| Quantum Computing | Superposition |
| Entanglement | Qubit |
| Quantum Gate | Decoherence |
| Quantum Supremacy | Quantum Algorithm |
| In the context of quantum computing, the fundamental concept of existing in multiple states simultaneously is observed by a qubit. | Computing that harnesses the principles of quantum mechanics to carry out computations. |
| "The essential information unit in quantum computing is known as a quantum bit, or simply a quantum bit. It possesses the ability to symbolize the values 0 or 1, or exist in a state of superposition encompassing both." | In quantum computing, there is a phenomenon where two or more qubits establish a correlation and effortlessly share information. |
| The loss of coherence or information in a quantum system occurs when it interacts with the external environment. | A fundamental element of quantum circuits that manipulates qubits with the purpose of executing precise operations. |
| A collection of instructions or operations designed to be executed on a quantum computer in order to solve particular problems. | The stage at which quantum computers can outperform classical computers in solving specific problems. |
| Quantum Error Correction | Hadamard Gate |
| Quantum Cryptography | Quantum Key Distribution |
| Eavesdropping | Quantum-Resistant Cryptography |
| Quantum Bits (Qubits) | DNA Computing |
| A quantum gate transforms a qubit from the base states to a superposition state with equal probability of different outcomes. | In quantum computing, a method is employed to safeguard against errors and decoherence that may occur throughout the computation process. |
| A method of transmitting cryptographic keys using quantum communication channels. | A branch of cryptography that uses principles of quantum mechanics to secure communication. |
| Cryptography algorithms designed to remain secure against attacks from quantum computers. | The unauthorized interception of communication intended for other parties, a major concern in quantum cryptography. |
| A field of study that focuses on the use of DNA molecules for performing computations. | The basic unit of quantum information, similar to classical bits but can be in a superposition of both 0 and 1 states. |
| Adleman | Parallelism |
| Algorithm | Hybridization |
| Molecular Computation | Turing Complete |
| DNA Strand | Nanotechnology |
| DNA computing utilizes the ability of DNA molecules to work together simultaneously, enabling efficient solution of intricate computational problems. | Named in honor of a visionary in the field, this method utilizes DNA to solve computational problems. |
| The process of forming DNA strands through the binding of complementary base pairs, an essential step in DNA computing. | A set of well-defined instructions or rules used to solve a particular computational problem in DNA computing. |
| A system or device that can perform any computation that a Turing machine can, including DNA computing systems. | The use of molecules, such as DNA, RNA, or proteins, to perform computational tasks. |
| The manipulation and control of matter on an atomic, molecular, and supramolecular scale, which plays a significant role in DNA computing. | A long chain of nucleotides, typically made up of adenine (A), cytosine (C), guanine (G), and thymine (T), used in DNA computing. |
| Nano Computing | Quantum Dots |
| Nanowires | Molecular Electronics |
| Nanoparticles | Nanocomponents |
| Self-Assembly | Nanorobotics |
| Tiny semiconductor particles with distinct quantum properties that enable the emission and absorption of light at specific wavelengths. | An computer science that concentrates on creating computer systems at a scale measured in nanometers. |
| utilizing individual molecules as building blocks for electronic parts to develop electronic devices and circuits on a minuscule scale. | Extremely thin wires made of semiconductor materials with a diameter of nanometers. |
| The elements of nanoscale devices and systems such as nanowires, nanotubes, nanoparticles, and additional nanostructures. | Microscopic particles, used in nano computing for data storage, sensing, and drug delivery. |
| Robots at nanometer scales to perform precise tasks inside the human body or other environments. | The automatic organization of nanostructures or nanomaterials into a desired structure or pattern without any external intervention. |
| Nanomedicine | Nanoelectronics |
| Nanomaterials | Molecular Manufacturing |
| Bio-Nanotechnology | Nano-Encapsulation |
| Nanofabrication |
| The use of nanoscale materials and devices to create electronic components and circuits with higher efficiency and performance. | The application of nanotechnology in healthcare for diagnosis, treatment, and prevention of diseases. |
| The process of building structures atom by atom, or molecule by molecule, to create advanced products with precise specifications. | Materials with structured components at the nanometer scale, exhibiting unique properties and applications. |
| The technique of enclosing nanoparticles or other substances within a protective shell for improved stability and controlled release. | The intersection of biology and nanotechnology for applications such as drug delivery, biomaterials, and biosensors. |
| The process of creating structures, devices, or patterns on the nanoscale, often using techniques like lithography and self-assembly. |