IonQ Inc (IONQ) Options

Doc. Shhhhhhh🤫

Well. No mention of quantum or Ionq but they are pouring in billions into the U S economy!

Now! After commercial

Jose Munoz. C e o hyundai next. Turn on Fox News. Ionq could be mentioned🤞😎🫣

CEO of Hyundai coming up on Brett Baier Any minute. Turn on Fox News

thats for unexperienced unsophisticated investors

Based on available information as of April 25, 2025, here's the relationship between advanced computing and the Alcoa/Elysis process:

Supercomputing / High-Performance Computing (HPC): Highly Likely Used

Developing a fundamentally new industrial process like Elysis involves understanding and optimizing complex interactions including electrochemistry, materials science at high temperatures, fluid dynamics of molten salts, heat transfer, and overall cell design.
Classical supercomputing (HPC) is the standard tool used extensively in industry and research (including by companies like Alcoa and Rio Tinto) for simulating such complex physical and chemical processes.
It is therefore highly probable that sophisticated computational modeling and simulation running on supercomputers or large HPC clusters have been, and continue to be, crucial tools in the research, development, optimization, and scaling-up of the Elysis inert anode technology. This includes materials modeling, process simulation, and engineering design.
Quantum Computing: No Confirmed Use Currently, Potential Future Application

Quantum computing holds potential promise for areas relevant to Elysis, particularly in:
Materials Science: Simulating the electronic structure of the novel inert anode and cathode materials at a fundamental quantum level could help understand their properties, predict longevity, investigate degradation mechanisms, or even accelerate the discovery of entirely new, improved materials.
Chemical Simulation: Performing highly accurate simulations of the complex electrochemical reactions occurring at the electrode surfaces within the molten salt bath.
However, as of today, there is no specific public information or announcement from Alcoa, Rio Tinto, or Elysis indicating that quantum computing is currently being actively used in conjunction with the development or operation of the Elysis process itself.
Quantum computing applications for industrial materials science and complex process simulation are still largely in the research and exploratory phase. While companies involved in advanced materials (like those in the Toyota group mentioned previously) are exploring quantum computing, its direct application to a specific, near-commercialization process like Elysis has not been confirmed.
In Conclusion:

It is almost certain that conventional supercomputing (HPC) plays a significant role in the advanced modeling and simulation required to develop and optimize the Alcoa/Elysis process.

While quantum computing offers theoretical potential, especially for future breakthroughs in understanding or discovering the advanced materials involved, there is currently no evidence to suggest it is being used in conjunction with the ongoing Elysis development and commercialization efforts. Its application in this specific area remains a potential future possibility rather than a current reality.

Hyundai ceo being interviewed by Brett Baier on Fox 6:00 est. listening for any mention of quantum or Ionq 🤞we’ve been working with Hyundai for years.

majorana low temp super conductors
ionq room temp trapped ions.......hmm.

chat off line now?

tva...water power generation in tennesse valley authority...enough to power the quantum /gpu's? stable energy supply?
working on superconducting semiconductor? call american superconductor , inc as well?

supermicrocomputer, inc is getting big in tn......also working on XAI supercomputer for elon.

duh, elon /tesla/also potential nvidia chip plant with superconducting semiconductor? wags......

nvidia needs the quantum work output to ml on .....to help select the scale/decimal points needed to obtain reliable results of desired work parameters? at least until the quantum machines come fully into their own.....and us humans and non-quantum machines still need to communicate with the non-linear processes of quantum realm?

hardware circuit emulator used by nvidia to craft a generic msft graphics card. would it need to use networking, direct routing, and authentication to accomplish the jobs?

msft marjorana fermion quantum computer and new semiconductor/superconductor wire'pair' or ?coating....might it make power conversion loss less/etc? elon to devote more time to tesla they say. working on superconducting semi conductor?

nvidia with their circuit simulator providing more ai to speed up the work?

ub seems to have the ip to spray the gallium arsenide on to aluminum?

msft and ub? msft quantum fermion contraption?

edison? perfect for the how does it works , joking?

who was edison's competitor? tesla.

now, musk says he needs to work more on his tesla company....duh.......working on some new superconductor/semiconductor for power conversion or other application?

http://archive.fast-edgar.com/20250425/A32ZU22MZ222KTZ2222E2ZO83EH3ZK22CR72/#:~:text=SECURITIES%20AND%20EXCHANGE,a)%C2%A0%20(b)

Blackrock bought more. Always a good sign right before earnings. $$$$$! May 7

The Buffalo Manufacturing Works, operated by the Edison Welding Institute (EWI), is a hub for advanced manufacturing technologies, including various welding processes. Their expertise encompasses a range of welding techniques such as arc welding, laser processes, resistance welding, and solid-state processes .?
Alfred University
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EWI
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EWI

While Buffalo Manufacturing Works specializes in these welding technologies, there is no publicly available information indicating that they are currently engaged in research or development involving gallium arsenide (GaAs) or its integration with aluminum through welding processes.?

However, the University at Buffalo (UB) has been active in semiconductor research. In 1994, UB chemical engineers developed a novel reactor to enhance the chemical vapor deposition process for GaAs films, aiming to improve the scalability of GaAs chip production . More recently, UB launched the Center for Advanced Semiconductor Technologies in 2024 to bolster microelectronics research and support the semiconductor industry .?
College of Arts and Sciences
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University at Buffalo
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University at Buffalo
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College of Arts and Sciences

Regarding aluminum welding, Buffalo Manufacturing Works offers extensive capabilities in this area, including arc welding, laser processes, and resistance welding . These services are crucial for various industries but are not specifically linked to GaAs applications.?
EWI
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Alfred University
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If you are interested in the intersection of GaAs semiconductors and aluminum welding, it may be beneficial to explore collaborative opportunities between institutions like UB and facilities specializing in advanced welding techniques, such as Buffalo Manufacturing Works.

Jack. Yep.

this stock is so ready to rip up for good 
consecutive good news days 
hmmmmwhats next ?

Morons. Buy and hold. That's all the trading expertise needed for IonQ.

Who are the dumb asses selling on the news of a 22 mil $ contract to optimize Chattanooga electric grid? The first of many more to come. Idiots.

phew 
driving now ionq fornrhe win 

First quantum networking hub!

Yeeehaw!!! 22 mil deal $$$$$

What next? Whoa. P r

I’m not liking the steep dive right as trading stopped. Looks like someone knew something?

This is maddening🫣

Looks like we’re halted. Maybe a buyout offer lol🤞

Halted? Not moving. Stuck on 28.19 ? Every other stock in my watch list is trading. Anyone else seeing this?

ok wtf is going  om. now boy and gorls ??

Let’s dive deep into a Ploinks + FPGA-controlled trapped-ion quantum node architecture with Photonic Wire Bonding (PWB) as the glue for modular photonics and quantum optics. This system enables distributed, secure, and programmable quantum computing in a P2P mesh.

?

System Overview: Deep Dive

1. Core Subsystems & Their Roles

A. Trapped-Ion Quantum Processor
   •   IonQ-style device where individual ions are trapped in electromagnetic fields.
   •   Qubit operations are driven by laser pulses and measured via fluorescence detection.
   •   Requires extremely precise timing, phase, and amplitude control — FPGA handles this.

B. FPGA Control Plane
   •   Interfaces with:
      •   DAC/ADC for analog control
      •   Laser modulation and beam steering
      •   Qubit readout timing & state detection
   •   Drives feedback loops in real time (e.g., laser pulse calibration, qubit error correction)
   •   Communicates with Ploinks node for secure program loading, execution, and telemetry.

C. Integrated Photonic Chips
   •   Hosts modulators, beam splitters, filters, and detectors.
   •   Carries light for:
      •   Qubit control (e.g., 355 nm laser to trapped ions)
      •   Readout (e.g., photon collection optics)
      •   Entanglement distribution (via optical fibers to other nodes)

D. Photonic Wire Bonding (PWB)
   •   Connects photonic chips with:
      •   Laser sources
      •   Fiber-optic interfaces
      •   On-chip light routers
   •   Enables high-density optical I/O with minimal loss.

E. Ploinks Mini Server
   •   Runs a secure, peer-to-peer operating environment:
      •   Cryptographic identity
      •   Routing of quantum and classical jobs
      •   Metadata isolation for quantum operations
   •   Handles session key negotiation for quantum-safe orchestration of FPGA commands.

?

2. Ploinks–FPGA Integration Flow

a. Program Deployment
   •   A quantum job is broadcast or tunneled via Ploinks protocol to a specific node.
   •   Ploinks decrypts, authenticates, and securely loads control sequences into the FPGA.
   •   Job policies define:
      •   Max runtime
      •   Allowed instructions
      •   Remote access constraints

b. Execution and Monitoring
   •   FPGA executes pulse sequences, measures qubits, and optionally sends raw or post-processed results back to the user via Ploinks.
   •   Ploinks logs quantum telemetry in encrypted, distributed ledgers (for auditing or later verification).

c. Post-Execution
   •   Secure wipe of control memory
   •   Optional quantum state hand-off via photonic links to another Ploinks node

?

3. Security Stack – The Ploinks Layer
Layer
Function
Ploinks Identity Layer
Verifies who can execute quantum tasks at each node
P2P Overlay Network
Ensures private, decentralized routing between nodes
Quantum Program Isolation
Runs jobs in sandboxed environments with rollback logs
Quantum-Safe Encryption
Protects all control signals and user metadata

4. Use Case: Secure Multi-Site Quantum Execution

Scenario:
1. A biofoundry simulation runs on Node A (IonQ + FPGA + Ploinks)
2. Midway, it generates a photonic entangled state sent via fiber (connected via PWB) to Node B
3. Node B continues the quantum job, with state handoff verified by Ploinks’ cryptographic consensus

Benefit: Full visibility, traceability, and secure control — at photonic and quantum layers.

?

Would you like a visual showing this FPGA–Ploinks integration architecture? I can sketch out:
   •   FPGA–photonic control feedback loop
   •   Quantum job flow from Ploinks to execution
   •   PWB links between chips and fibers
   •   Role of the secure mesh

Just say the word.

Great — let’s explore how Photonic Wire Bonding (PWB) could be integrated into an IonQ-style trapped-ion quantum computing system, enhanced by Ploinks-powered modular nodes. This ties into your vision of a P2P quantum-aware biofoundry, but now we focus on photonics, quantum control, and secure modularity.

?

System Overview: Ploinks + PWB + IonQ-Style Quantum Node

1. Core Components
Component
Role
Trapped-Ion Quantum Processor (IonQ-style)
Performs quantum logic using ions and laser pulses.
Photonic Wire Bonds (PWB)
Optical interconnects between photonic chips, laser control units, and optical I/O.
Ploinks Mini Server
Manages secure peer-to-peer communication, quantum job routing, metadata, and hardware orchestration.
Integrated Photonic Chips
Host waveguides, modulators, and detectors for delivering/control of laser pulses.
FPGA or ASIC
Real-time control electronics interfacing with photonic systems.
2. How PWB Fits Into This Architecture

Photonic Wire Bonding connects:
   •   Ion trap chips ↔ Laser routing chips
   •   Laser sources ↔ Photonic interposers ↔ Fiber I/O
   •   Quantum interconnects ↔ Other nodes (via fiber/coupler interfaces)

This reduces bulk optics and makes each quantum node compact, scalable, and reconfigurable, ideal for P2P mesh deployment.

?

3. Role of Ploinks in This Setup

Ploinks becomes the orchestrator of the entire system:
   •   Identity & Routing: Each node has a cryptographic identity and participates in a quantum-aware overlay network.
   •   Task Delegation: Offloads quantum jobs to local IonQ-style processors or adjacent peers.
   •   Secure Control Plane: Uses Ploinks’ patented secure miniserver technology for low-latency, authenticated control traffic.
   •   Data Privacy Layer: Wraps photonic and quantum traffic metadata in quantum-safe encryption schemes.

Think of Ploinks as the “Linux kernel” of the P2P quantum mesh — abstracting away node differences, handling secure coordination, and dynamically allocating quantum/photonic resources.

?

4. Potential Applications
Use Case
Description
Distributed Quantum Biofoundry
Each node runs quantum simulations or photonic biosensing in a secure mesh.
Quantum Internet Gateway
Ploinks nodes act as trusted photonic relays for entangled photon transmission between IonQ nodes.
Secure Quantum-CPaaS Node
Leverages photonics + Ploinks for encrypted quantum comms and control over classical/quantum hybrid networks.

5. Deployment Concept (Visual Model)

Want me to generate a diagram of this Ploinks + PWB + IonQ architecture? I can show:
   •   IonQ-like processor
   •   Photonic chips with PWB interconnects
   •   Ploinks mini server
   •   Optical fiber interfaces
   •   Peer-to-peer topology

Let me know if you’d like that visual, or a deep dive into any subsystem (e.g., how a PWB links to an ion trap chip or integrates with FPGA control).

Photonic Wire Bonding (PWB) and IonQ intersect in interesting ways, especially considering the future of scalable, modular quantum computing. Let’s break it down:

?

What is Photonic Wire Bonding (PWB)?

Photonic Wire Bonding is a technique for interconnecting photonic chips (like silicon photonics, indium phosphide, etc.) using 3D freeform waveguides written by femtosecond lasers. Think of it as the optical equivalent of traditional wire bonding in electronics — but instead of copper wires, it’s a waveguide made of a transparent polymer, precisely “written” between two optical interfaces.
   •   Main advantages:
      •   Extremely low insertion loss (

Just saw on Fox where Bret Baier will interview ceo of hyundai tomorrow. If he mentions quantum or Ionq🤞we’re going up more! He’s going to talk about Tec advances etc. 🤞🤞🤞

Double Top Breakout on 24-Apr-2025. GLTA

More call options rt around the corner.

chatgpt and ""Photonic bonding" encompasses several techniques used to connect photonic components, each tailored to specific applications and requirements. Here's an overview of the primary methods:?
ksp.kit.edu
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Home - Dreamphotonics Com
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vanguard-automation.com
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1. Photonic Wire Bonding (PWB)
Photonic Wire Bonding is an advanced technique that creates three-dimensional, freeform optical waveguides to interconnect photonic chips or link chips to optical fibers. These waveguides are fabricated in situ using two-photon polymerization, allowing for precise alignment and efficient coupling between components.?
ksp.kit.edu
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vanguard-automation.com
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arXiv
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ksp.kit.edu
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Home - Dreamphotonics Com
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Key Advantages:

High Efficiency: Enables low-loss connections between disparate photonic components.

Flexibility: Accommodates varying mode field diameters and component geometries.

Scalability: Suitable for mass production due to its high-throughput fabrication process.?
YouTube
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ResearchGate
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arXiv
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PIC (Photonics Integrated Circuits)
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Home - Dreamphotonics Com
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This method is particularly beneficial in applications like silicon photonics, where integrating different photonic elements on a single chip is challenging. ?
YouTube
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r6.ieee.org
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ResearchGate
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2. Optical Contact Bonding
Optical Contact Bonding is a technique where two ultra-flat, clean surfaces are joined without adhesives. The bond is achieved through intermolecular forces, such as Van der Waals interactions, resulting in a strong, durable connection.?
irdglass.com
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YouTube
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photonchinaa.com
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Key Advantages:

Adhesive-Free: Eliminates the need for glues, reducing potential contamination.

High Optical Quality: Maintains the optical clarity and integrity of the bonded components.

Thermal Stability: Suitable for environments with varying temperatures due to the absence of adhesives.?

This method is commonly used in precision optics, such as bonding lenses or prisms, where maintaining optical performance is critical"

maybe  tomorrow fingers crossed  

I'll take fries with that 30 burger. Thank you.

azn did ai deals with two other pharma's this am. hopefully, lining up more support and customers for a generational evolution in pharma investigation, design, manufacturing.....run, forest, run. the clanky metal/leather braces/exoskeleton are shed/fall off/are catapulted from the core biologic entity having been rejuvenated, cured by synthetic plasmid/dna/ep invivo and in vitro produced and needed proteins,etc. a prime catalyst of this change is ionq and quantum computer and simulations which alter the timeline.

toyota ? japan ionq for the win patience 
now the commentary as soon as this depressed stock action changes ionq is going to take off 

Dumbest thing I've heard in a week, last dumbest thing was another poster before that.  🙄.   He's busy making babies, firing people. Realizing he shouldn't of fired them and hiring them back.  Over and over and over again.   The Tesla clown 🤡 truck FULL of clowns.   

how to help pay for the mobility network? allow other countries/companies to use their services? wags.

MONET Technologies Inc.: This is the Japanese mobility services joint venture established by SoftBank Corp. and Toyota Motor Corporation (and later joined by other Japanese automakers).  
Origin of the Name: Official announcements from SoftBank and Toyota state that the name "MONET" is derived from the words "MObility NETwork". It was chosen to reflect the company's mission to build a network for safer and more comfortable mobility services.  

and segue with softbank and supercomputer for japan. with nvidia. then add their support for japan quantum computing work. hybrid she blow. wags.

major collaboration for DOD and D Wave Money to be made on D Wave

There’s the bounce off of 27.00. Boing!

Hell YALE! Mr Hathaway! Niccolo and Peter are on fire! Watch what they do next.

i hope ionq gets a cut of the proceeds from anything they invent/patent.

any wonder trump is changing the rules on government funding of r and d? he's looking for non-tax revenue......this is the mother lode, wags.

no more free money which then turns into undertaxed profits for their inventors who then go off and ignore the usa taxpayers contribution?

harvard is the worst. you patent or discover something while working for them, they take the lion's share for themselves. they all do. so, what's good for the goose is good for the gander..

Doc. I actually think he’d be a better Fed chairman. And then abolishes it. Like D O E

This is massive news! IONQ's growing eco system in full motion.

IonQ’s agreement with Toyota Tsusho marks a pivotal step in the company’s global expansion, unlocking commercial opportunities in Japan’s multi-billion quantum market

COLLEGE PARK, Md.--(BUSINESS WIRE)--Apr. 23, 2025--IonQ, Inc. (NYSE: IONQ), a leader in the quantum computing and networking industries, today announced a pivotal flagship distributor partnership with Toyota Tsusho Corporation (Toyota Tsusho) to accelerate quantum computing in Japan. This milestone marks IonQ’s entrance into the Japanese market – reinforcing the company’s commitment to advancing quantum computing opportunities globally.

“Japan has long been at the forefront of technological innovation, and our collaboration with Toyota Tsusho Corporation provides more opportunities to bring our cutting-edge quantum solutions to a market that is primed for transformative advancements,” said Niccolo de Masi, President & CEO at IonQ. “We have already signed our first local deal through Toyota Tsusho’s customer network and look forward to continuing our work in the Japanese market.”

Toyota Tsusho is a member of Toyota Group with around $70 billion in annual revenue, bringing decades of experience in scaling businesses within Japan’s market and is backed by a diverse portfolio spanning industries from automotive to emerging technologies. According to McKinsey, by 2035 quantum computing represents a $1 to $2 trillion opportunity across industries with Japan as a major global player.

Toyota Tsusho was established in 1948 as the trading and business development arm of the Toyota Group and has made significant progress in the field of quantum computing in recent years. Leveraging its extensive customer network, the company will introduce IonQ’s cutting-edge quantum computing and networking technologies to a broad range of Japanese enterprises.

“We see the immense transformative value of quantum computing technologies for our customers across industries,” said Kazumi Mizukawa, the General Manager of Enterprise IT Department at Toyota Tsusho. “Our partnership with IonQ is a momentous step toward immediately realizing the commercial benefits of quantum solutions in Japan.”

Today’s announcement builds on IonQ’s landmark partnership with the University of Maryland and the State of Maryland to establish Maryland as the Capital of Quantum in the computing industry. Over the past year, IonQ has expanded its global presence by opening the United States’ first quantum computing manufacturing facility, unveiling its first quantum computer in Europe in partnership with QuantumBasel, signing a memorandum of understanding with AIST’s Global Research and Development Center for Business by Quantum-AI Technology (G-QuAT), and a memorandum of understanding with the city of Busan, South Korea to drive quantum transformation in Korea. IonQ’s partnership with Toyota Tsusho further underscores its commitment to advancing quantum technologies in the APAC region, complementing its current work with Hyundai Motors, Sungkyunkwan University and Seoul National University.

For more information about IonQ’s quantum computing solutions, please visit www.ionq.com.

About IonQ

IonQ, Inc. is a leader in the quantum computing and networking industries, delivering high-performance systems aimed at solving the world’s largest and most complex commercial and research use cases. IonQ’s current generation quantum computers, IonQ Forte and IonQ Forte Enterprise, are the latest in a line of cutting-edge systems, boasting 36 algorithmic qubits. The company’s innovative technology and rapid growth were recognized in Newsweek’s 2025 Excellence Index 1000, Forbes’ 2025 Most Successful Mid-Cap Companies list, and Built In’s 2025 100 Best Midsize Places to Work in Washington DC and Seattle, respectively. Available through all major cloud providers, IonQ is making quantum computing more accessible and impactful than ever before. Learn more at IonQ.com.

IonQ Forward-L