Experimental verification of intermediate band formation on titanium-implanted silicon

Castán, Helena; Perez, E.; García, Héctor; Dueñas, S.; Bailón, L.; Olea, J.; Pastor, David; García-Hemme, E.; Irigoyen, Maite; González-Dı́az, G.

doi:10.1063/1.4774241

Cited by 35 publications

(27 citation statements)

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“…16 Other works report values of energy under 10 meV: Antonov et al found a MN energy of 6.9 meV in the diffusion of nanoclusters and islands on solid Xe. 17 The same group 18 studied nanoclusters and islands on CO 2 , obtaining a MN energy of approximately 9 meV, in agreement with the most active phonon band for solid CO 2 .…”

Section: -2mentioning

confidence: 73%

“…The main goal of these studies is the formation of an intermediate band (IB) in the midgap of the semiconductor to induce infrared absorption in this material. 1,2 This approach would enable electrons to be pumped from the valence band (VB) into conduction band (CB) via two-photon absorption with lower energy than the semiconductor band gap. 3 There are two main reasons why obtaining this target is so interesting.…”

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confidence: 99%

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Energy levels distribution in supersaturated silicon with titanium for photovoltaic applications

Perez

Castán

García

et al. 2015

Applied Physics Letters

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In the attempt to form an intermediate band in the bandgap of silicon substrates to give it the capability to absorb infrared radiation, we studied the deep levels in supersaturated silicon with titanium. The technique used to characterize the energy levels was the thermal admittance spectroscopy. Our experimental results showed that in samples with titanium concentration just under Mott limit there was a relationship among the activation energy value and the capture cross section value. This relationship obeys to the well known Meyer-Neldel rule, which typically appears in processes involving multiple excitations, like carrier capture/emission in deep levels, and it is generally observed in disordered systems. The obtained characteristic Meyer-Neldel parameters were Tmn = 176 K and kTmn = 15 meV. The energy value could be associated to the typical energy of the phonons in the substrate. The almost perfect adjust of all experimental data to the same straight line provides further evidence of the validity of the Meyer Neldel rule, and may contribute to obtain a deeper insight on the ultimate meaning of this phenomenon.

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Section: -2mentioning

confidence: 73%

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confidence: 99%

Energy levels distribution in supersaturated silicon with titanium for photovoltaic applications

Perez

Castán

García

et al. 2015

Applied Physics Letters

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“…As it was assumed, occurrence of this new band could allow the photons of energy lower than E g to be absorbed, generating additional photocurrent and consequently, increasing the PV cells efficiency. The possibility of IB formation was confirmed experimentally for different impurities such as titanium [12], sulphur [13], selenium and tellurium [14]. Moreover, this may be be possible for other elements such as chalcogens or transition metals.…”

Section: Introductionmentioning

confidence: 57%

“…As it was pointed out, some of the recorded plots did not reveal symptoms of the existence of any deep levels. According to what was suggested in [12], such tendency coincides with the IB theory which assumes that recombination is suppressed when the IB band is formed. However, in order to confirm whether the intermediate band was actually formed, it is necessary to perform further analyses.…”

Section: Discussionmentioning

confidence: 87%

“…In this context, it is reasonable to investigate if it is possible to induce a shift in the value of E g using appropriately configured ion implantation and whether such operation will influence the performance of PV cells. Since the ion implantation and post-implantation treatment are the processes that require predetermining of a number of correlated variables, the aspect of consideration was a matter of many experimental and theoretical studies [11][12][13][14][15].…”

Section: Introductionmentioning

confidence: 99%

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Application of Ion Implantation for Intermediate Energy Levels Formation in the Silicon-Based Structures Dedicated for Photovoltaic Purposes

Billewicz

Węgierek

Grudniewski³

et al. 2017

Acta Phys. Pol. A

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The main aim of the research was to verify if it is possible to create the intermediate energy levels in silicon by means of ion implantation as well as to confirm whether the intermediate band could arise. The tests covered recording of conductance and capacitance of antimony-doped silicon, implanted with Ne + ions. As a result, it was possible to identify a single deep level in the sample and determine its location in the band gap by estimating the value of activation energy.

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On the Optoelectronic Mechanisms Ruling Ti‐hyperdoped Si Photodiodes

García-Hemme

Caudevilla

Algaidy

et al. 2021

Adv Elect Materials

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room temperature to the short-wavelength infrared (SWIR) range (1.4-3 µm, i.e., 0.89-0.41 eV) has the potential to revolutionize silicon-based optoelectronic devices. The introduction of a complementary metaloxide semiconductor (CMOS) compatible process would enable the integration of optical and electronic functionality on a single chip. [1] Nowadays, several approaches are under intensive research to enhance Si SWIR photoresponse, such as the integration of III-V compound semiconductors with silicon, [2,3] photodetectors based on SiGe alloys [4,5] or HgCdTe/Si heterostructures. [6] Despite their high performances, these devices suffer from several drawbacks: they are based on nonabundant or contaminant materials, they usually require cryogenic temperatures to operate, and they are hardly integrated into the very mature Si-CMOS fabrication routes, adding considerable cost and complexity to photonic circuit manufacturing.An alternative path to increase the Si SWIR photoresponse that would avoid the hybrid integration of Si technology with unconventional materials is the direct modification of its electronic band structure. From this perspective it is possible to find interesting approaches. One is the use of a laser-crystallization process to induce an anisotropic tensile stress in silicon optical fibers. This way the bandgap can be reduced from 1.11 to 0.59 eV. [7] Unfortunately, the fiber structure hinders its incorporation into planar imaging arrays. A different method, that has attracted recently great attention, [8] is the extrinsic sub-bandgap photoresponse obtained from the incorporation of deep-level impurities at concentrations far above their equilibrium values. Single-crystalline silicon layers with transition metals (Ti, V, Au, and Ag) or chalcogens (S, Se, and Te) at concentrations above 10 19 cm -3 have been obtained by means of ion implantation and subsecond annealing techniques (in a process denominated as supersaturation or hyperdoping). We have shown that silicon hyperdoped with Ti [9,10] or V [11] presents outstanding properties such as a sub-bandgap optical absorption coefficient in the 10 4 cm -1 range [12] or a photoconductive response extended down to 0.2 eV (6.2 µm) at cryogenic temperatures. [13] Gold hyperdoped [14,15] or silver hyperdoped [16] This work deepens the understanding of the optoelectronic mechanisms ruling hyperdoped-based photodevices and shows the potential of Ti hyperdoped-Si as a fully complementary metal-oxide semiconductor compatible material for room-temperature infrared photodetection technologies. By the combination of ion implantation and laser-based methods, ≈20 nm thin hyperdoped single-crystal Si layers with a Ti concentration as high as 10 20 cm −3 are obtained. The Ti hyperdoped Si/p-Si photodiode shows a room temperature rectification factor at ±1 V of 509. Analysis of the temperature-dependent current-voltage characteristics shows that the transport is dominated by two mechanisms: a tunnel mechanism at low bias and a recombination process in the space charge...

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Experimental verification of intermediate band formation on titanium-implanted silicon

Cited by 35 publications

References 16 publications

Energy levels distribution in supersaturated silicon with titanium for photovoltaic applications

Energy levels distribution in supersaturated silicon with titanium for photovoltaic applications

Application of Ion Implantation for Intermediate Energy Levels Formation in the Silicon-Based Structures Dedicated for Photovoltaic Purposes

On the Optoelectronic Mechanisms Ruling Ti‐hyperdoped Si Photodiodes

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