Class 11 Physics MCQs | Chapter 1: Physical World – Part 2 (NCERT/CBSE)

Correct Answer: Energy cannot be created or destroyed, only transformed from one form to another

Explanation: The first law of thermodynamics states that energy cannot be created or destroyed; it can only change forms or be transferred from one part of a system to another.

Correct Answer: Second Law of Thermodynamics

Explanation: The second law of thermodynamics states that the entropy of an isolated system never decreases, implying that the disorder (or randomness) in a system tends to increase over time.

Correct Answer: Zeroth Law of Thermodynamics

Explanation: The Zeroth Law of Thermodynamics establishes the concept of thermal equilibrium and provides the basis for temperature measurement. It states that if two systems are each in thermal equilibrium with a third system, they are also in thermal equilibrium with each other.

Correct Answer: Electromagnetism

Explanation: Electromagnetism is the branch of physics that deals with the study of electric charges, electric fields, magnetic fields, and their interactions with each other and with matter.

Correct Answer: Coulomb

Explanation: The SI unit of electric charge is the Coulomb (C). It is defined as the amount of charge transported by a current of one ampere in one second.

Correct Answer: James Clerk Maxwell

Explanation: James Clerk Maxwell formulated the mathematical laws of electromagnetism, including Maxwell’s equations, which describe the behavior of electric and magnetic fields.

Correct Answer: Faraday’s Law of Electromagnetic Induction

Explanation: Faraday’s Law of Electromagnetic Induction states that a changing magnetic field induces an electromotive force (emf) in a conductor, leading to the generation of an electric current.

Correct Answer: Meson

Explanation: Mesons are particles responsible for carrying the nuclear force that binds protons and neutrons together in an atomic nucleus. They are composed of a quark and an antiquark pair.

Correct Answer: Fission

Explanation: Nuclear Fission is the process in nuclear physics where a heavy atomic nucleus splits into lighter nuclei, accompanied by the release of a large amount of energy. It is the principle behind nuclear reactors and atomic bombs.

Correct Answer: Astrophysics

Explanation: Astrophysics is the branch of physics that deals with the study of the universe, including its origins, evolution, and phenomena such as galaxies, stars, planets, and cosmic radiation.

Correct Answer: By developing new materials, technologies, and processes

Explanation: Physics contributes to technological advancements by providing the theoretical basis for understanding natural phenomena and developing practical applications that improve materials, technologies, and processes.

Correct Answer: Electromagnetism

Explanation: Electromagnetism plays a crucial role in the development of modern communication systems by enabling the transmission and reception of electromagnetic waves, such as radio waves, microwaves, and light waves.

Correct Answer: By understanding the principles of optics and developing imaging techniques

Explanation: Physics contributes to medical technology by applying principles of optics to develop advanced imaging techniques such as X-rays, MRI, and ultrasound, which are essential for medical diagnosis and treatment.

Correct Answer: Solid State Physics

Explanation: Solid State Physics is crucial for the development of renewable energy technologies such as solar cells and wind turbines, which rely on the principles of semiconductor materials to convert sunlight and wind into electrical energy.

Correct Answer: By applying principles of mechanics and aerodynamics to design aircraft and spacecraft

Explanation: Physics contributes to aerospace engineering by applying principles of mechanics, aerodynamics, and thermodynamics to design efficient and safe aircraft and spacecraft for various applications.

Correct Answer: Quantum Mechanics

Explanation: Quantum Mechanics is fundamental to the development of modern electronics and computing by providing the basis for understanding the behavior of electrons in semiconductors, which is essential for devices such as transistors and microprocessors.

Correct Answer: Condensed Matter Physics

Explanation: Condensed Matter Physics is essential for understanding the behavior of materials under extreme conditions, such as high pressures and temperatures, which is crucial for applications in materials science, geophysics, and engineering.

Correct Answer: By studying the principles of energy transfer and climate change

Explanation: Physics contributes to environmental sciences by studying the principles of energy transfer, climate change, and atmospheric physics, which are essential for understanding and mitigating environmental issues.

Correct Answer: Classical Mechanics

Explanation: Classical Mechanics plays a crucial role in the development of modern transportation systems by providing the theoretical foundation for understanding motion, dynamics, and mechanical systems used in vehicles and transportation infrastructure.

Correct Answer: By providing insights into the structure, properties, and behavior of materials

Explanation: Physics contributes to material science by providing insights into the structure, properties, and behavior of materials at the atomic and subatomic levels, which is crucial for developing new materials with specific properties and applications.

Correct Answer: By applying principles of electromagnetism to transmit and receive signals

Explanation: Physics contributes to telecommunications by applying principles of electromagnetism to transmit and receive signals, enabling technologies such as radio, television, mobile phones, and satellite communication.

Correct Answer: Quantum Mechanics

Explanation: Quantum Mechanics is crucial for the development of medical imaging technologies like CT scans and PET scans, which rely on principles such as wave-particle duality and quantum tunneling to create detailed images of internal body structures.

Correct Answer: By studying principles of thermodynamics and developing efficient energy conversion technologies

Explanation: Physics contributes to energy generation by studying principles of thermodynamics and developing efficient energy conversion technologies such as steam turbines, solar panels, and wind turbines.

Correct Answer: Fluid Dynamics

Explanation: Fluid Dynamics plays a crucial role in understanding the behavior of fluids (liquids and gases) and designing hydraulic systems used in engineering applications, such as pipelines, pumps, and aircraft aerodynamics.

Correct Answer: By using techniques such as X-ray diffraction and electron microscopy to analyze material properties

Explanation: Physics contributes to material characterization and analysis by using techniques such as X-ray diffraction, electron microscopy, and spectroscopy to analyze material properties at the atomic and molecular levels.

Correct Answer: Quantum Mechanics

Explanation: Quantum Mechanics is essential for understanding the behavior of semiconductors and developing electronic devices such as transistors, integrated circuits, and microprocessors, which form the basis of modern electronics.

Correct Answer: By applying principles of thermodynamics and atmospheric physics to study climate change

Explanation: Physics contributes to climate science and environmental monitoring by applying principles of thermodynamics, atmospheric physics, and energy transfer to study climate change, weather patterns, and environmental processes.

Correct Answer: Particle Physics

Explanation: Particle Physics is crucial for understanding the behavior of particles in accelerators (such as the Large Hadron Collider) and studying fundamental particles like quarks, leptons, and bosons, which are the building blocks of matter.

Correct Answer: By applying principles of mechanics and materials science to design lightweight and durable aerospace materials

Explanation: Physics contributes to aerospace materials and structures by applying principles of mechanics, materials science, and aerodynamics to design lightweight and durable materials for aircraft and spacecraft.

Correct Answer: Electromagnetism

Explanation: Electromagnetism is essential for understanding the behavior of waves (such as radio waves, microwaves, and light waves) and designing communication systems, antennas, and satellite technologies.

Correct Answer: It encompasses the study of matter, energy, space, and time

Explanation: The scope of physics encompasses the study of matter, energy, space, and time, ranging from the smallest particles to the largest galaxies in the universe.

Correct Answer: Because it seeks to understand the fundamental laws of nature and solve mysteries of the universe

Explanation: Physics is considered an exciting field of study because it seeks to understand the fundamental laws of nature, uncover the mysteries of the universe, and apply this knowledge to technological advancements and everyday life.

Correct Answer: Its contributions to technological innovations and scientific discoveries

Explanation: Physics remains relevant in modern society due to its contributions to technological innovations (such as electronics, telecommunications, and medical imaging) and scientific discoveries that impact various fields.

Correct Answer: By encouraging critical thinking and problem-solving skills

Explanation: Physics inspires curiosity and creativity by encouraging individuals to think critically, solve complex problems, and explore new ideas to understand the natural world and develop innovative technologies.

Correct Answer: By providing solutions to energy, climate, and environmental challenges

Explanation: Physics plays a crucial role in addressing global challenges by providing solutions to energy production, climate change mitigation, and environmental sustainability through scientific research and technological advancements.

Correct Answer: Because it seeks to uncover the fundamental laws governing the universe

Explanation: Physics is considered a fundamental science because it seeks to uncover and understand the fundamental laws governing the universe, from the microscopic to the cosmic scales.

Correct Answer: By collaborating with other scientific disciplines such as biology, chemistry, and engineering

Explanation: Physics contributes to interdisciplinary research by collaborating with other scientific disciplines such as biology, chemistry, and engineering to solve complex problems and develop innovative technologies.

Correct Answer: Classical Mechanics

Explanation: Classical Mechanics is crucial for understanding the behavior of natural phenomena (such as motion, forces, and energy) and predicting their outcomes using mathematical models and principles of mechanics.

Correct Answer: By applying principles of mechanics, electromagnetism, and astrophysics to design spacecraft and explore the universe

Explanation: Physics contributes to the advancement of space exploration by applying principles of mechanics, electromagnetism, and astrophysics to design spacecraft, navigate through space, and study celestial objects and phenomena.

Correct Answer: By understanding the properties of materials at the atomic and subatomic levels

Explanation: Physics plays a role in the development of new materials and technologies by understanding the properties of materials at the atomic and subatomic levels, which enables the creation of advanced materials with specific properties and applications.

Correct Answer: Subatomic particles and interactions at atomic and subatomic scales

Explanation: Physics studies the microscopic domain by examining subatomic particles (such as electrons, protons, and neutrons) and their interactions at atomic and subatomic scales. This exploration helps in understanding the fundamental building blocks of matter and the forces that govern their behavior.

Correct Answer: Brownian motion of particles in a fluid

Explanation: Brownian motion, where particles in a fluid exhibit random motion due to collisions with surrounding molecules, is an example of a macroscopic phenomenon studied in physics. It helps in understanding diffusion processes and is crucial in fields like chemistry, biology, and environmental science.

Correct Answer: By applying principles of quantum mechanics and statistical physics to describe systems at different scales

Explanation: Physics bridges the gap between the microscopic and macroscopic worlds by applying principles of quantum mechanics (for microscopic particles) and statistical physics (for large ensembles of particles) to describe systems across different scales. This approach helps in understanding phenomena from atomic structures to celestial bodies.

Correct Answer: Understanding atoms and molecules provides insights into the properties of materials and chemical reactions

Explanation: Understanding the behavior of atoms and molecules benefits both microscopic and macroscopic studies by providing insights into the properties of materials (such as strength, conductivity, and reactivity) and chemical reactions (such as combustion, oxidation, and synthesis), which are essential in various scientific and technological applications.

Correct Answer: MRI (Magnetic Resonance Imaging) technology

Explanation: MRI technology is a macroscopic application of principles from quantum mechanics, specifically nuclear magnetic resonance. It uses quantum mechanical principles to create detailed images of internal body structures by detecting signals from hydrogen atoms in tissues. MRI is essential in medical diagnostics and research.

Correct Answer: By applying principles of classical mechanics and gravitational interactions

Explanation: Studying macroscopic phenomena like planetary motion relates to microscopic physics principles by applying principles of classical mechanics (such as Newton’s laws of motion) and gravitational interactions (such as Newton’s law of universal gravitation) to describe and predict the motion of celestial bodies in the universe.

Correct Answer: Understanding heat transfer mechanisms

Explanation: Understanding macroscopic thermodynamic principles, such as heat transfer mechanisms (conduction, convection, and radiation), benefits microscopic studies by providing insights into how thermal energy affects the behavior of particles at atomic and molecular scales. This understanding is crucial in fields like materials science, engineering, and environmental studies.

Correct Answer: By describing electron behavior in semiconductors and enabling device functionality

Explanation: Quantum mechanics influences the behavior of electrons in electronic devices by describing their wave-like properties and behavior in semiconductors, which are essential for the functionality of devices like transistors, diodes, and integrated circuits. This understanding forms the basis of modern electronics.

Correct Answer: Scaling laws describe relationships between physical quantities at different scales

Explanation: Scaling laws are significant in connecting microscopic and macroscopic phenomena because they describe relationships between physical quantities (such as size, energy, or velocity) at different scales, allowing physicists to understand how properties and behaviors change as systems vary in size or complexity.

Correct Answer: By describing the behavior of fluids at both atomic and large-scale levels

Explanation: Understanding fluid dynamics benefits both microscopic and macroscopic studies by describing the behavior of fluids (liquids and gases) at both atomic and large-scale levels. This understanding is crucial in fields like engineering, meteorology, biology, and environmental science.

Correct Answer: Investigating the fundamental particles and forces of nature at extremely high energies

Explanation: High-energy physics focuses on investigating the fundamental particles and forces of nature at extremely high energies, often using particle accelerators and detectors to study particle collisions and interactions.

Correct Answer: ATLAS and CMS experiments at the Large Hadron Collider (LHC)

Explanation: The ATLAS and CMS experiments at the Large Hadron Collider (LHC) confirmed the existence of the Higgs boson in 2012, a discovery that contributed to our understanding of particle physics and the mechanism of mass generation.

Correct Answer: Properties and behavior of celestial objects and phenomena

Explanation: Astrophysics studies the properties and behavior of celestial objects and phenomena such as stars, galaxies, black holes, and cosmic radiation, using principles of physics to understand the universe’s structure and evolution.

Correct Answer: Because it constitutes a significant portion of the universe’s mass and affects its structure

Explanation: Dark matter is an important research topic in astrophysics because it constitutes a significant portion of the universe’s mass (about 27%) and influences the formation and evolution of galaxies and large-scale structures through its gravitational effects.

Correct Answer: Understanding the origin, evolution, and eventual fate of the universe

Explanation: Cosmology aims to understand the origin, evolution, and eventual fate of the universe as a whole, studying its large-scale structure, expansion, cosmic microwave background radiation, and theoretical models like the Big Bang theory.

Correct Answer: By analyzing cosmic microwave background radiation and using theoretical models

Explanation: Physicists study the early universe by analyzing cosmic microwave background radiation, the oldest light in the universe, and using theoretical models (such as inflationary theory) to understand its initial conditions and early evolution.

Correct Answer: By accelerating particles to high speeds and energies to study their fundamental properties

Explanation: Particle accelerators play a crucial role in high-energy physics research by accelerating particles to high speeds and energies, allowing physicists to study their fundamental properties and interactions in controlled conditions similar to those found in the early universe.

Correct Answer: Gravitational waves provide insights into celestial objects and phenomena not accessible through electromagnetic observations

Explanation: Gravitational wave detection is significant in astrophysics because it provides new insights into celestial objects and phenomena (such as black hole mergers and neutron star collisions) that are not directly observable through traditional electromagnetic observations, opening a new window to explore the universe.

Correct Answer: Developing mathematical models and theories to explain physical phenomena

Explanation: Theoretical physics focuses on developing mathematical models and theories to explain and predict physical phenomena across various scales, from the microscopic world of quantum mechanics to the large-scale universe studied in cosmology and astrophysics.

Correct Answer: Understanding the properties of dark matter

Explanation: One current challenge in high-energy physics research is understanding the properties of dark matter, a mysterious substance that constitutes a significant portion of the universe’s mass but interacts weakly with electromagnetic radiation, posing challenges for its detection and study.

Correct Answer: Studying the properties and behavior of atomic nuclei

Explanation: Nuclear physics focuses on studying the properties and behavior of atomic nuclei, including nuclear reactions, nuclear structure, and the properties of nuclear matter, which are essential in understanding processes like nuclear fusion and fission.

Correct Answer: Because they interact weakly with matter and provide insights into astrophysical processes

Explanation: Neutrinos are significant in astrophysics and particle physics because they interact weakly with matter, allowing them to escape dense astrophysical environments and providing insights into processes like supernovae explosions, solar fusion, and cosmic ray interactions.

Correct Answer: By observing how gravity bends light from distant objects, revealing details about their structure and distribution

Explanation: Astronomers use gravitational lensing to study distant galaxies by observing how gravity from massive objects (like galaxies or clusters of galaxies) bends light from even more distant objects, providing insights into their structure, mass distribution, and the nature of dark matter.

Correct Answer: Mapping the large-scale structure of the universe and measuring its expansion

Explanation: Observational cosmology aims to map the large-scale structure of the universe, including galaxies, galaxy clusters, and cosmic voids, and to measure the universe’s expansion rate over cosmic time using observations from telescopes and surveys.

Correct Answer: By performing complex calculations to simulate processes like galaxy formation, stellar evolution, and black hole dynamics

Explanation: Supercomputers play a crucial role in astrophysics by performing complex calculations to simulate astrophysical phenomena such as galaxy formation, stellar evolution, and black hole dynamics. These simulations help astronomers understand complex processes that occur over vast distances and timescales in the universe.

Correct Answer: Determining the origin and properties of dark energy, which accelerates the expansion of the universe

Explanation: A current challenge in astrophysics is understanding the nature of dark energy, a mysterious form of energy that accelerates the expansion of the universe. Researchers are investigating its origin and properties through observations of supernovae, galaxy clusters, and the cosmic microwave background.

Correct Answer: By combining observations from different cosmic messengers (such as light, gravitational waves, and neutrinos) to gain a more comprehensive understanding of astrophysical events

Explanation: Multi-messenger astronomy is significant in modern astrophysics because it combines observations from different cosmic messengers—such as electromagnetic radiation (light), gravitational waves, and neutrinos—to gain a more comprehensive understanding of astrophysical events like supernovae, neutron star mergers, and black hole collisions.

Correct Answer: By recreating conditions similar to those just after the Big Bang in particle accelerators

Explanation: High-energy physics contributes to our understanding of the early universe by recreating conditions similar to those just after the Big Bang in particle accelerators like the Large Hadron Collider (LHC), allowing physicists to study fundamental particles and forces that were present during the universe’s infancy.

Correct Answer: Gravitational waves are ripples in spacetime caused by accelerating masses, providing new insights into cosmic phenomena like black hole mergers and neutron star collisions

Explanation: Gravitational waves are ripples in spacetime caused by accelerating masses, predicted by Einstein’s theory of general relativity. Their detection provides new insights into cosmic phenomena such as black hole mergers, neutron star collisions, and the nature of gravity itself, advancing our understanding of astrophysical processes.

Correct Answer: By studying the oldest light in the universe, which provides crucial information about the universe’s early history, composition, and evolution

Explanation: Studying cosmic microwave background radiation is significant in cosmology because it represents the oldest light in the universe, providing crucial information about the universe’s early history, including its composition, initial conditions, and the formation of structures like galaxies and clusters.

Correct Answer: Applying principles of physics to understand biological systems and processes

Explanation: Biophysics applies principles of physics to understand biological systems and processes, including the study of biomolecules, cellular mechanics, neural networks, and biological membranes using techniques such as microscopy and spectroscopy.

Correct Answer: By applying principles of physics to study the physical and chemical properties of molecules and their interactions

Explanation: Chemical physics is important in understanding chemical reactions by applying principles of physics to study the physical and chemical properties of molecules, their structure, dynamics, and interactions, contributing to fields like materials science, catalysis, and atmospheric chemistry.

Correct Answer: Applying principles of physics to study Earth’s structure, processes, and phenomena

Explanation: Geophysics applies principles of physics to study Earth’s structure, processes, and phenomena such as seismic waves, magnetic fields, gravity, and plate tectonics, contributing to our understanding of earthquakes, volcanoes, and Earth’s interior dynamics.

Correct Answer: By applying principles of physics to study climate systems, atmospheric dynamics, and global warming

Explanation: Physics plays a crucial role in climate science by applying principles such as thermodynamics, fluid dynamics, and radiation physics to study climate systems, atmospheric dynamics, and phenomena like global warming and climate change impacts.

Correct Answer: By using principles of physics to develop and improve techniques such as MRI, CT scans, and ultrasound for diagnosing and treating medical conditions

Explanation: Applying physics to medical imaging technologies is significant because it uses principles such as electromagnetism, acoustics, and radiation physics to develop and improve techniques like MRI (Magnetic Resonance Imaging), CT scans (Computed Tomography), and ultrasound, enabling precise diagnosis and treatment of medical conditions.

Correct Answer: By applying principles of physics to study interactions between Earth’s atmosphere, oceans, and land, and their impact on climate and ecosystems

Explanation: Environmental physics focuses on applying principles of physics to study interactions between Earth’s atmosphere, oceans, and land, understanding processes such as climate dynamics, air pollution, water quality, and the impact of human activities on the environment.

Correct Answer: By applying principles of physics to study the behavior and properties of ionized gases (plasmas), essential for developing fusion energy technologies

Explanation: Plasma physics is important in fusion energy research by applying principles of physics to study the behavior and properties of ionized gases (plasmas), which are crucial for achieving and controlling nuclear fusion reactions that hold promise for clean and abundant energy production.

Correct Answer: By applying principles of physics to study the properties, structure, and behavior of materials, influencing fields like nanotechnology, semiconductors, and biomaterials

Explanation: Physics is applied in material science to study the properties, structure, and behavior of materials at atomic and molecular levels, influencing fields such as nanotechnology, semiconductors for electronics, biomaterials for medical applications, and advanced materials for energy technologies.

Correct Answer: By applying principles of physics to study fluid mechanics, including fluid flow, turbulence, and aerodynamics, critical for designing aircraft, vehicles, and renewable energy systems

Explanation: Physics contributes to understanding fluid behavior in engineering applications by applying principles of fluid mechanics, including the study of fluid flow, turbulence, and aerodynamics, which are essential for designing efficient aircraft, vehicles, turbines, and renewable energy systems.

Correct Answer: By applying principles of physics to study solar, wind, and hydroelectric energy systems, optimizing efficiency and sustainability

Explanation: Physics plays a crucial role in developing renewable energy technologies by applying principles such as solar radiation, wind dynamics, and hydrodynamics to study and optimize systems like solar panels, wind turbines, and hydroelectric dams for efficient and sustainable energy production.

Correct Answer: By understanding how forces and motions affect biological processes such as protein folding, DNA replication, and cellular mechanics

Explanation: Applying physics principles to study the mechanics of biological molecules is significant because it helps understand how forces and motions affect essential biological processes like protein folding, DNA replication, and cellular mechanics, aiding in biomedical research and drug development.

Correct Answer: By applying principles of physics to study brain functions, neural networks, and the transmission of signals in the nervous system

Explanation: Physics is applied in neuroscience to study brain functions, neural networks, and the transmission of signals in the nervous system using techniques such as imaging, electrophysiology, and computational modeling, advancing our understanding of cognition, behavior, and neurological disorders.

Correct Answer: By using mathematical models and simulations based on physics principles to study biological processes and systems

Explanation: Computational physics is important in understanding complex biological systems by using mathematical models and simulations based on physics principles to study processes such as molecular dynamics, cellular interactions, and biological networks, providing insights into disease mechanisms and treatment strategies.

Correct Answer: By applying principles of physics to study the mechanical, electrical, and optical properties of biomaterials for medical and technological applications

Explanation: Physics plays a role in understanding the physical properties of biomaterials by applying principles to study mechanical strength, electrical conductivity, optical transparency, and other properties essential for developing biomedical devices, implants, and tissue engineering scaffolds.

Correct Answer: By using principles of physics to analyze reaction kinetics, energy transfer mechanisms, and molecular interactions in chemical systems

Explanation: Applying physics to study the dynamics of chemical reactions is significant because it uses principles such as quantum mechanics, thermodynamics, and statistical mechanics to analyze reaction kinetics, energy transfer mechanisms, and molecular interactions, crucial for designing efficient catalysts and understanding reaction mechanisms.

Correct Answer: By applying principles of physics to study the composition, reactions, and dynamics of Earth’s atmosphere, including air pollution, climate change, and ozone depletion

Explanation: Physics is applied in atmospheric chemistry to study the composition, reactions, and dynamics of Earth’s atmosphere, including processes like air pollution, climate change, ozone depletion, and the interactions between atmospheric constituents and solar radiation.

Correct Answer: By applying principles of physics to study the structure, properties, and behavior of polymers for applications in plastics, textiles, and biomaterials

Explanation: Physics plays a role in understanding the behavior of polymers by applying principles to study their molecular structure, mechanical properties, and behavior under different conditions, influencing applications such as plastics, textiles, and biomaterials.

Correct Answer: By applying principles of physics to study energy flows, population dynamics, and interactions between species in ecological systems

Explanation: Physics is important in studying the dynamics of ecosystems and biodiversity by applying principles to analyze energy flows, population dynamics, nutrient cycling, and interactions between species, contributing to ecological conservation and management strategies.

Correct Answer: By applying principles of physics to design and optimize sensors for measuring pollutants, climate parameters, and ecosystem variables

Explanation: Physics plays a key role in developing sensors for environmental monitoring by applying principles to design and optimize sensors that measure pollutants, climate parameters (such as temperature and humidity), and variables in ecosystems, providing critical data for environmental assessment and management.

Correct Answer: By using principles of physics to study blood flow, respiratory mechanics, and fluid dynamics in biological tissues and organs

Explanation: Applying physics in understanding the behavior of fluids in biological systems involves using principles to study phenomena like blood flow, respiratory mechanics, and fluid dynamics in tissues and organs, aiding in medical diagnostics, drug delivery, and biomedical engineering.

Correct Answer: Observation of neutron star merger (GW170817)

Explanation: The observation of neutron star merger (GW170817) in 2017 confirmed the existence of gravitational waves, predicted by Einstein’s general theory of relativity. This event marked a significant breakthrough in astrophysics and gravitational wave astronomy.

Correct Answer: Higgs boson

Explanation: The discovery of the Higgs boson in 2012 at CERN’s Large Hadron Collider confirmed the existence of the Higgs field, explaining how particles acquire mass. This discovery validated the Standard Model of particle physics.

Correct Answer: Developing algorithms and hardware to perform computations based on quantum mechanics principles

Explanation: Research in quantum computing focuses on developing algorithms and hardware that leverage quantum mechanics principles such as superposition and entanglement to perform computations faster and more efficiently than classical computers.

Correct Answer: Discovery of exoplanets

Explanation: A recent advancement in astrophysics includes the discovery of exoplanets, planets orbiting stars outside our solar system. This discovery has expanded our understanding of planetary systems and the conditions necessary for life.

Correct Answer: Observation of supernovae

Explanation: The observation of distant supernovae, particularly Type Ia supernovae, provided evidence for the accelerating expansion of the universe, suggesting the presence of dark energy driving this expansion.

Correct Answer: Discovery of neutrino oscillations and neutrino mass

Explanation: A key development in particle physics is the discovery of neutrino oscillations and the determination that neutrinos have mass. This discovery challenged previous assumptions and expanded our understanding of fundamental particles.

Correct Answer: Discovery of graphene

Explanation: The discovery of graphene, a single layer of carbon atoms arranged in a hexagonal lattice, represents a significant breakthrough in materials science. Graphene’s unique properties, including high strength, conductivity, and flexibility, have potential applications in electronics, energy storage, and nanotechnology.

Correct Answer: Detection of gravitational lensing by dark matter

Explanation: A recent development in cosmology is the detection of gravitational lensing caused by dark matter. Observations of how dark matter bends light from distant objects provide indirect evidence of its existence and distribution in the universe.

Correct Answer: Development of quantum electrodynamics (QED)

Explanation: A significant advancement in quantum field theory is the development of quantum electrodynamics (QED), which describes the interactions of charged particles and electromagnetic fields. QED is a cornerstone of modern theoretical physics.

Correct Answer: Observation of black hole mergers (LIGO/Virgo collaborations)

Explanation: A key discovery in gravitational astronomy is the observation of black hole mergers by LIGO and Virgo collaborations, using gravitational wave detectors. These observations provide insights into black hole physics and the nature of extreme gravitational events.