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ronaldtateblog · 11 months ago

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Understanding Quantum Computers: A New Era in Computing

Understanding Quantum Computers: A New Era in Computing Recently, my friend Marques and I had the unique opportunity to visit IBM and see a quantum computer up close. Quantum computers are fascinating and hold the potential to revolutionize what we can achieve with computers. However, they are not simply a better, faster version of the current computers we use. Instead, they are something…

#Achieving Success #Quantum Computers #Quantum Computing Applications #The Future Impact of Quantum Computing

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techtoio · 1 year ago

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The Rise of Quantum Computing: What You Need to Know

Introduction

Quantum computing is poised to revolutionize the tech industry, promising to solve problems beyond the reach of classical computers. As this futuristic technology rapidly advances, it’s essential to understand its basics, potential, and implications. This article will delve into what quantum computing is, how it works, and why it matters. Read to continue

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tec4tric · 1 year ago

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Quantum Computer: Top 10 Real-World Applications

Quantum Computer applications are changing the world. Quantum computing, once confined to science fiction, is now a tangible reality with the potential to transform various industries. In this blog post, we will look into the exciting world of quantum computer applications and witness the groundbreaking impact. Speeding Up Cryptography Quantum computers have the potential to revolutionize…

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#Quantum Computer #Quantum Computing #Quantum Computing Applications

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niconiconwo · 1 year ago

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The latest quantum computing news is funny as hell, and mirrors the fiasco with Google's claim a few years ago. They claimed to have done a calculation that would've taken 10K years on a conventional processor, then maybe a few months later a Chinese group proved it was doable in five minutes on silicon. IBM's recent claim has already been refuted, with a research group making a better accurate calculation in only several minutes.

I'm all for quantum optimism, but it is not the era-changer that their marketing makes it out to be. It's also not even useful for anything yet and given the immense cost it's kind of silly. I don't particularly care for investment grifts but I also don't like false information.

#we are still a long time off from commercial application of quantum computing #and we haven't even reached the peak of silicon technology either

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ds4u · 1 month ago

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Experience GITEX Europe 2025: AI, Healthtech & Custom Software Development Solutions

Explore the future of Healthtech, AI, and custom software development at GITEX Europe 2025 in Berlin. Join 40,000+ tech leaders and discover cutting-edge innovations, including AR/VR, cybersecurity, cloud, and healthcare IT. Visit DreamSoft4u’s booth for next-gen software services and intelligent digital solutions.

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newstodays1 · 3 months ago

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Nanotechnology and Supercomputing: A Synergy for the Future

Introduction The intersection of nanotechnology and supercomputing is driving unprecedented advancements in computational power, energy efficiency, and miniaturization. As traditional silicon-based computing approaches its physical limits, nanomaterials and quantum-scale innovations are paving the way for next-generation supercomputers capable of solving complex global challenges. This blog…

#application of nanomaterials #Education #nanomaterial #nanoscience #nanotechnology #quantum computing #quantum dots #science #supercomputing #technology

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manmishra · 4 months ago

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🚀 Dive into the future of quantum computing! Will we see breakthroughs in just 5 years, or is it a decades-long journey? Discover the insights and advancements shaping today's tech landscape! #QuantumComputing #TechRevolution #FutureOfTech

#future of tech #industry insights #market predictions #practical applications #Quantum Computing #Quantum technology #tech revolution

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jcmarchi · 4 months ago

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Microsoft’s Majorana hype: Real proof or just marketing?

New Post has been published on https://thedigitalinsider.com/microsofts-majorana-hype-real-proof-or-just-marketing/

Microsoft’s Majorana hype: Real proof or just marketing?

Introduction: The quest for reliable qubits

Quantum computing faces a fundamental challenge: qubits, the basic units of quantum information, are notoriously fragile.

Conventional approaches, such as superconducting circuits and trapped ions, require intricate error-correction techniques to counteract decoherence. Microsoft has pursued an alternative path: Majorana-based topological qubits, which promise inherent noise resistance due to their non-local encoding of quantum information.

This idea, based on theoretical work from the late 1990s, suggests that quantum states encoded in Majorana zero modes (MZMs) could be immune to local noise, reducing the need for extensive error correction. Microsoft has invested two decades into developing these qubits, culminating in the recent “Majorana 1” prototype.

However, given past controversies and ongoing skepticism, the scientific community remains cautious in interpreting these results.

The scientific basis of Majorana-based qubits

Topological qubits derive their stability from the spatial separation of Majorana zero modes, which exist at the ends of specially engineered nanowires. These modes exhibit non-Abelian statistics, meaning their quantum state changes only through specific topological operations, rather than local perturbations. This property, in theory, makes Majorana qubits highly resistant to noise.

Microsoft’s approach involves constructing “tetrons,” pairs of Majorana zero modes that encode a single logical qubit through their collective parity state. Operations are performed using simple voltage pulses, which avoids the complex analog controls required for traditional superconducting qubits.

Additionally, digital measurement-based quantum computing is employed to correct errors passively. If successful, this design could lead to a scalable, error-resistant quantum architecture.

However, while the theoretical framework for Majorana qubits is robust, experimental verification has been challenging. Majorana zero modes do not occur naturally and must be engineered in materials like indium arsenide nanowires in proximity to superconductors.

Establishing that these states exist and behave as expected has proven difficult, leading to past controversies.

Historical controversies: The 2018 retraction

A major setback for Microsoft’s Majorana initiative occurred in 2018 when researchers, including Leo Kouwenhoven’s team at TU Delft (funded by Microsoft), published a Nature paper claiming to have observed quantized conductance signatures consistent with Majorana zero modes.

This was hailed as a breakthrough in topological quantum computing. However, by 2021, the paper was retracted after inconsistencies were found in data analysis. Independent replication attempts failed to observe the same results, and an internal investigation revealed that a key graph in the original paper had been selectively manipulated.

This event, dubbed the “Majorana Meltdown,” significantly damaged the credibility of Microsoft’s approach. It highlighted the challenge of distinguishing genuine Majorana modes from other quantum states that mimic their signatures due to material imperfections. Many physicists became skeptical, arguing that similar issues could undermine subsequent claims.

Experimental progress and remaining challenges

Despite the 2018 controversy, Microsoft and its collaborators have continued refining their approach. The recent announcement of the “Majorana 1” chip in 2025 presents experimental evidence supporting the feasibility of Majorana-based qubits.

Key advancements include:

Fabrication of “topoconductor” materials: Microsoft developed a new indium arsenide/aluminum heterostructure to reliably host Majorana zero modes.

Parity measurement success: The team demonstrated that they could measure the qubit’s parity (even vs. odd electron occupation) with 99% accuracy, a crucial validation step.

Increased parity lifetime: The qubit’s state exhibited stability over milliseconds, significantly surpassing superconducting qubits’ coherence times (which are typically in the microsecond range).

Digital control implementation: Unlike analog-tuned superconducting qubits, Majorana qubits can be manipulated with simple voltage pulses, theoretically enabling large-scale integration.

While these are important steps forward, the experiments have not yet demonstrated key quantum operations, such as two-qubit entanglement via non-Abelian braiding. Until this milestone is achieved, claims about the superiority of topological qubits remain speculative.

Comparison with other qubit technologies

To assess Microsoft’s claims, it is useful to compare Majorana qubits with existing quantum computing platforms:

Superconducting qubits (IBM, Google): These have demonstrated successful quantum error correction and multi-qubit entanglement but require extensive calibration and error correction. Fidelity levels for two-qubit gates currently range around 99.9%.

Trapped-ion qubits (IonQ, Quantinuum): These offer superior coherence times (seconds vs. microseconds for superconductors) but suffer from slow gate speeds and complex laser-based control.

Majorana-based qubits: Theoretically provide built-in error protection, reducing the need for extensive error correction. However, experimental validation is still in progress, and large-scale integration remains untested.

Microsoft has argued that Majorana qubits will enable a quantum computer with a million qubits on a single chip, a feat that conventional qubits struggle to achieve.

While this is an exciting possibility, many researchers caution that scaling challenges remain, especially given the extreme conditions (millikelvin temperatures, precise nanowire fabrication) required for Majorana qubits.

Despite recent progress, many physicists remain skeptical of Microsoft’s claims.

Key concerns include:

Lack of direct evidence for Majorana zero modes: While Microsoft’s 2025 Nature paper presents strong supporting data, the scientific community has yet to reach a consensus that Majorana modes have been definitively observed.

Alternative explanations for observed phenomena: Many experimental signatures attributed to Majorana states could be explained by disorder-induced states or other trivial effects in semiconductor-superconductor interfaces.

Unverified large-scale claims: Microsoft’s assertion that its approach will lead to fault-tolerant quantum computing “within years, not decades” is met with skepticism. Experts note that even the most advanced conventional quantum computers are still years away from practical applications, and scaling from an 8-qubit chip to a million-qubit processor is an enormous leap.

Comparison to competing approaches: Some argue that improvements in quantum error correction for superconducting and trapped-ion qubits may render topological qubits unnecessary by the time they are fully realized.

A Promising but unproven path

Microsoft’s Majorana-based qubits represent one of the most ambitious efforts in quantum computing. The theoretical promise of intrinsic error protection and simplified quantum control is compelling, and recent experiments provide encouraging evidence that topological qubits can be realized.

However, historical controversies, ongoing skepticism, and the lack of key demonstrations (such as two-qubit gates) mean that these qubits are not yet a proven alternative to existing technologies.

While Microsoft has made significant strides in overcoming past setbacks, their claims of imminent large-scale quantum computing should be met with caution.

The coming years will be critical in determining whether Majorana qubits will revolutionize quantum computing or remain an elegant but impractical idea. As independent verification and further experiments unfold, the scientific community will ultimately decide whether Microsoft’s bold bet pays off.

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mobmaxime · 4 months ago

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#Artificial Intelligence Trends 2025 #Blockchain Innovations 2025 #Energy-Efficient Computing Technologies #Impact of AI on Future Industries #Quantum Computing Applications in Business

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2ribu · 6 months ago

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Evolusi Framework AI: Alat Terbaru untuk Pengembangan Model AI di 2025

Kecerdasan buatan (AI) telah menjadi salah satu bidang yang paling berkembang pesat dalam beberapa tahun terakhir. Pada tahun 2025, teknologi AI diperkirakan akan semakin maju, terutama dengan adanya berbagai alat dan framework baru yang memungkinkan pengembang untuk menciptakan model AI yang lebih canggih dan efisien. Framework AI adalah sekumpulan pustaka perangkat lunak dan alat yang digunakan…

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nozycatblogger · 9 months ago

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Quantum Qubits Entanglement and More Applications and its Brief Descriptions

Quantum computing is a fascinating field that leverages the principles of quantum mechanics to process information in ways that classical computers cannot. Here are the key concepts: Quantum Computing Quantum computers use quantum bits (qubits) instead of classical bits. While classical bits can be either 0 or 1, qubits can exist in a superposition of both states simultaneously, thanks to the…

#Quantum Computing #quantum entanglement #quantum entanglement applications

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zomb13s · 9 months ago

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The Evolution and Impact of Supercomputers and Servers in the Modern World

Introduction Supercomputers represent the pinnacle of computational power, evolving from massive, room-sized machines to sleek, compact devices with immense processing capabilities. These advancements have drastically transformed scientific research, industry, and even daily life. In parallel, server technology has undergone a rapid evolution, supporting the backbone of global networks and data…

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gracetheacefromouterspace · 11 months ago

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I have too many hobbies, any body want one?

#Like it's a problem #sadly much of time is spent on my non hobby #work #though I have been studying quantum computing there #but not like the math #like the business applications #which is less fun

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ai-perceiver · 1 year ago

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#How Will Quantum Computing Affect Artificial Intelligence Applications

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techtoio · 1 year ago

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How to Create Stunning Graphics with Adobe Photoshop

Introduction

Adobe Photoshop is the preferred software for graphic designers, photographers, and digital artists worldwide. Its powerful tools and versatile features lead to the foundation of an essential application that one needs to create the best kind of graphics. Mastering Photoshop can improve your creative-level projects, whether you are a beginner or an experienced user. In this tutorial, we will walk you through the basics and advanced techniques so you can create stunning graphics with the help of Adobe Photoshop. Read to continue

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nomijigars-blog · 1 year ago

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#technology #quantum computing #applications #examples

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