238 research outputs found
Inelastic Scattering and Current Saturation in Graphene
We present a study of transport in graphene devices on polar insulating
substrates by solving the Bolzmann transport equation in the presence of
graphene phonon, surface polar phonon, and Coulomb charged impurity scattering.
The value of the saturated velocity shows very weak dependence on the carrier
density, the nature of the insulating substrate, and the low-field mobility,
varied by the charged impurity concentration. The saturated velocity of 4 - 8 x
10^7 cm/s calculated at room temperature is significantly larger than reported
experimental values. The discrepancy is due to the self-heating effect which
lowers substantially the value of the saturated velocity. We predict that by
reducing the insulator oxide thickness, which limits the thermal conductance,
the saturated currents can be significantly enhanced. We also calculate the
surface polar phonon contribution to the low-field mobility as a function of
carrier density, temperature, and distance from the substrate.Comment: 8 pages 9 figure
Measurements of Carrier Generation-Recombination Parameters in Silicon Solar Cell Material Using MOS Techniques
Modified and new measurement techniques were developed for determining the carrier generation-recombination (G-R) parameters in silicon solar cell material under carrier deficit and low-level carrier excess conditions using MOS-based test structures. The structures mainly consisted of ring-dot MOS Capacitors (MOS-C) and Schottky-Drained Gate-Controlled Diodes (SGCD). Sample G-R parameters were extracted from n-type high quality silicon solar cell material. Additional measurements were also performed on low-quality ntype silicon substrates for comparison purposes. The photoaccelerated MOS-C Capacitance-time (C-t) transient measurement technique, modified from the standard C-t method, allows one to drastically reduce the observation time in deducing the carrier generation lifetime (Tg) by simply illuminating the test structure during the transient. In applying the technique to MOS-C’s (which exhibited generation lifetime on the order of I msec) the observation time was reduced by approximately an order of magnitude. This is important in dealing with solar cell material because of typically long generation lifetimes. The SGCD structure, which consisted of an extended Schottky diode located next to an MOS-C, was developed and utilized for extracting the surface generation velocity (sg). The measurement is based on recording two C-t transients at Vd = 0 and at Vd = V t , respectively. The structure has a distinct advantage over the conventional PN junction GCD in that it is only slightly more complicated to fabricate and interrogate than a simple MOS-C. It was also demonstrated that steady-state deep-depletion C-V characteristics can be obtained using the SGCD structure. An MOS-C photo/forward-sweep measurement technique was primarily developed to extract the recombination lifetime (rp for n-type substrates) under low-level carrier excess conditions. The new technique is based on the change in inversion capacitance in response to a set of illumination and forward-sweep voltages applied to the MOS-C. The technique conveniently allows one to extract the recombination lifetime under room temperature conditions and was successfully applied to MOS-C’s fabricated on high quality silicon solar cell substrates
Electron-Hole Generation and Recombination Rates for Coulomb Scattering in Graphene
We calculate electron-hole generation and recombination rates for Coulomb
scattering (Auger recombination and impact ionization) in Graphene. The
conduction and valence band dispersion relation in Graphene together with
energy and momentum conservation requirements restrict the phase space for
Coulomb scattering so that electron-hole recombination times can be much longer
than 1 ps for electron-hole densities smaller than cm.Comment: 13 pages, 7 figure
Theoretical study of isolated dangling bonds, dangling bond wires and dangling bond clusters on H:Si(100)-(21) surface
We theoretically study the electronic band structure of isolated unpaired and
paired dangling bonds (DB), DB wires and DB clusters on H:Si(100)-(21)
surface using Extended H\"uckel Theory (EHT) and report their effect on the Si
band gap. An isolated unpaired DB introduces a near-midgap state, whereas a
paired DB leads to and states, similar to those introduced by an
unpassivated asymmetric dimer (AD) Si(100)-(21) surface. Such induced
states have very small dispersion due to their isolation from the other states,
which reside in conduction and valence band. On the other hand, the surface
state induced due to an unpaired DB wire in the direction along the dimer row
(referred to as ), has large dispersion due to the strong coupling
between the adjacent DBs, being 3.84 apart. However, in the direction
perpendicular to the dimer row (referred to as [110]), due to the reduced
coupling between the DBs being 7.68 apart, the dispersion in the surface
state is similar to that of an isolated unpaired DB. Apart from this, a paired
DB wire in direction introduces and states similar
to those of an AD surface and a paired DB wire in [110] direction exhibits
surface states similar to those of an isolated paired DB, as expected. Besides
this, we report the electronic structure of different DB clusters, which
exhibit states inside the band gap that can be interpreted as superpositions of
states due to unpaired and paired DBs.Comment: 7 pages, 10 figure, 1 tabl
Basic Studies of III-V High Efficiency Cell Components
The objective of the project is to raise the understanding of dark current mechanisms in GaAs-related solar cells to a level comparable to that of silicon cells. Motivation for this work arises from the observation that much of the progress in crystalline silicon cell performance has occurred as a result of a very deep knowledge of the physics controlling the cell’s dark current. Based on this knowledge, new cell structures evolved to suppress dominant dark current mechanisms. A comparable level of knowledge of GaAs cell device physics does not yet exist, but will be essential if cell performance near the thermodynamic limit is to be achieved. Moreover, knowledge gained from studies of the AlGaAs/GaAs material system, should help identify the key problems to be addressed in other III-V materials
Zinc Oxide-on-Silicon Surface Acoustic Wave Devices
A monolithic ZnO-on-silicon surface acoustic wave (SAW) memory correlator has been fabricated which utilizes induced junctions separated by ion implanted regions to store a reference signal. The performance characteristics of this device have been investigated including storage time, dynamic range, and degenerate convolution efficiency. Verification of the existence of charge storage regions is possible prior to completed device fabrication. A theory explaining the charge storage process is developed and applied to the implant-isolated storage correlator. The implant-isolated correlator theory is applied to related structures which employ slightly different storage mechanisms. The ion implanted correlator is used to determine the wave potential associated with a propagating SAW. Characteristics of ZnO-on-Si SAW resonators with sputtered ZnO films limited to the interdigital transducer (IDT) regions are investigated. Upper limits on propagation loss for surface waves on silicon substrates are determined by employing externally coupled limited ZnO SAW resonators. Resonator Q-values are enhanced by restricting the lossy ZnO area and predictions are made as to achievable Q-values for resonators fabricated in the externally coupled configuration. Experimental results for limited ZnO, internally coupled ZnO-on-Si resonators are also given. A complete theory for the mode conversion resonator is presented which predicts the array separation for proper device operation. The theory also gives way to a special condition for spatial ndependence of resonator output with respect to IDT placement. Mode conversion resonators are fabricated which experimentally verify these predictions
Orientation-dependent perimeter recombination in GaAs diodes
Perimeter recombination currents affect the performance of GaAs-based devices such as solar cells, heterojunction bipolar transistors, and injection lasers. We report that the n SEf 2 perimeter recombination current has a strong orientation dependence. More than a factor of five variation in the surface recombination current at mesa-etched edges has been observed. These results suggest that with proper device design, perimeter recombination currents could be substantially reduced
Bifacial Si heterojunction-perovskite organic-inorganic tandem to produce highly efficient (η T * ~ 33%) solar cell
As single junction photovoltaic (PV) technologies both Si heterojunction (HIT) and perovskite based solar cells promise high efficiencies at low cost. Intuitively a traditional tandem cell design with these cells connected in series is expected to improve the efficiency further. Using a self-consistent numerical modeling of optical and transport characteristics however we find that a traditional series connected tandem design suffers from low JSC due to band-gap mismatch and current matching constraints. Specifically a traditional tandem cell with state-of-the-art HIT ( η=24% ) and perovskite ( η=20% ) sub-cells provides only a modest tandem efficiency of ηT~ 25%. Instead we demonstrate that a bifacial HIT/perovskite tandem design decouples the optoelectronic constraints and provides an innovative path for extraordinary efficiencies. In the bifacial configuration the same state-of-the-art sub-cells achieve a normalized output of η∗T  = 33% exceeding the bifacial HIT performance at practical albedo reflections. Unlike the traditional design this bifacial design is relatively insensitive to perovskite thickness variations which may translate to simpler manufacture and higher yield
Basic Studies of III-IV High Efficiency Cell Components
The objective of the project is to raise the understanding of dark current mechanisms in GaAs-related solar cells to a level comparable to that of silicon cells. Motivation for this work arises from the observation that much of the progress in crystalline silicon cell performance has occurred as a result of a very deep knowledge of the physics controlling the cell’s dark current. Based on this knowledge, new cell structures evolved to suppress dominant dark current mechanisms. A comparable level of knowledge of GaAs cell device physics does not yet exist, but will be essential if cell performance near the thermodynamic limit is to be achieved
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