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2. Consumer radar: Technology and limitations

Author

IEEE International Radar Conference (2013: Adelaide, S.A.), Evans, RJ, Farrell, PM, Felic, G, Duong, Hoa Thai, Le, Hoang Viet, Li, J, Li, M, Moran, W, Morelande, M, and Skafidas, E

Published
2013

5. Cortico-cognition coupling in treatment resistant schizophrenia

Author

Syeda, W.T. Wannan, C.M.J. Merritt, A.H. Raghava, J.M. Jayaram, M. Velakoulis, D. Kristensen, T.D. Soldatos, R.F. Tonissen, S. Thomas, N. Ambrosen, K.S. Sørensen, M.E. Fagerlund, B. Rostrup, E. Glenthøj, B.Y. Skafidas, E. Bousman, C.A. Johnston, L.A. Everall, I. Ebdrup, B.H. Pantelis, C. and Syeda, W.T. Wannan, C.M.J. Merritt, A.H. Raghava, J.M. Jayaram, M. Velakoulis, D. Kristensen, T.D. Soldatos, R.F. Tonissen, S. Thomas, N. Ambrosen, K.S. Sørensen, M.E. Fagerlund, B. Rostrup, E. Glenthøj, B.Y. Skafidas, E. Bousman, C.A. Johnston, L.A. Everall, I. Ebdrup, B.H. Pantelis, C.

Abstract

Background: Brain structural alterations and cognitive dysfunction are independent predictors for poor clinical outcome in schizophrenia, and the associations between these domains remains unclear. We employed a novel, multiblock partial least squares correlation (MB-PLS-C) technique and investigated multivariate cortico-cognitive patterns in patients with treatment-resistant schizophrenia (TRS) and matched healthy controls (HC). Method: Forty-one TRS patients (age 38.5 ± 9.1, 30 males (M)), and 45 HC (age 40.2 ± 10.6, 29 M) underwent 3T structural MRI. Volumes of 68 brain regions and seven variables from CANTAB covering memory and executive domains were included. Univariate group differences were assessed, followed by the MB-PLS-C analyses to identify group-specific multivariate patterns of cortico-cognitive coupling. Supplementary three-group analyses, which included 23 non-affected first-degree relatives (NAR), were also conducted. Results: Univariate tests demonstrated that TRS patients showed impairments in all seven cognitive tasks and volume reductions in 12 cortical regions following Bonferroni correction. The MB-PLS-C analyses revealed two significant latent variables (LVs) explaining > 90% of the sum-of-squares variance. LV1 explained 78.86% of the sum-of-squares variance, describing a shared, widespread structure-cognitive pattern relevant to both TRS patients and HCs. In contrast, LV2 (13.47% of sum-of-squares variance explained) appeared specific to TRS and comprised a differential cortico-cognitive pattern including frontal and temporal lobes as well as paired associates learning (PAL) and intra-extra dimensional set shifting (IED). Three-group analyses also identified two significant LVs, with NARs more closely resembling healthy controls than TRS patients. Conclusions: MB-PLS-C analyses identified multivariate brain structural-cognitive patterns in the latent space that may provide a TRS signature. © 2022 The Authors

Published
2022

6. Low‐Temperature Solution‐Processed Transparent QLED Using Inorganic Metal Oxide Carrier Transport Layers (Adv. Funct. Mater. 3/2022)

Author

Yu, Y, Liang, Y, Yong, J, Li, T, Hossain, MS, Liu, Y, Hu, Y, Ganesan, K, Skafidas, E, Yu, Y, Liang, Y, Yong, J, Li, T, Hossain, MS, Liu, Y, Hu, Y, Ganesan, K, and Skafidas, E

Abstract

In article number 2106387, Yang Yu, Efstratios Skafidas, and co-workers present transparent and fully solution processed inorganic quantum dots LED (QLED). To improve upon the structures hole injection efficiency, a low-temperature sol-gel derived copper doped NiO interlayer is introduced. The derived QLED analytical models and simulation results are in good concordance with experimental results, providing a new framework for the development of novel QLEDs.

Published
2022

7. Low-Temperature Solution-Processed Transparent QLED Using Inorganic Metal Oxide Carrier Transport Layers

Author

Yu, Y, Liang, Y, Yong, J, Li, T, Hossain, MS, Liu, Y, Hu, Y, Ganesan, K, Skafidas, E, Yu, Y, Liang, Y, Yong, J, Li, T, Hossain, MS, Liu, Y, Hu, Y, Ganesan, K, and Skafidas, E

Abstract

Quantum dot light‐emitting diodes (QLEDs) represent an exciting new technology that has many desirable attributes when compared to existing organic LEDs (OLEDs) including increased brightness, contrast, and response time. Solution‐based fabrication approaches have the advantage of being able to produce large‐area electronic systems at reduced costs and critical in applications such as large display fabrication and electronics on curved surfaces including low‐profile augmented reality glasses. In this paper, for the first time, a fully solution‐processed transparent inorganic QLED is described. Traditional QLED fabrication methodologies require the use of air‐sensitive materials that make fabrication of these devices challenging and expensive. Instead of using air‐sensitive organic materials, in the approach, nickel oxide (NiO) is used as the hole transport layer and is deposited using a sol‐gel method. Copper doping of the NiO to reduce the turn‐on voltage of the QLED device is investigated. Importantly, the post‐annealing temperature of the sol‐gel process is below 275 °C, which permits the fabrication of QLEDs on a wide range of substrates. The experimental results are concordant with the COMSOL simulation data and demonstrate the feasibility of fabricating fully transparent inorganic QLED devices using a solution‐based process.

Published
2022

8. Cortico-cognition coupling in treatment resistant schizophrenia

Author

Syeda, WT, Wannan, CMJ, Merritt, AH, Raghava, JM, Jayaram, M, Velakoulis, D, Kristensen, TD, Soldatos, RF, Tonissen, S, Thomas, N, Ambrosen, KS, Sorensen, ME, Fagerlund, B, Rostrup, E, Glenthoj, BY, Skafidas, E, Bousman, CA, Johnston, LA, Everall, I, Ebdrup, BH, Pantelis, C, Syeda, WT, Wannan, CMJ, Merritt, AH, Raghava, JM, Jayaram, M, Velakoulis, D, Kristensen, TD, Soldatos, RF, Tonissen, S, Thomas, N, Ambrosen, KS, Sorensen, ME, Fagerlund, B, Rostrup, E, Glenthoj, BY, Skafidas, E, Bousman, CA, Johnston, LA, Everall, I, Ebdrup, BH, and Pantelis, C

Abstract

BACKGROUND: Brain structural alterations and cognitive dysfunction are independent predictors for poor clinical outcome in schizophrenia, and the associations between these domains remains unclear. We employed a novel, multiblock partial least squares correlation (MB-PLS-C) technique and investigated multivariate cortico-cognitive patterns in patients with treatment-resistant schizophrenia (TRS) and matched healthy controls (HC). METHOD: Forty-one TRS patients (age 38.5 ± 9.1, 30 males (M)), and 45 HC (age 40.2 ± 10.6, 29 M) underwent 3T structural MRI. Volumes of 68 brain regions and seven variables from CANTAB covering memory and executive domains were included. Univariate group differences were assessed, followed by the MB-PLS-C analyses to identify group-specific multivariate patterns of cortico-cognitive coupling. Supplementary three-group analyses, which included 23 non-affected first-degree relatives (NAR), were also conducted. RESULTS: Univariate tests demonstrated that TRS patients showed impairments in all seven cognitive tasks and volume reductions in 12 cortical regions following Bonferroni correction. The MB-PLS-C analyses revealed two significant latent variables (LVs) explaining > 90% of the sum-of-squares variance. LV1 explained 78.86% of the sum-of-squares variance, describing a shared, widespread structure-cognitive pattern relevant to both TRS patients and HCs. In contrast, LV2 (13.47% of sum-of-squares variance explained) appeared specific to TRS and comprised a differential cortico-cognitive pattern including frontal and temporal lobes as well as paired associates learning (PAL) and intra-extra dimensional set shifting (IED). Three-group analyses also identified two significant LVs, with NARs more closely resembling healthy controls than TRS patients. CONCLUSIONS: MB-PLS-C analyses identified multivariate brain structural-cognitive patterns in the latent space that may provide a TRS signature.

Published
2022

14. Detection of voluntary dehydration in paediatric populations using non-invasive point-of-care saliva and urine testing

Author

Faidah, N, Soraya, G, Erlichster, M, Natzir, R, Chana, G, Skafidas, E, Hardjo, M, Ganda, IJ, Bahar, B, Faidah, N, Soraya, G, Erlichster, M, Natzir, R, Chana, G, Skafidas, E, Hardjo, M, Ganda, IJ, and Bahar, B

Abstract

AIM: Voluntary dehydration, or lack of fluid intake despite water availability, is common in otherwise healthy children, and can lead to adverse effects. Most dehydration biomarkers are impractical for routine assessment in paediatric populations. This study aimed to assess two non-invasive hydration assessment tools, urine specific gravity (USG ) and a novel point-of-care (POC) salivary osmolarity (SOSM) sensor, in healthy children. METHODS: Volunteers were tested by colorimetric USG and a handheld SOSM system. Observed values were compared against previous studies to determine hydration status, as was the concordance between parameters. RESULTS: At the common USG threshold of 1.020, 42.4% of the 139 healthy children were dehydrated. The same prevalence was found using the 70-mOSM cut-off value. Comparative analysis of SOSM at varying USG thresholds demonstrated significantly higher SOSM in dehydrated children with a USG ≥ 1.030 (P = 0.002). CONCLUSION: At the USG threshold of 1.020 and SOSM threshold of 70 mOSM, 42.4% of healthy children were found to be voluntarily dehydrated. Significantly higher SOSM was observed in dehydrated children (USG ≥ 1.030). As the first study on the utility of POC SOSM measurements for detecting dehydration, these results provide a foundation for future POC characterisation of SOSM in other populations and clinical contexts.

Published
2021

15. Heater Integrated Lab-on-a-Chip Device for Rapid HLA Alleles Amplification towards Prevention of Drug Hypersensitivity

Author

Uddin, SM, Sayad, A, Chan, J, Huynh, DH, Skafidas, E, Kwan, P, Uddin, SM, Sayad, A, Chan, J, Huynh, DH, Skafidas, E, and Kwan, P

Abstract

HLA-B*15:02 screening before administering carbamazepine is recommended to prevent life-threatening hypersensitivity. However, the unavailability of a point-of-care device impedes this screening process. Our research group previously developed a two-step HLA-B*15:02 detection technique utilizing loop-mediated isothermal amplification (LAMP) on the tube, which requires two-stage device development to translate into a portable platform. Here, we report a heater-integrated lab-on-a-chip device for the LAMP amplification, which can rapidly detect HLA-B alleles colorimetrically. A gold-patterned micro-sized heater was integrated into a 3D-printed chip, allowing microfluidic pumping, valving, and incubation. The performance of the chip was tested with color dye. Then LAMP assay was conducted with human genomic DNA samples of known HLA-B genotypes in the LAMP-chip parallel with the tube assay. The LAMP-on-chip results showed a complete match with the LAMP-on-tube assay, demonstrating the detection system's concurrence.

Published
2021

16. Pan-Family Assays for Rapid Viral Screening: Reducing Delays in Public Health Responses During Pandemics

Author

Erlichster, M, Chana, G, Zantomio, D, Goudey, B, Skafidas, E, Erlichster, M, Chana, G, Zantomio, D, Goudey, B, and Skafidas, E

Abstract

BACKGROUND: Coronavirus disease 2019 has highlighted deficiencies in the testing capacity of many developed countries during the early stages of pandemics. Here we describe a strategy using pan-family viral assays to improve early accessibility of large-scale nucleic acid testing. METHODS: Coronaviruses and severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) were used as a case study for assessing utility of pan-family viral assays during the early stages of a novel pandemic. Specificity of a pan-coronavirus (Pan-CoV) assay for a novel pathogen was assessed using the frequency of common human coronavirus (HCoV) species in key populations. A reported Pan-CoV assay was assessed to determine sensitivity to 60 reference coronaviruses, including SARS-CoV-2. The resilience of the primer target regions of this assay to mutation was assessed in 8893 high-quality SARS-CoV-2 genomes to predict ongoing utility during pandemic progression. RESULTS: Because of common HCoV species, a Pan-CoV assay would return false positives for as few as 1% of asymptomatic adults, but up to 30% of immunocompromised patients with respiratory disease. One-half of reported Pan-CoV assays identify SARS-CoV-2 and with small adjustments can accommodate diverse variation observed in animal coronaviruses. The target region of 1 well-established Pan-CoV assay is highly resistant to mutation compared to species-specific SARS-CoV-2 reverse transcriptase-polymerase chain reaction assays. CONCLUSIONS: Despite cross-reactivity with common pathogens, pan-family assays may greatly assist management of emerging pandemics through prioritization of high-resolution testing or isolation measures. Targeting highly conserved genomic regions make pan-family assays robust and resilient to mutation. A strategic stockpile of pan-family assays may improve containment of novel diseases before the availability of species-specific assays.

Published
2021

18. Meander Thin-Film Biosensor Fabrication to Investigate the Influence of Structural Parameters on the Magneto-Impedance Effect

Author

Sayad, A, Uddin, SM, Chan, J, Skafidas, E, Kwan, P, Sayad, A, Uddin, SM, Chan, J, Skafidas, E, and Kwan, P

Abstract

Thin-film magneto-impedance (MI) biosensors have attracted significant attention due to their high sensitivity and easy miniaturization. However, further improvement is required to detect weak biomagnetic signals. Here, we report a meander thin-film biosensor preparation to investigate the fabrication parameters influencing the MI effect. Specifically, we hypothesized that an optimal film thickness and sensing area size ratio could be achieved to obtain a maximum MI ratio. A meander multilayer MI biosensor based on a NiFe/Cu/NiFe thin-film was designed and fabricated into 3-, 6-, and 9-turn models with film thicknesses of 3 µm and 6 µm. The 9-turn biosensor resembled the largest sensing area, while the 3- and 6-turn biosensors were designed with identical sensing areas. The results indicated that the NiFe film thickness of 6 µm with a sensing area size of 14.4 mm2 resembling a 9-turn MI biosensor is the optimal ratio yielding the maximum MI ratio of 238%, which is 70% larger than the 3- and 6-turn structures. The 3- and 6-turn MI biosensors exhibited similar characteristics where the MI ratio peaked at a similar value. Our results suggest that the MI ratio can be increased by increasing the sensing area size and film thickness rather than the number of turns. We showed that an optimal film thickness to sensing area size ratio is required to obtain a high MI ratio. Our findings will be useful for designing highly sensitive MI biosensors capable of detecting low biomagnetic signals.

Published
2021

19. Characterization of the 60 GHz wireless desktop channel

Author

Liu, C., Skafidas, E., and Evans, R.J.

Subjects
Millimeter waves -- Analysis, Wireless communication systems -- Services, Wireless communication systems -- Analysis, Wireless voice/data service, Business, Computers, Electronics, Electronics and electrical industries
Abstract

We measure and characterize the 55-65 GHz wireless channel for a typical desktop environment. The Saleh-Valenzuela (S-V) model is used to describe the desktop environment. Key S-V model parameters such as cluster decay factor, ray decay factor, cluster arrival rate, and ray arrival rate are extracted from measured data. Index Terms--Millimeter wave propagation, multiple-path channel, radio propagation.

Published
2007

20. Minimum phase properties for input nonaffine nonlinear systems

Author

Nesic, D., Skafidas, E., Mareels, I.M.Y., and Evans, R.J.

Subjects
Control systems -- Analysis
Abstract

For input nonaffine nonlinear control systems, the minimum phase property of the system in general depends on the control law. Switching or discontinuous controllers may offer advantages in this context. In particular, there may not exist a continuous control law which would keep the output identically equal to zero and for which the zero output constrained dynamics are locally stable, whereas a discontinuous controller which achieves this exists. For single-input/single-output input nonaffine nonlinear systems we give sufficient conditions for existence and present a method for the design of discontinuous switching controllers which yield locally stable zero dynamics. Index Terms - Input nonaffine systems, minimum phase, nonlinear, switching control.

Published
1999

21. A single sensor based multispectral imaging camera using a narrow spectral band color mosaic integrated on the monochrome CMOS image sensor

Author

He, X, Liu, Y, Ganesan, K, Ahnood, A, Beckett, P, Eftekhari, F, Smith, D, Uddin, MH, Skafidas, E, Nirmalathas, A, Unnithan, RR, He, X, Liu, Y, Ganesan, K, Ahnood, A, Beckett, P, Eftekhari, F, Smith, D, Uddin, MH, Skafidas, E, Nirmalathas, A, and Unnithan, RR

Abstract

A multispectral image camera captures image data within specific wavelength ranges in narrow wavelength bands across the electromagnetic spectrum. Images from a multispectral camera can extract a additional information that the human eye or a normal camera fails to capture and thus may have important applications in precision agriculture, forestry, medicine, and object identification. Conventional multispectral cameras are made up of multiple image sensors each fitted with a narrow passband wavelength filter and optics, which makes them heavy, bulky, power hungry, and very expensive. The multiple optics also create an image co-registration problem. Here, we demonstrate a single sensor based three band multispectral camera using a narrow spectral band red–green–blue color mosaic in a Bayer pattern integrated on a monochrome CMOS sensor. The narrow band color mosaic is made of a hybrid combination of plasmonic color filters and a heterostructured dielectric multilayer. The demonstrated camera technology has reduced cost, weight, size, and power by almost n times (where n is the number of bands) compared to a conventional multispectral camera.

Published
2020

22. A meta-analysis of in vitro exposures to weak radiofrequency radiation exposure from mobile phones (1990–2015)

Author

Halgamuge, MN, Skafidas, E, Davis, D, Halgamuge, MN, Skafidas, E, and Davis, D

Abstract

To function, mobile phone systems require transmitters that emit and receive radiofrequency signals over an extended geographical area exposing humans in all stages of development ranging from in-utero, early childhood, adolescents and adults. This study evaluates the question of the impact of radiofrequency radiation on living organisms in vitro studies. In this study, we abstract data from 300 peer-reviewed scientific publications (1990–2015) describing 1127 experimental observations in cell-based in vitro models. Our first analysis of these data found that out of 746 human cell experiments, 45.3% indicated cell changes, whereas 54.7% indicated no changes (p = 0.001). Realizing that there are profound distinctions between cell types in terms of age, rate of proliferation and apoptosis, and other characteristics and that RF signals can be characterized in terms of polarity, information content, frequency, Specific Absorption Rate (SAR) and power, we further refined our analysis to determine if there were so e distinct properties of negative and positive findings associated with these specific characteristics. We further analyzed the data taking into account the cumulative effect (SAR × exposure time) to acquire the cumulative energy absorption of experiments due to radiofrequency exposure, which we believe, has not been fully considered previously. When the frequency of signals, length and type of exposure, and maturity, rate of growth (doubling time), apoptosis and other properties of individual cell types are considered, our results identify a number of potential non-thermal effects of radiofrequency fields that are restricted to a subset of specific faster-growing less differentiated cell types such as human spermatozoa (based on 19 reported experiments, p-value = 0.002) and human epithelial cells (based on 89 reported experiments, p-value < 0.0001). In contrast, for mature, differentiated adult cells of Glia (p = 0.001) and Glioblastoma (p < 0.0001) and adult h

Published
2020

23. Utility of Pan-Family Assays for Rapid Viral Screening: Reducing Delays in Public Health Responses During Pandemics

Author

Erlichster, M, Chana, G, Zantomio, D, Goudey, B, Skafidas, E, Erlichster, M, Chana, G, Zantomio, D, Goudey, B, and Skafidas, E

Abstract

Summary

Background

The SARS-CoV-2 pandemic has highlighted deficiencies in the testing capacity of many developed countries during the early stages of emerging pandemics. Here we describe the potential for pan-family viral assays to improve early accessibility of large-scale nucleic acid testing.

Methods

Coronaviruses and SARS-CoV-2 were used as a case-study for investigating the utility of pan-family viral assays during the early stages of a novel pandemic. Specificity of a pan-coronavirus (Pan-CoV) assay for viral detection was assessed using the frequency of common human coronavirus (HCoV) species in key populations. A reported Pan-CoV assay was assessed to determine sensitivity to SARS-CoV-2 and 59 other coronavirus species. The resilience of the primer target regions of this assay to mutation was assessed in 8893 high quality SARS-CoV-2 genomes to predict ongoing utility during pandemic progression.

Findings

Due to infection with common HCoV species, a Pan-CoV assay would return a false positive for as few as 1% of asymptomatic adults, but up to 30% of immunocompromised patients displaying symptoms of respiratory disease. Two of the four reported pan-coronavirus assays would have identified SARS-CoV-2 and we demonstrate that with small adjustments to the primers, these assays can accommodate novel variation observed in animal coronaviruses. The assay target region of one well established Pan-CoV assay is highly resistant to mutation compared to regions targeted by other widely applied SARS-CoV-2 RT-PCR assays.

Interpretation

Pan-family assays have the potential to greatly assist management of emerging public health emergencies through prioritization of high-resolution testing or isolation measures, despite limitations in test specificity due to cross-reactivity with common pathogens. Targeting highly conserved genomic regions make pan-family assays robust and resilient to mutation of a given virus. This approach may

Published
2020

24. Magneto-Impedance Biosensor Sensitivity: Effect and Enhancement

Author

Sayad, A, Skafidas, E, Kwan, P, Sayad, A, Skafidas, E, and Kwan, P

Abstract

Biosensors based on magneto-impedance (MI) effect are powerful tools for biomedical applications as they are highly sensitive, stable, exhibit fast response, small in size, and have low hysteresis and power consumption. However, the performance of these biosensors is influenced by a variety of factors, including the design, geometry, materials and fabrication procedures. Other less appreciated factors influencing the MI effect include measuring circuit implementation, the material used for construction, geometry of the thin film sensing element, and patterning shapes compatible with the interface microelectronic circuitry. The type magnetic (ferrofluid, Dynabeads, and nanoparticles) and size of the particles, the magnetic particle concentration, magnetic field strength and stray magnetic fields can also affect the sensor sensitivity. Based on these considerations it is proposed that ideal MI biosensor sensitivity could be achieved when the sensor is constructed in sandwich thick magnetic layers with large sensing area in a meander shape, measured with circuitry that provides the lowest possible external inductance at high frequencies, enclosed by a protective layer between magnetic particles and sensing element, and perpendicularly magnetized when detecting high-concentration of magnetic particles.

Published
2020

25. Structural and functional brain abnormalities in children with schizotypal disorder: a pilot study

Author

Wang, Y, Harding, IH, Testa, R, Tonge, B, Jones, H, Seal, M, Ross, N, Chan, RCK, van Beurden, F, Abu-Akel, A, Skafidas, E, Pantelis, C, Wang, Y, Harding, IH, Testa, R, Tonge, B, Jones, H, Seal, M, Ross, N, Chan, RCK, van Beurden, F, Abu-Akel, A, Skafidas, E, and Pantelis, C

Abstract

Schizotypal disorder lies in the schizophrenia spectrum and is widely studied in adult populations. Schizotypal disorder in children (SDc) is less well described. This study examined brain morphological and functional connectivity abnormalities in SDc (12 SDc and 9 typically developing children), focusing on the default mode and executive control brain networks. Results indicated that SDc is associated with reduced grey matter volume (GMV) in superior and medial frontal gyri, and increased resting-state functional connectivity between the superior frontal gyrus and inferior parietal lobule, compared to typically developing children (cluster-level FWE-corrected p < 0.05). The brain structure abnormality (GMV in left superior frontal gyrus) was correlated with clinical symptoms in SDc (r = −0.66, p = 0.026) and functional connectivity abnormality was correlated with extra-dimensional shifting impairments in all participants (r = 0.62, p = 0.011), suggesting their contribution to the underlying mechanisms of clinical presentation. These preliminary results motivate further work to characterize the neural basis of SDc and its significance as a risk factor for later psychosis.

Published
2020

28. Development of an Ultrasensitive Impedimetric Immunosensor Platform for Detection of Plasmodium Lactate Dehydrogenase

Author

Low, YK, Chan, J, Soraya, GV, Buffet, C, Abeyrathne, CD, Huynh, DH, Skafidas, E, Kwan, P, Rogerson, SJ, Low, YK, Chan, J, Soraya, GV, Buffet, C, Abeyrathne, CD, Huynh, DH, Skafidas, E, Kwan, P, and Rogerson, SJ

Abstract

Elimination of malaria is a global health priority. Detecting an asymptomatic carrier of Plasmodium parasites to receive treatment is an important step in achieving this goal. Current available tools for detection of malaria parasites are either expensive, lacking in sensitivity for asymptomatic carriers, or low in throughput. We investigated the sensitivity of an impedimetric biosensor targeting the malaria biomarker Plasmodium lactate dehydrogenase (pLDH). Following optimization of the detection protocol, sensor performance was tested using phosphate-buffered saline (PBS), and then saliva samples spiked with pLDH at various concentrations. The presence of pLDH was determined by analyzing the sensor electrical properties before and after sample application. Through comparing percentage changes in impedance magnitude, the sensors distinguished pLDH-spiked PBS from non-spiked PBS at concentrations as low as 250 pg/mL (p = 0.0008). Percentage changes in impedance magnitude from saliva spiked with 2.5 ng/mL pLDH trended higher than those from non-spiked saliva. These results suggest that these biosensors have the potential to detect concentrations of pLDH up to two logs lower than currently available best-practice diagnostic tools. Successful optimization of this sensor platform would enable more efficient diagnosis of asymptomatic carriers, who can be targeted for treatment, contributing to the elimination of malaria.

Published
2019

29. Ultrasensitive and label-free biosensor for the detection of Plasmodium falciparum histidine-rich protein II in saliva.

Author

Soraya, GV, Abeyrathne, CD, Buffet, C, Huynh, DH, Uddin, SM, Chan, J, Skafidas, E, Kwan, P, Rogerson, SJ, Soraya, GV, Abeyrathne, CD, Buffet, C, Huynh, DH, Uddin, SM, Chan, J, Skafidas, E, Kwan, P, and Rogerson, SJ

Abstract

Malaria elimination is a global public health priority. To fulfil the demands of elimination diagnostics, we have developed an interdigitated electrode sensor platform targeting the Plasmodium falciparum Histidine Rich Protein 2 (PfHRP2) protein in saliva samples. A protocol for frequency-specific PfHRP2 detection in phosphate buffered saline was developed, yielding a sensitivity of 2.5 pg/mL based on change in impedance magnitude of the sensor. This protocol was adapted and optimized for use in saliva with a sensitivity of 25 pg/mL based on change in resistance. Further validation demonstrated detection in saliva spiked with PfHRP2 from clinical isolates in 8 of 11 samples. With a turnaround time of ~2 hours, the label-free platform based on impedance sensors has the potential for miniaturization into a point-of-care diagnostic device for malaria elimination.

Published
2019

30. Rapid Detection of HLA-B*57:01-Expressing Cells Using a Label-Free Interdigitated Electrode Biosensor Platform for Prevention of Abacavir Hypersensitivity in HIV Treatment

Author

Chan, J, Soraya, GV, Craig, L, Uddin, SM, Todaro, M, Huynh, DH, Abeyrathne, CD, Kostenko, L, McCluskey, J, Skafidas, E, Kwan, P, Chan, J, Soraya, GV, Craig, L, Uddin, SM, Todaro, M, Huynh, DH, Abeyrathne, CD, Kostenko, L, McCluskey, J, Skafidas, E, and Kwan, P

Abstract

Pre-treatment screening of individuals for human leukocyte antigens (HLA) HLA-B*57:01 is recommended for the prevention of life-threatening hypersensitivity reactions to abacavir, a drug widely prescribed for HIV treatment. However, the implementation of screening in clinical practice is hindered by the slow turnaround time and high cost of conventional HLA genotyping methods. We have developed a biosensor platform using interdigitated electrode (IDE) functionalized with a monoclonal antibody to detect cells expressing HLA-B*57:01. This platform was evaluated using cell lines and peripheral blood mononuclear cells expressing different HLA-B alleles. The functionalized IDE sensor was able to specifically capture HLA-B*57:01 cells, resulting in a significant change in the impedance magnitude in 20 min. This IDE platform has the potential to be further developed to enable point-of-care HLA-B*57:01 screening

Published
2019

31. Self-Organized Nanostructure Modified Microelectrode for Sensitive Electrochemical Glutamate Detection in Stem Cells-Derived Brain Organoids

Author

Nasr, B, Chatterton, R, Yong, JHM, Jamshidi, P, D'Abaco, GM, Bjorksten, AR, Kavehei, O, Chana, G, Dottori, M, Skafidas, E, Nasr, B, Chatterton, R, Yong, JHM, Jamshidi, P, D'Abaco, GM, Bjorksten, AR, Kavehei, O, Chana, G, Dottori, M, and Skafidas, E

Abstract

Neurons release neurotransmitters such as glutamate to communicate with each other and to coordinate brain functioning. As increased glutamate release is indicative of neuronal maturation and activity, a system that can measure glutamate levels over time within the same tissue and/or culture system is highly advantageous for neurodevelopmental investigation. To address such challenges, we develop for the first time a convenient method to realize functionalized borosilicate glass capillaries with nanostructured texture as an electrochemical biosensor to detect glutamate release from cerebral organoids generated from human embryonic stem cells (hESC) that mimic various brain regions. The biosensor shows a clear catalytic activity toward the oxidation of glutamate with a sensitivity of 93 ± 9.5 nA·µM-1·cm-2. It was found that the enzyme-modified microelectrodes can detect glutamate in a wide linear range from 5 µM to 0.5 mM with a limit of detection (LOD) down to 5.6 ± 0.2 µM. Measurements were performed within the organoids at different time points and consistent results were obtained. This data demonstrates the reliability of the biosensor as well as its usefulness in measuring glutamate levels across time within the same culture system.

Published
2018

32. A compact silicon grating coupler based on hollow tapered spot-size converter

Author

Asaduzzaman, M, Bakaul, M, Skafidas, E, Khandokar, MRH, Asaduzzaman, M, Bakaul, M, Skafidas, E, and Khandokar, MRH

Abstract

A new compact silicon grating coupler enabling fibre-to-chip light coupling at a minimized taper length is proposed. The proposed coupler, which incorporates a hollow tapered waveguide, converts the spot-size of optical modes from micro- to nano-scales by reducing the lateral dimension from 15 µm to 300 nm at a length equals to 60 µm. The incorporation of such a coupler in photonic integrated circuit causes a physical footprint as small as 81 µm × 15 µm with coupling efficiency and 3-dB coupling bandwidth as high as 72% and 69 nm respectively.

Published
2018

33. Phenotypic and Functional Characterization of Peripheral Sensory Neurons derived from Human Embryonic Stem Cells

Author

Alshawaf, AJ, Viventi, S, Qiu, W, D'Abaco, G, Nayagam, B, Erlichster, M, Chana, G, Everall, I, Ivanusic, J, Skafidas, E, Dottori, M, Alshawaf, AJ, Viventi, S, Qiu, W, D'Abaco, G, Nayagam, B, Erlichster, M, Chana, G, Everall, I, Ivanusic, J, Skafidas, E, and Dottori, M

Abstract

The dorsal root ganglia (DRG) consist of a multitude of sensory neuronal subtypes that function to relay sensory stimuli, including temperature, pressure, pain and position to the central nervous system. Our knowledge of DRG sensory neurons have been predominantly driven by animal studies and considerably less is known about the human DRG. Human embryonic stem cells (hESC) are valuable resource to help close this gap. Our previous studies reported an efficient system for deriving neural crest and DRG sensory neurons from hESC. Here we show that this differentiation system gives rise to heterogeneous populations of sensory neuronal subtypes as demonstrated by phenotypic and functional analyses. Furthermore, using microelectrode arrays the maturation rate of the hESC-derived sensory neuronal cultures was monitored over 8 weeks in culture, showing their spontaneous firing activities starting at about 12 days post-differentiation and reaching maximum firing at about 6 weeks. These studies are highly valuable for developing an in vitro platform to study the diversity of sensory neuronal subtypes found within the human DRG.

Published
2018

34. Graphene foam as a biocompatible scaffold for culturing human neurons

Author

D'Abaco, GM, Mattei, C, Nasr, BK, Hudson, EJ, Alshawaf, AJ, Chana, G, Everall, IP, Nayagam, B, Dottori, M, Skafidas, E, D'Abaco, GM, Mattei, C, Nasr, BK, Hudson, EJ, Alshawaf, AJ, Chana, G, Everall, IP, Nayagam, B, Dottori, M, and Skafidas, E

Abstract

In this study, we explore the use of electrically active graphene foam as a scaffold for the culture of human-derived neurons. Human embryonic stem cell (hESC)-derived cortical neurons fated as either glutamatergic or GABAergic neuronal phenotypes were cultured on graphene foam. We show that graphene foam is biocompatible for the culture of human neurons, capable of supporting cell viability and differentiation of hESC-derived cortical neurons. Based on the findings, we propose that graphene foam represents a suitable scaffold for engineering neuronal tissue and warrants further investigation as a model for understanding neuronal maturation, function and circuit formation.

Published
2018

35. A Silk Fibroin Bio-Transient Solution Processable Memristor

Author

Yong, J, Hassan, B, Liang, Y, Ganesan, K, Rajasekharan, R, Evans, R, Egan, G, Kavehei, O, Li, J, Chana, G, Nasr, B, Skafidas, E, Yong, J, Hassan, B, Liang, Y, Ganesan, K, Rajasekharan, R, Evans, R, Egan, G, Kavehei, O, Li, J, Chana, G, Nasr, B, and Skafidas, E

Abstract

Today's electronic devices are fabricated using highly toxic materials and processes which limits their applications in environmental sensing applications and mandates complex encapsulation methods in biological and medical applications. This paper proposes a fully resorbable high density bio-compatible and environmentally friendly solution processable memristive crossbar arrays using silk fibroin protein which demonstrated bipolar resistive switching ratio of 104 and possesses programmable device lifetime characteristics before the device gracefully bio-degrades, minimizing impact to environment or to the implanted host. Lactate dehydrogenase assays revealed no cytotoxicity on direct exposure to the fabricated device and support their environmentally friendly and biocompatible claims. Moreover, the correlation between the oxidation state of the cations and their tendency in forming conductive filaments with respect to different active electrode materials has been investigated. The experimental results and the numerical model based on electro-thermal effect shows a tight correspondence in predicting the memristive switching process with various combinations of electrodes which provides insight into the morphological changes of conductive filaments in the silk fibroin films.

Published
2017

36. No preliminary evidence of differences in astrocyte density within the white matter of the dorsolateral prefrontal cortex in autism

Author

Lee, TT, Skafidas, E, Dottori, M, Zantomio, D, Pantelis, C, Everall, I, Chana, G, Lee, TT, Skafidas, E, Dottori, M, Zantomio, D, Pantelis, C, Everall, I, and Chana, G

Abstract

BACKGROUND: While evidence for white matter and astrocytic abnormalities exist in autism, a detailed investigation of astrocytes has not been conducted. Such an investigation is further warranted by an increasing role for neuroinflammation in autism pathogenesis, with astrocytes being key players in this process. We present the first study of astrocyte density and morphology within the white matter of the dorsolateral prefrontal cortex (DLPFC) in individuals with autism. METHODS: DLPFC formalin-fixed sections containing white matter from individuals with autism (n = 8, age = 4-51 years) and age-matched controls (n = 7, age = 4-46 years) were immunostained for glial fibrillary acidic protein (GFAP). Density of astrocytes and other glia were estimated via the optical fractionator, astrocyte somal size estimated via the nucleator, and astrocyte process length via the spaceballs probe. RESULTS: We found no evidence for alteration in astrocyte density within DLPFC white matter of individuals with autism versus controls, together with no differences in astrocyte somal size and process length. CONCLUSION: Our results suggest that astrocyte abnormalities within the white matter in the DLPFC in autism may be less pronounced than previously thought. However, astrocytic dysregulation may still exist in autism, even in the absence of gross morphological changes. Our lack of evidence for astrocyte abnormalities could have been confounded to an extent by having a small sample size and wide age range, with pathological features potentially restricted to early stages of autism. Nonetheless, future investigations would benefit from assessing functional markers of astrocytes in light of the underlying pathophysiology of autism.

Published
2017

37. Indoor infrared optical wireless localization system with background light power estimation capability

Author

Wang, K, Nirmalathas, A, Lim, C, Alameh, K, Li, H, Skafidas, E, Wang, K, Nirmalathas, A, Lim, C, Alameh, K, Li, H, and Skafidas, E

Abstract

The indoor user localization function is in high demand for high-speed wireless communications, navigations and smart-home applications. The optical wireless technology has been used to localize end users in indoor environments. However, its accuracy is typically very limited, due to the ambient light, which is relatively strong. In this paper, a novel high-localization-accuracy optical wireless based indoor localization system, based on the use of the mechanism that estimates background light intensity, is proposed. Both theoretical studies and demonstration experiments are carried out. Experimental results show that the accuracy of the proposed optical wireless indoor localization system is independent on the localization light strength, and that an average localization error as small as 2.5 cm is attained, which is 80% better than the accuracy of previously reported optical wireless indoor localization systems.

Published
2017

38. Plasmonic Colour Filters Based on Coaxial Holes in Aluminium

Author

Unnithan, RR, Sun, M, He, X, Balaur, E, Minovich, A, Neshev, DN, Skafidas, E, Roberts, A, Unnithan, RR, Sun, M, He, X, Balaur, E, Minovich, A, Neshev, DN, Skafidas, E, and Roberts, A

Abstract

Aluminum is an alternative plasmonic material in the visible regions of the spectrum due to its attractive properties such as low cost, high natural abundance, ease of processing, and complementary metal-oxide-semiconductor (CMOS) and liquid crystal display (LCD) compatibility. Here, we present plasmonic colour filters based on coaxial holes in aluminium that operate in the visible range. Using both computational and experimental methods, fine-tuning of resonance peaks through precise geometric control of the coaxial holes is demonstrated. These results will lay the basis for the development of filters in high-resolution liquid crystal displays, RGB-spatial light modulators, liquid crystal over silicon devices and novel displays.

Published
2017

39. A tight binding and (k)over-right-arrow . (p)over-right-arrow study of monolayer stanene

Author

Jiang, L, Marconcini, P, Hossian, MS, Qiu, W, Evans, R, Macucci, M, Skafidas, E, Jiang, L, Marconcini, P, Hossian, MS, Qiu, W, Evans, R, Macucci, M, and Skafidas, E

Abstract

Stanene is a single layer of tin atoms which has been discovered as an emerging material for quantum spin Hall related applications. In this paper, we present an accurate tight-binding model for single layer stanene near the Fermi level. We parameterized the onsite and hopping energies for the nearest, second nearest, and third nearest neighbor tight-binding method, both without and with spin orbital coupling. We derived the analytical solution for the [Formula: see text]and [Formula: see text] points and numerically investigated the buckling effect on the material electronic properties. In these points of the reciprocal space, we also discuss a corresponding [Formula: see text] description, obtaining the value of the [Formula: see text] parameters both analytically from the tight-binding ones, and numerically, fitting the ab-initio dispersion relations. Our models provide a foundation for large scale atomistic device transport calculations.

Published
2017

40. Pathway-wide association study identifies five shared pathways associated with schizophrenia in three ancestral distinct populations

Author

Liu, C, Bousman, CA, Pantelis, C, Skafidas, E, Zhang, D, Yue, W, Everall, IP, Liu, C, Bousman, CA, Pantelis, C, Skafidas, E, Zhang, D, Yue, W, and Everall, IP

Abstract

Genome-wide association studies have confirmed the polygenic nature of schizophrenia and suggest that there are hundreds or thousands of alleles associated with increased liability for the disorder. However, the generalizability of any one allelic marker of liability is remarkably low and has bred the notion that schizophrenia may be better conceptualized as a pathway(s) disorder. Here, we empirically tested this notion by conducting a pathway-wide association study (PWAS) encompassing 255 experimentally validated Kyoto Encyclopedia of Genes and Genomes (KEGG) pathways among 5033 individuals diagnosed with schizophrenia and 5332 unrelated healthy controls across three distinct ethnic populations; European-American (EA), African-American (AA) and Han Chinese (CH). We identified 103, 74 and 87 pathways associated with schizophrenia liability in the EA, CH and AA populations, respectively. About half of these pathways were uniquely associated with schizophrenia liability in each of the three populations. Five pathways (serotonergic synapse, ubiquitin mediated proteolysis, hedgehog signaling, adipocytokine signaling and renin secretion) were shared across all three populations and the single-nucleotide polymorphism sets representing these five pathways were enriched for single-nucleotide polymorphisms with regulatory function. Our findings provide empirical support for schizophrenia as a pathway disorder and suggest schizophrenia is not only a polygenic but likely also a poly-pathway disorder characterized by both genetic and pathway heterogeneity.

Published
2017

41. A Label-Free, Quantitative Fecal Hemoglobin Detection Platform for Colorectal Cancer Screening

Author

Soraya, GV, Nguyen, TC, Abeyrathne, CD, Huynh, DH, Chan, J, Nguyen, PD, Nasr, B, Chana, G, Kwan, P, Skafidas, E, Soraya, GV, Nguyen, TC, Abeyrathne, CD, Huynh, DH, Chan, J, Nguyen, PD, Nasr, B, Chana, G, Kwan, P, and Skafidas, E

Abstract

The early detection of colorectal cancer is vital for disease management and patient survival. Fecal hemoglobin detection is a widely-adopted method for screening and early diagnosis. Fecal Immunochemical Test (FIT) is favored over the older generation chemical based Fecal Occult Blood Test (FOBT) as it does not require dietary or drug restrictions, and is specific to human blood from the lower digestive tract. To date, no quantitative FIT platforms are available for use in the point-of-care setting. Here, we report proof of principle data of a novel low cost quantitative fecal immunochemical-based biosensor platform that may be further developed into a point-of-care test in low-resource settings. The label-free prototype has a lower limit of detection (LOD) of 10 µg hemoglobin per gram (Hb/g) of feces, comparable to that of conventional laboratory based quantitative FIT diagnostic systems.

Published
2017

43. Energy-filtered Electron Transport Structures for Low-power Low-noise 2-D Electronics

Author

Pan, X, Qiu, W, Skafidas, E, Pan, X, Qiu, W, and Skafidas, E

Abstract

In addition to cryogenic techniques, energy filtering has the potential to achieve high-performance low-noise 2-D electronic systems. Assemblies based on graphene quantum dots (GQDs) have been demonstrated to exhibit interesting transport properties, including resonant tunnelling. In this paper, we investigate GQDs based structures with the goal of producing energy filters for next generation lower-power lower-noise 2-D electronic systems. We evaluate the electron transport properties of the proposed GQD device structures to demonstrate electron energy filtering and the ability to control the position and magnitude of the energy passband by appropriate device dimensioning. We also show that the signal-to-thermal noise ratio performance of the proposed nanoscale device can be modified according to device geometry. The tunability of two-dimensional GQD structures indicates a promising route for the design of electron energy filters to produce low-power and low-noise electronics.

Published
2016

44. Microglial activation and progressive brain changes in schizophrenia

Author

Laskaris, LE, Di Biase, MA, Everall, I, Chana, G, Christopoulos, A, Skafidas, E, Cropley, VL, Pantelis, C, Laskaris, LE, Di Biase, MA, Everall, I, Chana, G, Christopoulos, A, Skafidas, E, Cropley, VL, and Pantelis, C

Abstract

Schizophrenia is a debilitating disorder that typically begins in adolescence and is characterized by perceptual abnormalities, delusions, cognitive and behavioural disturbances and functional impairments. While current treatments can be effective, they are often insufficient to alleviate the full range of symptoms. Schizophrenia is associated with structural brain abnormalities including grey and white matter volume loss and impaired connectivity. Recent findings suggest these abnormalities follow a neuroprogressive course in the earliest stages of the illness, which may be associated with episodes of acute relapse. Neuroinflammation has been proposed as a potential mechanism underlying these brain changes, with evidence of increased density and activation of microglia, immune cells resident in the brain, at various stages of the illness. We review evidence for microglial dysfunction in schizophrenia from both neuroimaging and neuropathological data, with a specific focus on studies examining microglial activation in relation to the pathology of grey and white matter. The studies available indicate that the link between microglial dysfunction and brain change in schizophrenia remains an intriguing hypothesis worthy of further examination. Future studies in schizophrenia should: (i) use multimodal imaging to clarify this association by mapping brain changes longitudinally across illness stages in relation to microglial activation; (ii) clarify the nature of microglial dysfunction with markers specific to activation states and phenotypes; (iii) examine the role of microglia and neurons with reference to their overlapping roles in neuroinflammatory pathways; and (iv) examine the impact of novel immunomodulatory treatments on brain structure in schizophrenia.

Published
2016

47. Decreased expression of mGluR5 within the dorsolateral prefrontal cortex in autism and increased microglial number in mGluR5 knockout mice: Pathophysiological and neurobehavioral implications

Author

Chana, G, Laskaris, L, Pantelis, C, Gillett, P, Testa, R, Zantomio, D, Burrows, EL, Hannan, AJ, Everall, IP, Skafidas, E, Chana, G, Laskaris, L, Pantelis, C, Gillett, P, Testa, R, Zantomio, D, Burrows, EL, Hannan, AJ, Everall, IP, and Skafidas, E

Abstract

Metabotropic glutamate receptor 5 (mGluR5) and microglial abnormalities have been implicated in autism spectrum disorder (ASD). However, controversy exists as to whether the receptor is down or upregulated in functioning in ASD. In addition, whilst activation of mGluR5 has been shown to attenuate microglial activation, its role in maintaining microglial homeostasis during development has not been investigated. We utilised published microarray data from the dorsolateral prefrontal cortex (DLPFC) of control (n=30) and ASD (n=27) individuals to carry out regression analysis to assess gene expression of mGluR5 downstream signalling elements. We then conducted a post-mortem brain stereological investigation of the DLPFC, to estimate the proportion of mGluR5-positive neurons and glia. Finally, we carried out stereological investigation into numbers of microglia in mGluR5 knockout mice, relative to wildtype littermates, together with assessment of changes in microglial somal size, as an indicator of activation status. We found that gene expression of mGluR5 was significantly decreased in ASD versus controls (p=0.018) as well as downstream elements SHANK3 (p=0.005) and PLCB1 (p=0.009) but that the pro-inflammatory marker NOS2 was increased (p=0.047). Intensity of staining of mGluR5-positive neurons was also significantly decreased in ASD versus controls (p=0.016). Microglial density was significantly increased in mGluR5 knockout animals versus wildtype controls (p=0.011). Our findings provide evidence for decreased expression of mGluR5 and its signalling components representing a key pathophysiological hallmark in ASD with implications for the regulation of microglial number and activation during development. This is important in the context of microglia being considered to play key roles in synaptic pruning during development, with preservation of appropriate connectivity relevant for normal brain functioning.

Published
2015

48. Highly Effective Conductance Modulation in Planar Silicene Field Effect Devices Due to Buckling

Author

Al-Dirini, F, Hossain, FM, Mohammed, MA, Nirmalathas, A, Skafidas, E, Al-Dirini, F, Hossain, FM, Mohammed, MA, Nirmalathas, A, and Skafidas, E

Abstract

Silicene is an exciting two-dimensional material that shares many of graphene's electronic properties, but differs in its structural buckling. This buckling allows opening a bandgap in silicene through the application of a perpendicular electric field. Here we show that this buckling also enables highly effective modulation of silicene's conductance by means of an in-plane electric field applied through silicene side gates, which can be realized concurrently within the same silicene monolayer. We illustrate this by using silicene to implement Self-Switching Diodes (SSDs), which are two-dimensional field effect nanorectifiers realized within a single silicene monolayer. Our quantum simulation results show that the atomically-thin silicene SSDs, with sub-10 nm dimensions, achieve a current rectification ratio that exceeds 200, without the need for doping, representing a 30 fold enhancement over graphene SSDs. We attribute this enhancement to a bandgap opening due to the in-plane electric field, as a consequence of silicene's buckling. Our results suggest that silicene is a promising material for the realization of planar field effect devices.

Published
2015

49. High Performance Graphene Nano-ribbon Thermoelectric Devices by Incorporation and Dimensional Tuning of Nanopores

Author

Hossain, MS, Al-Dirini, F, Hossain, FM, Skafidas, E, Hossain, MS, Al-Dirini, F, Hossain, FM, and Skafidas, E

Abstract

Thermoelectric properties of Graphene nano-ribbons (GNRs) with nanopores (NPs) are explored for a range of pore dimensions in order to achieve a high performance two-dimensional nano-scale thermoelectric device. We reduce thermal conductivity of GNRs by introducing pores in them in order to enhance their thermoelectric performance. The electrical properties (Seebeck coefficient and conductivity) of the device usually degrade with pore inclusion; however, we tune the pore to its optimal dimension in order to minimize this degradation, enhancing the overall thermoelectric performance (high ZT value) of our device. We observe that the side channel width plays an important role to achieve optimal performance while the effect of pore length is less pronounced. This result is consistent with the fact that electronic conduction in GNRs is dominated along its edges. Ballistic transport regime is assumed and a semi-empirical method using Huckel basis set is used to obtain the electrical properties, while the phononic system is characterized by Tersoff empirical potential model. The proposed device structure has potential applications as a nanoscale local cooler and as a thermoelectric power generator.

Published
2015

50. All-Graphene Planar Self-Switching MISFEDs, Metal-Insulator-Semiconductor Field-Effect Diodes

Author

Al-Dirini, F, Hossain, FM, Nirmalathas, A, Skafidas, E, Al-Dirini, F, Hossain, FM, Nirmalathas, A, and Skafidas, E

Abstract

Graphene normally behaves as a semimetal because it lacks a bandgap, but when it is patterned into nanoribbons a bandgap can be introduced. By varying the width of these nanoribbons this band gap can be tuned from semiconducting to metallic. This property allows metallic and semiconducting regions within a single Graphene monolayer, which can be used in realising two-dimensional (2D) planar Metal-Insulator-Semiconductor field effect devices. Based on this concept, we present a new class of nano-scale planar devices named Graphene Self-Switching MISFEDs (Metal-Insulator-Semiconductor Field-Effect Diodes), in which Graphene is used as the metal and the semiconductor concurrently. The presented devices exhibit excellent current-voltage characteristics while occupying an ultra-small area with sub-10 nm dimensions and an ultimate thinness of a single atom. Quantum mechanical simulation results, based on the Extended Huckel method and Nonequilibrium Green's Function Formalism, show that a Graphene Self-Switching MISFED with a channel as short as 5 nm can achieve forward-to-reverse current rectification ratios exceeding 5000.

Published
2014

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