A study of cuprous oxide solid photoelectric cells,

Fogle, Marlin Earnest,

January 1934

Thesis (PH. D.)--Columbia University, 1934. / Vita.

Photoelectric cells. Cuprous oxide.

Semi-conductor photocells and rectifiers; a new cuprous ocide photocell ...

Adler, Edward,

January 1940

Thesis (Ph. D.)--Columbia University, 1940. / Transactions of the Electrochemical society, Preprint 79-1 and 79-6, 1940. Vita. Includes bibliographical references.

Photoelectric cells. Cuprous oxide.

Resonance Raman scattering and optical reflectivity studies of ion implantation-produced damage in cuprous oxide

Hesse, Joseph Fredrick

January 2011

Typescript. / Digitized by Kansas Correctional Industries

Ion implantation

Raman spectroscopy

Semiconductors

Cuprous oxide

Study on the Growth and Characterization of Epitaxial Cu2O Thin Films by Magnetron Sputtering

Lin, Chaio-Wei,

30 August 2012

Cuprous oxide (Cu2O) was first investigated in the 1920s as a semiconductor material with Eg~2.17 eV. It is ideal for applications in solar cells, electrochromic devices, oxygen and humidity sensors because of its high optical absorption coefficient, non-toxic nature, abundant availability and low cost for production. Many groups have tried different ways to grow the cuprous oxide by, for instance, sputtering, CVD, PLD, MBE, and electro-deposition etc. Among them, the sputtering method is probably the most cost-effective and easy to operate. In this work, the cuprous oxide thin films were grown on R-Al2O3 and (110)-MgO substrates by DC reactive magnetron sputtering. Thin films grown at different temperatures under various oxygen partial pressures were studied by X-ray diffraction (XRD) to test their structural perfections. Samples with the Cu2O on Al2O3(1012) and MgO(110) were studied via measurement of cathodoluminescence(CL) spectroscopy, photoluminescence (PL) spectroscopy, transmission spectroscopy and magneto transport behaviors. The correlation of growth condition and physical properties are discussed.

R-Al2O3

MgO

sputter

cuprous oxide (Cu2O)

p-type semiconducting Cu2O thin films prepared by reactive magnetron sputtering and a study of its properties and application

Yang, Shun-jie

06 July 2005

Polycrystalline p-Cu2O were fabricated by reactive rf magnetron sputtering . we found that The electrical, optical, and crystallographical properties of films were strongly dependent on the deposition condition . Grant size increasing in the range from 10 to 45nm , A hole concentration increasing in the range from 1016 to 1017 cm-3 and a mobility increasing on the order of 10-1 cm2/V s were obtained in the cuprous oxide thin film prepared by controlling work pressure (Argon partial partial pressure ) . Fabricated thin-film heterojunction diodes consisting of a p-type cuprous oxide combined with and n-type Al-doped ZnO and ITO exhibited a rectifying current-voltage characteristic .

vacancy

cuprous oxide

p-n junction

Cu2O thin films for p-type metal oxide thin film transistors

Han, Sanggil

January 2018

The rapid progress of n-type metal oxide thin film transistors (TFTs) has motivated research on p-type metal oxide TFTs in order to realise metal oxide-based CMOS circuits which enable low power consumption large-area electronics. Cuprous oxide (Cu2O) has previously been proposed as a suitable active layer for p-type metal oxide TFTs. The two most significant challenges for achieving good quality Cu2O TFTs are to overcome the low field-effect mobility and an unacceptably high off-state current that are a feature of devices that have been reported to date. This dissertation focuses on improving the carrier mobility, and identifying the main origins of the low field-effect mobility and high off-state current in Cu2O TFTs. This work has three major findings. The first major outcome is a demonstration that vacuum annealing can be used to improve the carrier mobility in Cu2O without phase conversion, such as oxidation (CuO) or oxide reduction (Cu). In order to allow an in-depth discussion on the main origins of the very low carrier mobility in as-deposited films and the mobility enhancement by annealing, a quantitative analysis of the relative dominance of the main conduction mechanisms (i.e. trap-limited and grain-boundary-limited conduction) is performed. This shows that the low carrier mobility of as-deposited Cu2O is due to significant grain-boundary-limited conduction. In contrast, after annealing, grain-boundary-limited conduction becomes insignificant due to a considerable reduction in the energy barrier height at grain boundaries, and therefore trap-limited conduction dominates. A further mobility improvement by an increase in annealing temperature is explained by a reduction in the effect of trap-limited conduction resulting from a decrease in tail state density. The second major outcome of this work is the observation that grain orientation ([111] or [100] direction) of sputter-deposited Cu2O can be varied by control of the incident ion-to-Cu flux ratio. Using this technique, a systematic investigation on the effect of grain orientation on carrier mobility in Cu2O thin films is presented, which shows that the [100] Cu2O grain orientation is more favourable for realising a high carrier mobility. In the third and final outcome of this thesis, the temperature dependence of the drain current as a function of gate voltage along with the C-V characteristics reveals that minority carriers (electrons) cause the high off-state current in Cu2O TFTs. In addition, it is observed that an abrupt lowering of the activation energy and pinning of the Fermi energy occur in the off-state, which is attributed to subgap states at 0.38 eV below the conduction band minimum. These findings provide readers with the understanding of the main origins of the low carrier mobility and high off-state current in Cu2O TFTs, and the future research direction for resolving these problems.

Development and Mechanism of Action of Antimicrobial Coatings

Behzadinasab, Saeed

14 July 2023

Doctor of Philosophy / Antimicrobial coatings can inhibit the spread, via surfaces, of various diseases that infect humans. Antimicrobial coatings are useful because they can continue to kill pathogens (germs) for a long time after the surface is coated. This is a big improvement over use of common disinfectants that must be applied continuously. The main goal of this dissertation research is to develop various surface coatings that are antimicrobial and can provide a rapid killing of germs. We demonstrate 6 different antimicrobial coatings that rapidly inactivate a wide variety of pathogens, such as the most recent coronavirus, drug-resistant bacteria, or fungi. The antimicrobial coatings were composed of a variety of adhesives and active antimicrobial ingredients. Traditional adhesives and recently-invented adhesives were incorporated into the coatings, and active ingredients included copper, copper oxide, or zinc oxide. In short, our coatings provide a short killing period of a few minutes to one hour. Additionally, we investigated the mechanism of action of copper oxide surface coatings, and determined that the proximity of microbial cells to an antimicrobial surface is the key to inactivation or killing of the pathogen. Also, we measured the transfer of the most recent coronavirus from solid surfaces to skin under various conditions. We found that a substantial quantity of the virus is transferred to skin. More specifically, when the virus-infected droplet is still wet, a higher percentage is transferred from the solid to skin. In addition, we composed a review of the scientific literature on antimicrobial coatings with a focus on coatings and methods that inactivate the coronavirus.

antimicrobial

coatings

functional

surface

copper

cuprous oxide

Cu2O

antibacterial

mechanism

Aqueous Solution Synthesis of ZnO for Application in Optoelectronics

Joo, John Hwajong

23 September 2013

Recently, ZnO has garnered widespread attention in the semiconductor community for its large set of useful properties, which include a wide bandgap and its resulting optical transparency, a large exciton binding energy, a significant piezoelectric response, and good electrical conductivity. In many ways, it shares many properties with a widely used and technologically important semiconductor GaN, which is widely used for blue LEDs and lasers. However, ZnO cannot substitute for GaN in most optoelectronic applications, because it cannot be doped p-type. On the other hand, unlike many traditional, covalently bonded semiconductors like GaN, ZnO can be easily formed aqueous solutions at close to room temperature and pressure in the form of large crystals or a variety of nanostructures, making possible applications that are normally very difficult with traditional semiconductors. In this light, we aimed to take advantage of aqueous solution-based, ZnO growth techniques and incorporated ZnO structures novel optoelectronic and photonic structures. By controlling the morphology of ZnO, we studied the effects of nanowire-based \(ZnO/Cu_2O\) solar cells. Carrier collection was increased using a nanowire-based device architecture. The main result, however, was the time evolution of the performance of these devices due to the movement of ionized defects in the material. The effects of geometry on the ageing characteristics were studied, which showed that the carrier collection could be increased further with ageing in a nanowire \(Cu_2O\) solar cell. The aging behavior was substantially different between nanowire and planar solar cells, which implies that future design of nanostructured solar cells must long term aging effects. In addition to solar cells, we explored the possibilities of using aqueous solution growth of ZnO to fabricated whispering gallery mode optical cavities and waveguides for enhancing extraction from a single photon source. In both applications, we used templated growth of ZnO to fabricate geometrically (near) perfect rods and disks for these photonics applications. Finally, since epitaxy is important in the process of optimizing device performance and fabrication, we showed the ability to grow ZnO epitaxially on single crystalline plates of Au, expanding the options of epitaxial substrates to include a metal. / Engineering and Applied Sciences

Materials Science

Electrical engineering

cuprous oxide

epitaxial

oxide

solar cell

ZnO

Vliv prostředí na fotokatalytické vlastnosti oxidů mědi / Effect of environment on the photocatalytic properties of copper oxides

Šmatlo, Filip

January 2021

V této práci byl popsán princip fotokatalýzy. Práce se soustřeďuje na kovové oxidy, které mají široké využití ve fotokatalytických aplikacích. Bylo také popsáno různé použití fotokatalytických materiálů. Tato práce se zaměřuje zejména na využití fotokatalytických materiálů pro rozklad organických vodu znečisťujících látek. Popsaný fotokatalyzátor je oxid měďný, který má velmi dobré vlastnosti pro rozklad organických látek pomocí fotokatalýzy. Schopnost rozkladu organických látek oxidu měďného byla popsána na rozkladu organického barviva methylová oranž.

Light-activated gas sensing with copper oxide micro- and nanostructures

Yousef, Gabriel, Persson, Carl

January 2022

Metal oxide semiconductor (MOS) gas sensors have proven to be useful in many applications, ranging from detection of hazardous gases to monitoring of air quality. The demand for power efficient and high performance gas sensors has seen an increase in situations facing contemporary society. Currently it is common for sensors to employ an energy inefficient heater to provide for the optimal working temperature of the sensor. Light activation has been proposed as an alternative that could possibly improve modern gas sensors by decreasing energy utilization as well as increasing sensitivity and selectivity. The purpose of the following project is to explore the mechanisms and characteristics of light activated gas sensing using cuprous oxide (Cu2O), such that the findings may contribute to the development of power efficient gas sensors able to distinguish between gases at low concentrations. Several Cu2O-sensors with thicknesses of 300, 500 and 700 nm were examined, many of which also were doped with materials such as silver, graphene and titanium. Multiple types of measurements were performed where the sensors were exposed to nitrogen and carbon dioxide gas under illumination from one of three distinct light sources. The results show that conditions such as low light intensities, doping the sensors and air as the operating environment (compared to nitrogen gas) are beneficial for the carbon dioxide response under light activation. However, these findings are only indications and would need confirmation by additional measurements, both in terms of variation and repetition, under improved conditions.

Gas sensors

Gas sensing

Light-activation

Copper oxide

Cuprous Oxide

Nanomaterials

Physical Sciences

Fysik