Enhanced absorbance of a strained nanoscale Si-layered system

Abstract: Si modifications implemented at the nanoscale lead to optoelectronic and photovoltaic effects that can widen applications of conventional Si devices. The investigation exploits charge carrier and photon flux transformations at a so-called carrier collection limit. Comparison of the collection efficiencies of the same sample with and without a buried nanosystem allows a better understanding of the optical (absorbance) and electronic (carrier collection) behaviors. Experimental evidence for enhanced absorbance o… Show more

“…Fig. 2 shows a comparison of MIND absorption coefficients obtained by PDS and of intrinsic crystalline Si [1]. Over the whole range of indirect bandgap transitions, the absorption coefficients of the strained nanoscale Si-layered system obtained by PDS are much larger (one and a half orders of magnitude) than those of the intrinsic Si (it is also greater than that of the most heavily P-doped Si shown in [6]).…”

“…3). 1 The CE is defined as the mean number of collected carriers per given wavelength photon. 4 shows the differential absorptance of a surface dead zone as a function of its thickness, for different wavelengths.…”

“…The intersection point of two curves for 1.5 eV (small diamonds from [6] and large diamonds from [1]) gives the value of the free carrier density in the MIND structure under the probing laser flux of PDS equipment. P-doping by implantation followed by a pulsed-laser annealing allows maximal/total P solubility in c-Si (ionization rate).…”

“…Optical functions of nanoscale Si-layered systems show a specific behaviour, for example, large absorption coefficients [1], and reflectivity nonlinearities [2]. The MIND (MultiInterface Novel Device [3]), that contains a heavily doped surface zone, will show there effects when exposed to a relatively important illumination.…”

Non-linear optical functions of crystalline-Si resulting from nanoscale layered systems

“…Fig. 2 shows a comparison of MIND absorption coefficients obtained by PDS and of intrinsic crystalline Si [1]. Over the whole range of indirect bandgap transitions, the absorption coefficients of the strained nanoscale Si-layered system obtained by PDS are much larger (one and a half orders of magnitude) than those of the intrinsic Si (it is also greater than that of the most heavily P-doped Si shown in [6]).…”

“…3). 1 The CE is defined as the mean number of collected carriers per given wavelength photon. 4 shows the differential absorptance of a surface dead zone as a function of its thickness, for different wavelengths.…”

“…The intersection point of two curves for 1.5 eV (small diamonds from [6] and large diamonds from [1]) gives the value of the free carrier density in the MIND structure under the probing laser flux of PDS equipment. P-doping by implantation followed by a pulsed-laser annealing allows maximal/total P solubility in c-Si (ionization rate).…”

“…Optical functions of nanoscale Si-layered systems show a specific behaviour, for example, large absorption coefficients [1], and reflectivity nonlinearities [2]. The MIND (MultiInterface Novel Device [3]), that contains a heavily doped surface zone, will show there effects when exposed to a relatively important illumination.…”

Non-linear optical functions of crystalline-Si resulting from nanoscale layered systems

“…The physical parameters used in these simulations are listed in Table 1. In order to compare with the experimental E p 0.033 eV The rate of electron-phonon energy transfer to the lattice [24] g 10 13 -10 15 s À1 Band gap energy [1] U I 9 e V Electron mass [27] m e 9.11 Â 10 À31 kg Electron charge [27] e 1.60 Â 10 À19 C Vacuum permittivity [27] e 0 8.9 Â 10 À12 C 2 /N m 2 Reduced Planck constant [27] £ 1.055 Â 10 À34 J s Scale constant of impact ionization [1] x 1.5 Â 10 15 Cross section for 4-photon absorption [24] s 4 2 Â 10 À114 cm 8 s 3 Reflectivity [25] R 0.927 Absorption coefficient (l = 800 nm) [26] a 1.25 Â 10 5 cm À1 Optical penetration depth d 8 Â 10 À8 m results in Refs. [1] and [21], the multiphoton ionization rates for lasers of wavelength 800 and 1053 nm are computed using the Keldysh's formula in Ref.…”

Ultra-short laser ablation of dielectrics: Theoretical analysis of threshold damage fluence and ablation depth

Photovoltaics literature survey (no. 25)