ensure early detection, is the key to the survival of cancer patients. [1][2][3][4][5][6] Cancer biomarkers (encompassing metabolites, peptides/proteins, and nucleic acids-based markers) play a vital role in detecting cancers and monitoring their progression as well as in evaluating treatment effectiveness. Even minor changes in the levels of cancer biomarkers are very relevant for diagnostics. These minor changes need to be detected in complex biological samples, such as blood, saliva, urine, and/or other body fluids. [7][8][9][10][11][12] Hence, ultrasensitive and very specific diagnostic tools are required for the detection and quantification of such biomarkers. Conventional cancer detection methods such as computed tomography, cytological detection, magnetic resonance imaging, fluorescence imaging, immunohistochemistry, thermography, X-ray technique, radioimmunoassay, enzyme-linked immunosorbent assay (ELISA), and ultrasound method, typically encompass several stages, e.g., complex pretreatment processes, timeconsuming nucleic acid amplification or mass spectrometry analysis of protein biomarkers. In addition to being time-consuming, existing diagnostic tools are also typically expensive, and in some cases lack the required sensitivity and specificity, which limits their utility in clinical diagnostics. [13][14][15][16] Recent advancements in micro/nanoelectromechanical system (M/ NEMS) technology show their potential to overcome such drawbacks and have the possibility to fabricate a miniaturized device with highly selective and sensitive clinical diagnostic functions.
An industry-ready strategic process
for the fabrication of cost-effective,
micropatterned Ni–Cu–Sn front contact metallization
has been demonstrated using maskless direct-write lithography, which
could effectively reduce the shadow loss and thereby enhance the efficiency
of silicon solar cells by increasing the active area. This investigation
also addresses the challenging issues in Ni–Cu–Sn metallization,
such as adhesion of the seed layer, low-ohmic contact formation, background
plating, and cell processing complications. An eco-friendly aluminum
paste with a sheet resistivity of 35 mΩ/cm2 has been
developed to fabricate the rear contact on silicon solar cells. A
front contact metallization grid with an optimal narrow finger width
of 20 μm with an interfinger spacing of 1000 μm has been
micropatterned using maskless direct-write lithography for the metallization
process. To improve the electrical and mechanical properties of the
nickel seed layer, the thickness was optimized as ∼100 nm with
a contact resistivity of 6.87 μΩ cm2, which
exhibited an adhesion strength of 2.5 N/mm. A low ohmic contact intermediate
silicide layer has been created at the Ni–Si interface by the
rapid thermal annealing process at 420 °C for 90 s with subsequent
copper and tin electroplating to form the Ni–Cu–Sn contacts.
An average cell efficiency of 18.5% is achieved for silicon solar
cells with a micropatterned Ni–Cu–Sn-based narrow line-width
front contact grid design, which could exhibit an ∼1% cell
efficiency enhancement as compared to commercial Ag screen-printed
solar cells. An ∼6% improvement in cell performance is achieved
by reducing the shadow loss with the Ni–Cu–Sn-based
front contact metallization as compared to the commercial Ag screen-printed
metallization.
Production and alignment of heterojunction metal oxide semiconductor nanomaterials-based sensing elements for microsensor devices has always posed fabrication challenges since it involves multi-step synthesis processes. Herein, we demonstrate a coaxial...
Herein, n-n type one dimensional ZnO@In2O3 heterojunction nanowires have been developed and its localized electron transfer properties during trace-level NO2 gas sensing process have been probed at room-temperature. Solvothermally synthesized...
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