16,17,26,27 . Extensive theoretical modeling 19,[28][29][30][31][32][33] in conjunction with detailed STM images provided a consistent interpretation of the first stage of this reaction, namely the thermal dissociation of PH 3 into phosphorus and hydrogen adatoms.…”

Section: Introductionmentioning

confidence: 99%

Diffusion pathways of phosphorus atoms on silicon (001)

et al. 2009

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Using density functional theory and a combination of growing string and dimer method transition state searches, we investigate the interaction of phosphorus atoms with the silicon (001) surface.We report reaction pathways for three technologically important processes: diffusion of phosphorus adatoms on the surface, incorporation of the phosphorus adatom into the surface, and diffusion of the incorporated phosphorus atom within the surface. These reactions have direct relevance to nanoscale lithographic schemes capable of positioning single phosphorus atoms on the silicon surface. Temperatures of activation for the various processes are calculated and, where possible, compared with experiment.

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Phosphorus incorporation during Si(001):P gas-source molecular beam epitaxy: Effects on growth kinetics and surface morphology

Cited by 21 publications

References 30 publications

Laterally assembled nanowires for ultrathin broadband solar absorbers

Laterally assembled nanowires for ultrathin broadband solar absorbers

Semiconductor nanowires: a platform for exploring limits and concepts for nano-enabled solar cells

Diffusion pathways of phosphorus atoms on silicon (001)

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