premise stringlengths 1 46.3k | hypothesis stringlengths 21 234 | label stringclasses 2 values |
|---|---|---|
In visible light the fields change direction about 1.000.000.000.000.000 times per second, and the exact frequency determines the color of the light. | Exact wavelength determines the color of visible light. | entails |
It detects infrared wavelengths that are beyond the red light in the rainbow of visible colors. | Exact wavelength determines the color of visible light. | neutral |
Natural or white light is composed of a combination of all visible wavelengths (colors) and some non-visible. | Exact wavelength determines the color of visible light. | neutral |
So most wavelengths of light cancel out and the colors associated with those wavelengths aren't visible. | Exact wavelength determines the color of visible light. | neutral |
The focal length for light at other visible wavelengths will be similar but not exactly equal to this. | Exact wavelength determines the color of visible light. | neutral |
The method also permits determination of the wavelength or the color of incident light. | Exact wavelength determines the color of visible light. | neutral |
Wavelength, color, and visibility. | Exact wavelength determines the color of visible light. | neutral |
approximate wavelength of visible light; | Exact wavelength determines the color of visible light. | neutral |
their wavelength is longer than visible light. | Exact wavelength determines the color of visible light. | neutral |
wavelengths shorter than visible light. | Exact wavelength determines the color of visible light. | neutral |
A gas propellent gives these pistols greater velocity and distance. | Distance over time in a given direction determines velocity. | neutral |
Define speed, velocity, distance, and time. | Distance over time in a given direction determines velocity. | neutral |
Direction is determined by velocity and intent. | Distance over time in a given direction determines velocity. | neutral |
In order to measure the velocity images were taken of two bubbles rising in the pipe until coalescence and the velocity as a function of the separation distance was determined directly from the film. | Distance over time in a given direction determines velocity. | neutral |
Observers were required (i) to determine the direction of motion and (ii) to estimate and compare the velocities and distances travelled from distinct elements. | Distance over time in a given direction determines velocity. | neutral |
Sound velocity measured on parallel and perpendicular planes (of a known distance) permits determination of wind speed in the horizontal direction. | Distance over time in a given direction determines velocity. | neutral |
The time interval (round trip) is then converted, using a two-way velocity-of-light factor, to give the distance to the target. | Distance over time in a given direction determines velocity. | neutral |
This frequency when multiplied by the distance between the beams at that altitude gives the wind velocity in the direction along the plane of the five beams. | Distance over time in a given direction determines velocity. | neutral |
This give the direction of the velocity, since the time interval or increment is a scalar. | Distance over time in a given direction determines velocity. | neutral |
This speed is called the radial Doppler velocity because it gives only the radial variation of distance versus time between the radar and the target. | Distance over time in a given direction determines velocity. | neutral |
Velocity is distance divided with time. | Distance over time in a given direction determines velocity. | entails |
distance, velocity, and time; | Distance over time in a given direction determines velocity. | neutral |
A maar is a low relief volcanic crater produced by the interaction of rising magma and ground water and the product is shallow explosive eruptions. | The thickness of magma determines whether a volcanic eruption will be explosive or not. | neutral |
Although rising from much greater depths than other magmas, these pipes and volcanic cones are relatively small and rare, but they erupt in extraordinary supersonic explosions. | The thickness of magma determines whether a volcanic eruption will be explosive or not. | neutral |
During this time more explosive magmas were erupted showering the eastern ring plain with successive thick pumice layers. | The thickness of magma determines whether a volcanic eruption will be explosive or not. | neutral |
He is also very interested in how the violent escape of volatile compounds from magmas drives explosive volcanic eruptions. | The thickness of magma determines whether a volcanic eruption will be explosive or not. | neutral |
In explosive volcanic eruptions, sudden release of gases from magma may cause rapid movements of the molten rock. | The thickness of magma determines whether a volcanic eruption will be explosive or not. | neutral |
Occasionally this magma will erupt to the surface through some crevice or volcanic explosion and rudely remind us about exactly where it is that we are living on. | The thickness of magma determines whether a volcanic eruption will be explosive or not. | neutral |
Phreatic Eruption A volcanic steam explosion caused when magma heats subsurface water. | The thickness of magma determines whether a volcanic eruption will be explosive or not. | neutral |
The thickness and thinness of the magma will determine how a volcano will erupt and what kind of a cone will form. | The thickness of magma determines whether a volcanic eruption will be explosive or not. | entails |
Viscous (thick) magma produces volcanoes characterised by explosive eruptions, while non-viscous (runny) magma produce volcanoes characterised by effusive eruptions pouring large amounts of lava onto the surface. | The thickness of magma determines whether a volcanic eruption will be explosive or not. | entails |
Volcanic steam-blasts do not erupt magma directly but, rather, are explosively expanding steam. | The thickness of magma determines whether a volcanic eruption will be explosive or not. | neutral |
Volcanic tremors are associated with volcanic eruptions, when magma penetrates the crust and ruptures it. | The thickness of magma determines whether a volcanic eruption will be explosive or not. | neutral |
When the magma erupts rapidly and explosively into the air, it is fragmented into small particles which solidify into VOLCANIC ASH. | The thickness of magma determines whether a volcanic eruption will be explosive or not. | neutral |
magma movement and volcanic explosions. | The thickness of magma determines whether a volcanic eruption will be explosive or not. | neutral |
volcanic dome (viscous magma, explosive, dangerous), 3. | The thickness of magma determines whether a volcanic eruption will be explosive or not. | neutral |
2) Touch the charged electroscope with the finger and the charge escapes into the body and the electroscope is grounded . | A(n) electroscope is used to study charge. | neutral |
An electroscope is a device that detects electrical charge. | A(n) electroscope is used to study charge. | entails |
An electroscope is a device that will detect very small charges of static electricity. | A(n) electroscope is used to study charge. | entails |
Charge the electroscope with the rubber rod. | A(n) electroscope is used to study charge. | neutral |
Charged object touches the electroscope. | A(n) electroscope is used to study charge. | neutral |
Charging an Electroscope by Contact (conduction) | A(n) electroscope is used to study charge. | neutral |
Charging an Electroscope by Induction | A(n) electroscope is used to study charge. | neutral |
EM-a4b Charged Rods and Aluminum Can A charged rod can be used to pull a pop can by electrostatic induction EM-a4a Electroscope Charged by Induction Charge an electroscope by induction. | A(n) electroscope is used to study charge. | neutral |
Electroscope ends up oppositely charged to the object used to charge it. | A(n) electroscope is used to study charge. | neutral |
Explain why the electroscope has this charge. | A(n) electroscope is used to study charge. | neutral |
Give the electroscope a positive charge, using the acrylic rubbed with silk. | A(n) electroscope is used to study charge. | neutral |
In fact, a negatively charged plastic golf tube can used to charge an electroscope. | A(n) electroscope is used to study charge. | neutral |
Many might quickly suggest that they have used a charged insulator to charge a neutral electroscope (or some other object) by contact. | A(n) electroscope is used to study charge. | neutral |
Suppose that a negatively charged balloon is used to charge an electroscope by induction. | A(n) electroscope is used to study charge. | neutral |
The charged rods can be used with the foil leaf electroscope and projector, as shown above. | A(n) electroscope is used to study charge. | neutral |
The leaves of a positively charged electroscope are separated. | A(n) electroscope is used to study charge. | neutral |
The process of charging an electroscope by induction using a negatively-charged balloon is depicted in the animation below. | A(n) electroscope is used to study charge. | neutral |
This principle is used in making an electroscope, which is a scientific instrument that detects electrical charges. | A(n) electroscope is used to study charge. | entails |
EUS uses a high frequency ultrasound transducer housed on the tip of a flexible endoscope. | Ultrasound, a diagnostic technology, uses high-frequency vibrations transmitted into any tissue in contact with the transducer. | neutral |
For NCU to become a reality, we first need the transducers and electronic systems sensitive enough to transmit and detect ultrasound without using any contact. | Ultrasound, a diagnostic technology, uses high-frequency vibrations transmitted into any tissue in contact with the transducer. | neutral |
Sonora is a 9002 certified refurbisher of high performance ultrasound systems and replacement transducers for the medical diagnostic ultrasound industry. | Ultrasound, a diagnostic technology, uses high-frequency vibrations transmitted into any tissue in contact with the transducer. | neutral |
The optimal ultrasound frequency for any application represesents a tradeoff between a) the need to acquire ultrasound images with a high degree of spatial resolution, dictating use of higher frequencies, and b) the need to obtain adequate "penetration" in the tissue. | Ultrasound, a diagnostic technology, uses high-frequency vibrations transmitted into any tissue in contact with the transducer. | neutral |
Ultrasound imaging is performed using a high frequency linear array transducer. | Ultrasound, a diagnostic technology, uses high-frequency vibrations transmitted into any tissue in contact with the transducer. | entails |
It had long been recognized that in a neutral gas, such as the earth's atmosphere, particles must collide if shocks are to form. | Volcanic gases helpe to form the atmosphere on earth. | neutral |
N is superabundant in the Earth's atmosphere in the form of N 2 gas. | Volcanic gases helpe to form the atmosphere on earth. | neutral |
Snow forms high in the atmosphere with the help of particles, such as dust, volcanic ash or sea salt. | Volcanic gases helpe to form the atmosphere on earth. | neutral |
The Stratospheric Aerosol and Gas Experiment III (SAGE III) is a continuation of the very successful SAGE I and SAGE II instruments for studying aerosols, small particles in the Earth's atmosphere, such as volcanic ash and liquid droplets. | Volcanic gases helpe to form the atmosphere on earth. | neutral |
The evaporation of water from seas, lakes, rivers, ponds, snow and ice fields, vegetation, and the earth itself forms an invisible gas in the atmosphere of the earth. | Volcanic gases helpe to form the atmosphere on earth. | neutral |
The main gas in Earth's atmosphere 7. | Volcanic gases helpe to form the atmosphere on earth. | neutral |
The poison gas burns off in the atmosphere and the Earth is saved. | Volcanic gases helpe to form the atmosphere on earth. | neutral |
This atmosphere was formed by the constant outpouring of gases from the Earth's interior through volcanic eruptions, known as outgassing. | Volcanic gases helpe to form the atmosphere on earth. | entails |
Today, volcanic carbon dioxide is kept in check by natural processes such as chemical weathering of rocks, which removes the gas from the atmosphere in the form of carbonate minerals. | Volcanic gases helpe to form the atmosphere on earth. | neutral |
Unfortunately, carbon in the earth and atmosphere is locked in highly oxidized forms, such as carbonate minerals and carbon dioxide gas. | Volcanic gases helpe to form the atmosphere on earth. | neutral |
Volcanic Gases and Earth's Atmosphere 37. | Volcanic gases helpe to form the atmosphere on earth. | neutral |
Volcanic ash and Earth's atmosphere 42. | Volcanic gases helpe to form the atmosphere on earth. | neutral |
Volcanic gases helped create earth's atmosphere, and continue to affect its composition today. | Volcanic gases helpe to form the atmosphere on earth. | entails |
When burned, coal, oil and natural gas release their carbon dioxide into the atmosphere, helping to raise the earth's average temperature. | Volcanic gases helpe to form the atmosphere on earth. | neutral |
trace gas see atmosphere venus what normal volcanic activity. | Volcanic gases helpe to form the atmosphere on earth. | neutral |
A severe lack of minerals can lead to Heart Disease (lack of magnesium), Osteoporosis (lack of calcium) and many other diseases. | Too little calcium can cause the disease osteoporosis. | entails |
Adequate calcium helps prevent osteoporosis, a disease that causes the bones to become porous and fragile because calcium is withdrawn faster than it is deposited. | Too little calcium can cause the disease osteoporosis. | entails |
Although lack of calcium can cause osteoporosis, taking extra calcium, by itself, does not treat osteoporosis. | Too little calcium can cause the disease osteoporosis. | entails |
Calcium Osteoporosis is a disease that involves the loss of bone mass. | Too little calcium can cause the disease osteoporosis. | neutral |
Great recipes and information about diet, calcium, osteoporosis and coronary heart disease too. | Too little calcium can cause the disease osteoporosis. | neutral |
Not getting enough calcium can predispose you to osteoporosis (brittle bone disease). | Too little calcium can cause the disease osteoporosis. | entails |
Osteoporosis (loss of bone density, brittle bones) has been taught to be caused by too little calcium in the diet. | Too little calcium can cause the disease osteoporosis. | entails |
Osteoporosis can be caused by inadequate calcium, magnesium and vitamin D intake; | Too little calcium can cause the disease osteoporosis. | entails |
Osteoporosis can be due to calcium deficiency. | Too little calcium can cause the disease osteoporosis. | entails |
Osteoporosis is caused by a lack of calcium intake. | Too little calcium can cause the disease osteoporosis. | entails |
Osteoporosis is caused by deficiencies of calcium and estrogen. | Too little calcium can cause the disease osteoporosis. | entails |
Osteoporosis is the disease of weak, porous bones caused by inadequate calcium, family history, inactivity, certain medications, and lifestyle choices. | Too little calcium can cause the disease osteoporosis. | entails |
The lack of calcium for bones can lead to osteoporosis, which is not a for-women-only disease. | Too little calcium can cause the disease osteoporosis. | entails |
Too little calcium can cause osteoporosis . | Too little calcium can cause the disease osteoporosis. | entails |
Too little calcium in a diet can reduce bone growth, which can lead to osteoporosis later in life. | Too little calcium can cause the disease osteoporosis. | entails |
for example, calcium and a reduced risk of osteoporosis, a bone disease; | Too little calcium can cause the disease osteoporosis. | neutral |
A DNA molecule consists of two chains of nucleotides woven around each other to form a double helix (like braids). | The double helix dna shape forms when the two nucleotide chains wrap around the same axis. | entails |
DNA consists of two 1 20 long chains of nucleotides twisted into a double helix and 1 21 joined by hydrogen bonds between the complementary bases 1 22 adenine and thymine or cytosine and guanine. | The double helix dna shape forms when the two nucleotide chains wrap around the same axis. | entails |
DNA is described as a double helix formed of two complementary and antiparallel strands of deoxyribose nucleotides. | The double helix dna shape forms when the two nucleotide chains wrap around the same axis. | entails |
DNA's secondary structure is predominantly determined by base-pairing of the two polynucleotide strands wrapped around each other to form a double helix. | The double helix dna shape forms when the two nucleotide chains wrap around the same axis. | entails |
Other researchers discovered that DNA has a double helix shape, consisting of two polynucleotide chains held together by bonds between complementary bases. | The double helix dna shape forms when the two nucleotide chains wrap around the same axis. | entails |
The DNA is composed of two long molecular strands, wrapped around one another in the familiar shape of a double helix. | The double helix dna shape forms when the two nucleotide chains wrap around the same axis. | entails |
The Watson-Crick model (6) postulates two right-handed helical nucleotide chains coiled around the same axis to form a double helix. | The double helix dna shape forms when the two nucleotide chains wrap around the same axis. | entails |
The chromosome is made up of two very long single strands of a chemical called DNA (deoxyribonucleic acid) that are wrapped around each other to form a double helix. | The double helix dna shape forms when the two nucleotide chains wrap around the same axis. | entails |
The primary structure consists of two long nucleotide chains that are joined by hydrogen bonds and twisted together to form a double helix. | The double helix dna shape forms when the two nucleotide chains wrap around the same axis. | entails |
These nitrogenous bases hydrogen bond between opposing DNA strands to form the rungs of the "twisted ladder" or double helix of DNA or a biological catalyst that is found in the nucleotides. | The double helix dna shape forms when the two nucleotide chains wrap around the same axis. | entails |
Subsets and Splits
No community queries yet
The top public SQL queries from the community will appear here once available.