Your search keyword '"Aeppli, Gabriel"' showing total 262 results

251. Virus lasers for biological detection.

Author

Hales JE, Matmon G, Dalby PA, Ward JM, and Aeppli G

Subjects

Antibodies, Monoclonal, Bacteriophage M13 ultrastructure, Biophysical Phenomena, Biosensing Techniques instrumentation, DNA Probes, Electrons, Fluorescent Dyes, Humans, Ligands, Models, Chemical, Nucleic Acids, Polymerase Chain Reaction, Biosensing Techniques methods, DNA analysis, Lasers, Oligonucleotide Probes chemistry, Viruses

Abstract

The selective amplification of DNA in the polymerase chain reaction is used to exponentially increase the signal in molecular diagnostics for nucleic acids, but there are no analogous techniques for signal enhancement in clinical tests for proteins or cells. Instead, the signal from affinity-based measurements of these biomolecules depends linearly on the probe concentration. Substituting antibody-based probes tagged for fluorescent quantification with lasing detection probes would create a new platform for biomarker quantification based on optical rather than enzymatic amplification. Here, we construct a virus laser which bridges synthetic biology and laser physics, and demonstrate virus-lasing probes for biosensing. Our virus-lasing probes display an unprecedented > 10,000 times increase in signal from only a 50% increase in probe concentration, using fluorimeter-compatible optics, and can detect biomolecules at sub-100 fmol mL -1 concentrations.

Published

2019

252. Giant non-linear susceptibility of hydrogenic donors in silicon and germanium.

Author

Le NH, Lanskii GV, Aeppli G, and Murdin BN

Abstract

Implicit summation is a technique for the conversion of sums over intermediate states in multiphoton absorption and the high-order susceptibility in hydrogen into simple integrals. Here, we derive the equivalent technique for hydrogenic impurities in multi-valley semiconductors. While the absorption has useful applications, it is primarily a loss process; conversely, the non-linear susceptibility is a crucial parameter for active photonic devices. For Si:P, we predict the hyperpolarizability ranges from χ (3) / n 3D  = 2.9 to 580 × 10 -38  m 5 /V 2 depending on the frequency, even while avoiding resonance. Using samples of a reasonable density, n 3D , and thickness, L , to produce third-harmonic generation at 9 THz, a frequency that is difficult to produce with existing solid-state sources, we predict that χ (3) should exceed that of bulk InSb and χ (3) L should exceed that of graphene and resonantly enhanced quantum wells., Competing Interests: Conflict of interestThe authors declare that they have no conflict of interest., (© The Author(s) 2019.)

Published

2019

253. Nondestructive imaging of atomically thin nanostructures buried in silicon.

Author

Gramse G, Kölker A, Lim T, Stock TJZ, Solanki H, Schofield SR, Brinciotti E, Aeppli G, Kienberger F, and Curson NJ

Abstract

It is now possible to create atomically thin regions of dopant atoms in silicon patterned with lateral dimensions ranging from the atomic scale (angstroms) to micrometers. These structures are building blocks of quantum devices for physics research and they are likely also to serve as key components of devices for next-generation classical and quantum information processing. Until now, the characteristics of buried dopant nanostructures could only be inferred from destructive techniques and/or the performance of the final electronic device; this severely limits engineering and manufacture of real-world devices based on atomic-scale lithography. Here, we use scanning microwave microscopy (SMM) to image and electronically characterize three-dimensional phosphorus nanostructures fabricated via scanning tunneling microscope-based lithography. The SMM measurements, which are completely nondestructive and sensitive to as few as 1900 to 4200 densely packed P atoms 4 to 15 nm below a silicon surface, yield electrical and geometric properties in agreement with those obtained from electrical transport and secondary ion mass spectroscopy for unpatterned phosphorus δ layers containing ~10 13 P atoms. The imaging resolution was 37 ± 1 nm in lateral and 4 ± 1 nm in vertical directions, both values depending on SMM tip size and depth of dopant layers. In addition, finite element modeling indicates that resolution can be substantially improved using further optimized tips and microwave gradient detection. Our results on three-dimensional dopant structures reveal reduced carrier mobility for shallow dopant layers and suggest that SMM could aid the development of fabrication processes for surface code quantum computers.

Published

2017

254. High-resolution non-destructive three-dimensional imaging of integrated circuits.

Author

Holler M, Guizar-Sicairos M, Tsai EH, Dinapoli R, Müller E, Bunk O, Raabe J, and Aeppli G

Abstract

Modern nanoelectronics has advanced to a point at which it is impossible to image entire devices and their interconnections non-destructively because of their small feature sizes and the complex three-dimensional structures resulting from their integration on a chip. This metrology gap implies a lack of direct feedback between design and manufacturing processes, and hampers quality control during production, shipment and use. Here we demonstrate that X-ray ptychography-a high-resolution coherent diffractive imaging technique-can create three-dimensional images of integrated circuits of known and unknown designs with a lateral resolution in all directions down to 14.6 nanometres. We obtained detailed device geometries and corresponding elemental maps, and show how the devices are integrated with each other to form the chip. Our experiments represent a major advance in chip inspection and reverse engineering over the traditional destructive electron microscopy and ion milling techniques. Foreseeable developments in X-ray sources, optics and detectors, as well as adoption of an instrument geometry optimized for planar rather than cylindrical samples, could lead to a thousand-fold increase in efficiency, with concomitant reductions in scan times and voxel sizes.

Published

2017

255. Fast diffusion of water nanodroplets on graphene.

Author

Ma M, Tocci G, Michaelides A, and Aeppli G

Subjects

Diffusion, Wettability, Graphite chemistry, Nanostructures chemistry, Water chemistry

Abstract

Diffusion across surfaces generally involves motion on a vibrating but otherwise stationary substrate. Here, using molecular dynamics, we show that a layered material such as graphene opens up a new mechanism for surface diffusion whereby adsorbates are carried by propagating ripples in a motion similar to surfing. For water nanodroplets, we demonstrate that the mechanism leads to exceedingly fast diffusion that is 2-3 orders of magnitude faster than the self-diffusion of water molecules in liquid water. We also reveal the underlying principles that regulate this new mechanism for diffusion and show how it also applies to adsorbates other than water, thus opening up the prospect of achieving fast and controllable motion of adsorbates across material surfaces more generally.

Published

2016

256. Corrigendum: Crystallinity of tellurium capping and epitaxy of ferromagnetic topological insulator films on SrTiO3.

Author

Park J, Soh YA, Aeppli G, Feng X, Ou Y, He K, and Xue QK

Published

2015

257. Charge-order domain walls with enhanced conductivity in a layered manganite.

Author

Ma EY, Bryant B, Tokunaga Y, Aeppli G, Tokura Y, and Shen ZX

Abstract

Interfaces and boundaries in condensed-matter systems often have electronic properties distinct from the bulk material and thus have become a topic of both fundamental scientific interest and technological importance. Here we identify, using microwave impedance microscopy, enhanced conductivity of charge-order domain walls in the layered manganite Pr(Sr0.1Ca0.9)2Mn2O7. We obtain a complete mesoscopic map of surface topography, crystalline orientation and electronic phase, and visualize the thermal phase transition between two charge-ordered phases. In both phases, charge-order domains occur with domain walls showing enhanced conductivity likely due to local lifting of the charge order. Finite element analysis shows that the resolved domain walls can be as narrow as few nanometres. The domain walls are stabilized by structural twins and have a strong history dependence, suggesting that they may be manipulated to create novel devices.

Published

2015

258. Dipolar antiferromagnetism and quantum criticality in LiErF₄.

Author

Kraemer C, Nikseresht N, Piatek JO, Tsyrulin N, Dalla Piazza B, Kiefer K, Klemke B, Rosenbaum TF, Aeppli G, Gannarelli C, Prokes K, Podlesnyak A, Strässle T, Keller L, Zaharko O, Krämer KW, and Rønnow HM

Abstract

Magnetism has been predicted to occur in systems in which dipolar interactions dominate exchange. We present neutron scattering, specific heat, and magnetic susceptibility data for LiErF(4), establishing it as a model dipolar-coupled antiferromagnet with planar spin-anisotropy and a quantum phase transition in applied field H(c|| = 4.0 ± 0.1 kilo-oersteds. We discovered non-mean-field critical scaling for the classical phase transition at the antiferromagnetic transition temperature that is consistent with the two-dimensional XY/h(4) universality class; in accord with this, the quantum phase transition at H(c) exhibits three-dimensional classical behavior. The effective dimensional reduction may be a consequence of the intrinsic frustrated nature of the dipolar interaction, which strengthens the role of fluctuations.

Published

2012

259. Protein denaturation and protein:drugs interactions from intrinsic protein fluorescence measurements at the nanolitre scale.

Author

Gaudet M, Remtulla N, Jackson SE, Main ER, Bracewell DG, Aeppli G, and Dalby PA

Subjects

Animals, Binding Sites, Cattle, Drug Design, Models, Molecular, Protein Conformation, Sensitivity and Specificity, Serum Albumin, Bovine chemistry, Tacrolimus Binding Protein 1A genetics, Thermodynamics, Anti-Bacterial Agents chemistry, Fluorescence, Microfluidics methods, Protein Denaturation, Sirolimus chemistry, Tacrolimus Binding Protein 1A chemistry

Abstract

Protein stability and ligand-binding affinity measurements are widely required for the formulation of biopharmaceutical proteins, protein engineering and drug screening within life science research. Current techniques either consume too much of often precious biological or compound materials, in large sample volumes, or alternatively require chemical labeling with fluorescent tags to achieve measurements at submicrolitre volumes with less sample. Here we present a quantitative and accurate method for the determination of protein stability and the affinity for small molecules, at only 1.5-20 nL optical sample volumes without the need for fluorescent labeling, and that takes advantage of the intrinsic tryptophan fluorescence of most proteins. Coupled to appropriate microfluidic sample preparation methods, the sample requirements could thus be reduced 85,000-fold to just 10(8) molecules. The stability of wild-type FKBP-12 and a destabilizing binding-pocket mutant are studied in the presence and absence of rapamycin, to demonstrate the potential of the technique to both drug screening and protein engineering. The results show that 75% of the interaction energy between FKBP-12 and rapamycin originates from residue Phe99 in the binding site.

Published

2010

260. A novel route for the inclusion of metal dopants in silicon.

Author

Gardener JA, Liaw I, Aeppli G, Boyd IW, Chater RJ, Jones TS, McPhail DS, Sankar G, Stoneham AM, Sikora M, Thornton G, and Heutz S

Subjects

Macromolecular Substances chemistry, Macromolecular Substances radiation effects, Manganese radiation effects, Materials Testing, Molecular Conformation radiation effects, Nanostructures radiation effects, Nanostructures ultrastructure, Particle Size, Silicon radiation effects, Surface Properties radiation effects, Ultraviolet Rays, Crystallization methods, Manganese chemistry, Nanostructures chemistry, Nanotechnology methods, Silicon chemistry

Abstract

We report a new method for introducing metal atoms into silicon wafers, using negligible thermal budget. Molecular thin films are irradiated with ultra-violet light releasing metal species into the semiconductor substrate. Secondary ion mass spectrometry and x-ray absorption spectroscopy show that Mn is incorporated into Si as an interstitial dopant. We propose that our method can form the basis of a generic low-cost, low-temperature technology that could lead to the creation of ordered dopant arrays.

Published

2010

261. Launch of the London Centre for Nanotechnology.

Author

Aeppli G and Pankhurst Q

Subjects

London, Academies and Institutes organization & administration, Biomedical Research organization & administration, Nanomedicine organization & administration, Nanotechnology organization & administration, Research organization & administration

Abstract

Is nanomedicine an area with the promise that its proponents claim? Professors Gabriel Aeppli and Quentin Pankhurst explore the issues in light of the new London Centre for Nanotechnology (LCN)--a joint enterprise between Imperial College and University College London--opened on November 7, 2006. The center is a multidisciplinary research initiative that aims to bridge the physical, engineering and biomedical sciences. In this interview, Professor Gabriel Aeppli, LCN co-Director, and Deputy Director Professor Quentin Pankhurst discuss the advent and future role of the LCN with Nanomedicine's Morag Robertson. Professor Aeppli was formerly with NEC, Bell Laboratories and MIT and has more than 15 years' experience in the computer and telecommunications industry. Professor Pankhurst is a physicist with more than 20 years' experience of working with magnetic materials and nanoparticles, who now works closely with clinicians and medics on innovative healthcare applications. He also recently formed the new start-up company Endomagnetics Inc.

Published

2006

262. Applied physics: making sense of magnetic fields.

Author

Soh YA and Aeppli G

Published

2002