DefenceLab/scitail · Datasets at Hugging Face

premise stringlengths 1 69.2k	hypothesis stringlengths 21 234	label class label 2 classes
Catabolism -Decomposition reactions- bonds are broken.	Catabolic reactions involve breaking bonds.	1entails
Chemical reactions also involve bond breaking and bond forming.	Catabolic reactions involve breaking bonds.	0neutral
Examples of a ChemViz simulation include plotting the energy of a reaction along a reaction coordinate, visualizing the electron density changes during such a reaction, or visualizing the participating electronic orbitals involved in bond-making and -breaking processes.	Catabolic reactions involve breaking bonds.	0neutral
In addition, quantum mechanics methods are required to accurately describe transition states and chemical reactions involving bond breaking and formation.	Catabolic reactions involve breaking bonds.	0neutral
In biochemistry the process of breaking down large molecules (by splitting their internal bonds) is catabolism.	Catabolic reactions involve breaking bonds.	1entails
Quantum Classical Molecular Dynamics Chemical reactions involving bond formation and breaking are outside the purview of classical molecular dynamics simulations.	Catabolic reactions involve breaking bonds.	0neutral
The carbon-hydrogen bond energy, for example, is less than that of the carbon-deuterium bond energy, so reactions involving the breaking of these bonds will differ in various parameters.	Catabolic reactions involve breaking bonds.	0neutral
The chain scission reaction involves the breaking of one of the oxygen bonds between the glucose units (the building blocks of cellulose).	Catabolic reactions involve breaking bonds.	0neutral
The final step involves a reverse-aldol reaction to break the bond between the alpha and beta carbons.	Catabolic reactions involve breaking bonds.	0neutral
The reaction involves the breaking of two C-Br bonds (one per bromomethane molecule) and of an F-F bond and the making of two C-F bonds and of a Br-Br bond.	Catabolic reactions involve breaking bonds.	0neutral
The total energy for a given reaction may involve the breaking of bonds in the reacting molecules as well as the formation of the new bonds which are present in the product molecules.	Catabolic reactions involve breaking bonds.	0neutral
Therefore during many chemical reactions involving molecules that have Pi bonds and sigma bonds , the Pi bond breaks without disturbing the sigma bond.	Catabolic reactions involve breaking bonds.	0neutral
This can lead to a decrease in the reaction rate if the rate-determining step involves breaking a bond between hydrogen and another atom.	Catabolic reactions involve breaking bonds.	0neutral
This reaction also may not break bonds to the chiral center.	Catabolic reactions involve breaking bonds.	0neutral
A tyrosine kinase puts phosphate on the amino acid tyrosine.	Catecholamines are a class of amine hormones that when synthesised form the amino acid tyrosine.	0neutral
Composed mainly of hormone-producing chromaffin cells, the adrenal medulla is the principal site of the conversion of the amino acid tyrosine into the catecholamines epinephrine, norepinephrine, and dopamine.	Catecholamines are a class of amine hormones that when synthesised form the amino acid tyrosine.	1entails
L- Tyrosine is natural amino acid.	Catecholamines are a class of amine hormones that when synthesised form the amino acid tyrosine.	0neutral
L-Tyrosine A dietary nonessential amino acid, tyrosine is a component of thyroxin, a hormone secreted by the thyroid gland.	Catecholamines are a class of amine hormones that when synthesised form the amino acid tyrosine.	0neutral
Neuropeptide Y (NPY) is a 36 amino acid peptide hormone that begins and ends with tyrosine (Y) residues.	Catecholamines are a class of amine hormones that when synthesised form the amino acid tyrosine.	0neutral
Phenylalanine Tyrosine Tryptophan Proline Next we have 2 amino acids with acidic sidechains, and 2 more with half-acidic and half-aminic sidechains.	Catecholamines are a class of amine hormones that when synthesised form the amino acid tyrosine.	0neutral
Some of the modifications are quite extensive--thyroid hormone, for example, is a modification of the amino acid tyrosine with iodine molecules added.	Catecholamines are a class of amine hormones that when synthesised form the amino acid tyrosine.	0neutral
TYROSINE Tyrosine is a non-essential amino acid that is used by the thyroid gland to produce one of the major hormones, Thyroxin.	Catecholamines are a class of amine hormones that when synthesised form the amino acid tyrosine.	0neutral
The amino acid l-tyrosine is a precursor to the all-important T3 hormone and a precursor to the stimulatory neurotransmitters epinephrine, norepinephrine, and dopamine.	Catecholamines are a class of amine hormones that when synthesised form the amino acid tyrosine.	0neutral
The amino acids phenylalanine or tyrosine, taken in daily doses of 1500 mg, to boost levels of brain hormones and neurotransmitters (refer to Phenylalanine and Tyrosine-Dosing and Precautions protocol).	Catecholamines are a class of amine hormones that when synthesised form the amino acid tyrosine.	0neutral
The synthesis of catecholamines (e.g., dopamine, norepinephrine) in the brain also varies with the availability of the precursor amino acid L-tyrosine.	Catecholamines are a class of amine hormones that when synthesised form the amino acid tyrosine.	0neutral
The thyroid gland combines the amino acid tyrosine and iodine to manufacture the thyroid hormone.	Catecholamines are a class of amine hormones that when synthesised form the amino acid tyrosine.	0neutral
Thyroid hormone is produced using phenalaline and tyrosine which are amino acids.	Catecholamines are a class of amine hormones that when synthesised form the amino acid tyrosine.	0neutral
Two tyrosines separated by a single amino acid, typically valine or another tyrosine, form a short intra-molecular diphenylether crosslink.	Catecholamines are a class of amine hormones that when synthesised form the amino acid tyrosine.	0neutral
Tyr Tyrosine (an amino acid ).	Catecholamines are a class of amine hormones that when synthesised form the amino acid tyrosine.	0neutral
Tyrosine A nonessential amino acid used to manufacture adrenal and thyroid hormones, and converted into the skin pigment melanin.	Catecholamines are a class of amine hormones that when synthesised form the amino acid tyrosine.	0neutral
Tyrosine Crystals Tyrosine, an amino acid, may be the problem.	Catecholamines are a class of amine hormones that when synthesised form the amino acid tyrosine.	0neutral
synthesizing carnitine, tyrosine, adrenal hormones, and vasoactive amines;	Catecholamines are a class of amine hormones that when synthesised form the amino acid tyrosine.	0neutral
At the time of cell division a structure known as the phragmoplast appears across the center of the cell.	Cells in green algae divide along cell plates called phragmoplasts.	1entails
Be able to define cytokinesis, and describe the process as it occurs in plant cells, including the role of the phragmoplast and cell plate.	Cells in green algae divide along cell plates called phragmoplasts.	0neutral
Unlike other charophytes, cell division in the Klebsormidiales occurs through formation of a cleavage furrow, but apparently neither a phragmoplast nor a cell plate is formed.	Cells in green algae divide along cell plates called phragmoplasts.	0neutral
At the micro level, however, inertia is much more feeble at performing these tasks because the mass of micromachines and microcomponents is very small relative to the forces acting on it;	Centrifuges use inertia to perform their task.	0neutral
Both results are achieved through precise use of leverage, inertia, gravity, and the action of centrifugal and centripetal forces.	Centrifuges use inertia to perform their task.	0neutral
By using eggs, boomerangs, bubbles, a bucket of water, beach balls, leaf blowers, whips, and a stack of glassware, they'll demonstrate flight, aerodynamics, friction, the sound barrier, inertia, centrifugal force, and more.	Centrifuges use inertia to perform their task.	0neutral
CONCLUSIONS We observe consistently improved pointing performance with an isometric joystick using a negative inertia transfer function.	Centrifuges use inertia to perform their task.	0neutral
Centrifuges don't increase gravity, the centrifugal force caused by inertia is what causes the effect of 9 g's.	Centrifuges use inertia to perform their task.	1entails
Conventional computers may remain common because of technological inertia and because they can continue to perform simpler tasks.	Centrifuges use inertia to perform their task.	0neutral
Each section also includes links to suggested classroom activities, most performed using a Slinky, that demonstrate concepts such as inertia, gravity, potential energy, kinetic energy, longitudinal waves, and centrifugal force.	Centrifuges use inertia to perform their task.	0neutral
Electrical inertia simulation, or a combination of electrical and mechanical simulation may be used in lieu of mechanical flywheels, provided that the performance of the electrically simulated inertia complies with the following specifications.	Centrifuges use inertia to perform their task.	0neutral
Look at the mechanics of movement with a little help from author David Macaulay and use both our minds and bodies to learn about incline planes, levers, fulcrum, inertia, centrifugal force, pulleys and friction.	Centrifuges use inertia to perform their task.	0neutral
Performance can compare with conventional actuator systems using expensive low-inertia motors at much lower system cost.	Centrifuges use inertia to perform their task.	0neutral
Performance will be satisfactory if the student can use integral calculus to derive moments of inertia for simple macroscopic objects.	Centrifuges use inertia to perform their task.	0neutral
Stories about shuttle launches, space station dockings and space probe expeditions are filled with data that can be used to illustrate concepts such as inertia, speed, acceleration and centrifugal force.	Centrifuges use inertia to perform their task.	0neutral
The moment of inertia tests were performed in all three primary axes using torsional spring method.	Centrifuges use inertia to perform their task.	0neutral
They do this because they can't overcome the inertia to change their organization to use it, or the tool doesn't adequately perform the required functions.	Centrifuges use inertia to perform their task.	0neutral
Using Moment of Inertia	Centrifuges use inertia to perform their task.	0neutral
inertia balance by using a stroboscope.	Centrifuges use inertia to perform their task.	0neutral
A small protozoan named Trichonympha companula lives in the termite s digestive system and does the job of breaking down the cellulose the termite eats.	Certain anaerobic parabasalid species exist in the digestive tracts of termites and wood-eating cockroaches, where they contribute an essential step in the digestion of cellulose.	1entails
An example of a symbiotic member of this Division is the protozoans which live in the gut of termites and digest cellulose in the wood the termites eat.	Certain anaerobic parabasalid species exist in the digestive tracts of termites and wood-eating cockroaches, where they contribute an essential step in the digestion of cellulose.	1entails
Another example is the relation- ship between termites and certain protists that inhabit their digestive tracts and are responsible for the break- down of cellulose into compounds that can be assimilated by their insect hosts.	Certain anaerobic parabasalid species exist in the digestive tracts of termites and wood-eating cockroaches, where they contribute an essential step in the digestion of cellulose.	1entails
Termites are able to digest wood cellulose because of flagellate protozoans in their gut which in turn contain cellulase-producing bacteria.	Certain anaerobic parabasalid species exist in the digestive tracts of termites and wood-eating cockroaches, where they contribute an essential step in the digestion of cellulose.	1entails
Though termites consume wood, they are unable to digest it but instead possess one-celled protozoa in their gut that breaks down the wood cellulose into a form that the termite can then consume.	Certain anaerobic parabasalid species exist in the digestive tracts of termites and wood-eating cockroaches, where they contribute an essential step in the digestion of cellulose.	1entails
A linkage is a relationship between genes that tends to cause the characteristics of these genes to be inherited together.	Certain characteristics are frequently inherited together because of linkage.	1entails
But there is no causal linkage between these physical and behavioral traits, and therefore it is not justifiable to attribute cultural characteristics to genetic inheritance.	Certain characteristics are frequently inherited together because of linkage.	0neutral
In fact, one of the most enduring characteristics of online discussions is the frequent use of citations that the linkage of the Web makes possible.	Certain characteristics are frequently inherited together because of linkage.	0neutral
Linkage The tendency for certain genes to be inherited together due to their physical proximity on the chromosome.	Certain characteristics are frequently inherited together because of linkage.	1entails
Linkage explains why certain characteristics are frequently inherited together.	Certain characteristics are frequently inherited together because of linkage.	1entails
Managed care organizations inherently possess certain characteristics that facilitate linkages with schools.	Certain characteristics are frequently inherited together because of linkage.	0neutral
Specifically genetic markers termed microsatellites are to be analyzed for their linkage to characteristics such as growth and food metabolism for certain fish species.	Certain characteristics are frequently inherited together because of linkage.	0neutral
These pragmas are used for defining special linkage characteristics and to associate these linkage characteristics with functions.	Certain characteristics are frequently inherited together because of linkage.	0neutral
These projects are used again when studying crossing over, gene linkage, segregation and independent assortment of alleles in the gametes and studying certain human inheritance patterns.	Certain characteristics are frequently inherited together because of linkage.	0neutral
linkage analysis of inherited arthropathies;	Certain characteristics are frequently inherited together because of linkage.	0neutral
Impulse Momentum	Change in momentum in an object is equivalent to impulse .	0neutral
Impulse is also described as the change in momentum.	Change in momentum in an object is equivalent to impulse .	1entails
Impulse is change in momentum due to collision.	Change in momentum in an object is equivalent to impulse .	1entails
Impulse is equal to momentum change.	Change in momentum in an object is equivalent to impulse .	1entails
Impulse is the change in momentum.	Change in momentum in an object is equivalent to impulse .	1entails
Since impulse equals a change in momentum and since the two objects have equal and opposite impulses, they must also have equal and opposite changes in momentum.	Change in momentum in an object is equivalent to impulse .	1entails
The change in the momentum is given by the impulse .	Change in momentum in an object is equivalent to impulse .	1entails
The equation is known as the impulse-momentum change equation .	Change in momentum in an object is equivalent to impulse .	0neutral
The impulse experienced by an object is always equal to the change in its momentum.	Change in momentum in an object is equivalent to impulse .	1entails
The impulse is equal to the amount of momentum change.	Change in momentum in an object is equivalent to impulse .	1entails
The momentum of an object is changed by giving it an impulse .	Change in momentum in an object is equivalent to impulse .	1entails
Types of wave-energy-momentum impulses and other quantities-to measure 1.	Change in momentum in an object is equivalent to impulse .	0neutral
that is, the impulse is always equal to the momentum change.	Change in momentum in an object is equivalent to impulse .	1entails
the impulse causes (and is equal to) the change in momentum.	Change in momentum in an object is equivalent to impulse .	1entails
Calculate elastic potential elastic potential energy.	Changing the shape of an elastic material gives it potential energy.	0neutral
Calculate elastic potential energy.	Changing the shape of an elastic material gives it potential energy.	0neutral
Calculate the elastic potential energy.	Changing the shape of an elastic material gives it potential energy.	0neutral
Common types of potential energy are elastic, gravitational, chemical, electrical and nuclear.	Changing the shape of an elastic material gives it potential energy.	0neutral
Definition of Spring Potential Energy (Elastic Potential Energy)	Changing the shape of an elastic material gives it potential energy.	0neutral
Elastic Potential Energy Calculator	Changing the shape of an elastic material gives it potential energy.	0neutral
Elastic Potential Energy is stored energy that comes from deforming an object that will resume its previous shape.	Changing the shape of an elastic material gives it potential energy.	1entails
Elastic energy is sometimes called elastic potential energy because it can be recovered when the object returns to its original shape;	Changing the shape of an elastic material gives it potential energy.	1entails
Elastic energy is the total potential and kinetic energy in a system.	Changing the shape of an elastic material gives it potential energy.	0neutral
Elastic potential energy is the energy stored in elastic materials as the result of their stretching or compressing.	Changing the shape of an elastic material gives it potential energy.	1entails
Introduction to Elastic Potential Energy with Examples	Changing the shape of an elastic material gives it potential energy.	0neutral
Other examples of Elastic Potential Energy are	Changing the shape of an elastic material gives it potential energy.	0neutral
The longer the distance pushed, the greater the Elastic Potential Energy the material has.	Changing the shape of an elastic material gives it potential energy.	0neutral
The potential energy of a body by virtue of it's configuration ( shape) is called it's elastic potential energy.	Changing the shape of an elastic material gives it potential energy.	1entails
Then we are to calculate the elastic potential energy.	Changing the shape of an elastic material gives it potential energy.	0neutral
There are two types of potential energies, gravitational and elastic.	Changing the shape of an elastic material gives it potential energy.	0neutral
e.g., chemical, elastic, gravitational, and nuclear are all types of potential energy.	Changing the shape of an elastic material gives it potential energy.	0neutral
where Ue is the elastic potential energy.	Changing the shape of an elastic material gives it potential energy.	0neutral
A new element in this report is a chapter on biogeochemical cycles.	Chemical elements and water are recycled through the biogeochemical cycle.	0neutral
BioGeoChemical Cycles.	Chemical elements and water are recycled through the biogeochemical cycle.	0neutral

Catabolism -Decomposition reactions- bonds are broken.

Catabolic reactions involve breaking bonds.

1entails

Chemical reactions also involve bond breaking and bond forming.

Catabolic reactions involve breaking bonds.

0neutral

Examples of a ChemViz simulation include plotting the energy of a reaction along a reaction coordinate, visualizing the electron density changes during such a reaction, or visualizing the participating electronic orbitals involved in bond-making and -breaking processes.

Catabolic reactions involve breaking bonds.

0neutral

In addition, quantum mechanics methods are required to accurately describe transition states and chemical reactions involving bond breaking and formation.

Catabolic reactions involve breaking bonds.

0neutral

In biochemistry the process of breaking down large molecules (by splitting their internal bonds) is catabolism.

Catabolic reactions involve breaking bonds.

1entails

Quantum Classical Molecular Dynamics Chemical reactions involving bond formation and breaking are outside the purview of classical molecular dynamics simulations.

Catabolic reactions involve breaking bonds.

0neutral

The carbon-hydrogen bond energy, for example, is less than that of the carbon-deuterium bond energy, so reactions involving the breaking of these bonds will differ in various parameters.

Catabolic reactions involve breaking bonds.

0neutral

The chain scission reaction involves the breaking of one of the oxygen bonds between the glucose units (the building blocks of cellulose).

Catabolic reactions involve breaking bonds.

0neutral

The final step involves a reverse-aldol reaction to break the bond between the alpha and beta carbons.

Catabolic reactions involve breaking bonds.

0neutral

The reaction involves the breaking of two C-Br bonds (one per bromomethane molecule) and of an F-F bond and the making of two C-F bonds and of a Br-Br bond.

Catabolic reactions involve breaking bonds.

0neutral

The total energy for a given reaction may involve the breaking of bonds in the reacting molecules as well as the formation of the new bonds which are present in the product molecules.

Catabolic reactions involve breaking bonds.

0neutral

Therefore during many chemical reactions involving molecules that have Pi bonds and sigma bonds , the Pi bond breaks without disturbing the sigma bond.

Catabolic reactions involve breaking bonds.

0neutral

This can lead to a decrease in the reaction rate if the rate-determining step involves breaking a bond between hydrogen and another atom.

Catabolic reactions involve breaking bonds.

0neutral

This reaction also may not break bonds to the chiral center.

Catabolic reactions involve breaking bonds.

0neutral

A tyrosine kinase puts phosphate on the amino acid tyrosine.

Catecholamines are a class of amine hormones that when synthesised form the amino acid tyrosine.

0neutral

Composed mainly of hormone-producing chromaffin cells, the adrenal medulla is the principal site of the conversion of the amino acid tyrosine into the catecholamines epinephrine, norepinephrine, and dopamine.

Catecholamines are a class of amine hormones that when synthesised form the amino acid tyrosine.

1entails

L- Tyrosine is natural amino acid.

Catecholamines are a class of amine hormones that when synthesised form the amino acid tyrosine.

0neutral

L-Tyrosine A dietary nonessential amino acid, tyrosine is a component of thyroxin, a hormone secreted by the thyroid gland.

Catecholamines are a class of amine hormones that when synthesised form the amino acid tyrosine.

0neutral

Neuropeptide Y (NPY) is a 36 amino acid peptide hormone that begins and ends with tyrosine (Y) residues.

Catecholamines are a class of amine hormones that when synthesised form the amino acid tyrosine.

0neutral

Phenylalanine Tyrosine Tryptophan Proline Next we have 2 amino acids with acidic sidechains, and 2 more with half-acidic and half-aminic sidechains.

Catecholamines are a class of amine hormones that when synthesised form the amino acid tyrosine.

0neutral

Some of the modifications are quite extensive--thyroid hormone, for example, is a modification of the amino acid tyrosine with iodine molecules added.

Catecholamines are a class of amine hormones that when synthesised form the amino acid tyrosine.

0neutral

TYROSINE Tyrosine is a non-essential amino acid that is used by the thyroid gland to produce one of the major hormones, Thyroxin.

Catecholamines are a class of amine hormones that when synthesised form the amino acid tyrosine.

0neutral

The amino acid l-tyrosine is a precursor to the all-important T3 hormone and a precursor to the stimulatory neurotransmitters epinephrine, norepinephrine, and dopamine.

Catecholamines are a class of amine hormones that when synthesised form the amino acid tyrosine.

0neutral

The amino acids phenylalanine or tyrosine, taken in daily doses of 1500 mg, to boost levels of brain hormones and neurotransmitters (refer to Phenylalanine and Tyrosine-Dosing and Precautions protocol).

Catecholamines are a class of amine hormones that when synthesised form the amino acid tyrosine.

0neutral

The synthesis of catecholamines (e.g., dopamine, norepinephrine) in the brain also varies with the availability of the precursor amino acid L-tyrosine.

Catecholamines are a class of amine hormones that when synthesised form the amino acid tyrosine.

0neutral

The thyroid gland combines the amino acid tyrosine and iodine to manufacture the thyroid hormone.

Catecholamines are a class of amine hormones that when synthesised form the amino acid tyrosine.

0neutral

Thyroid hormone is produced using phenalaline and tyrosine which are amino acids.

Catecholamines are a class of amine hormones that when synthesised form the amino acid tyrosine.

0neutral

Two tyrosines separated by a single amino acid, typically valine or another tyrosine, form a short intra-molecular diphenylether crosslink.

Catecholamines are a class of amine hormones that when synthesised form the amino acid tyrosine.

0neutral

Tyr Tyrosine (an amino acid ).

Catecholamines are a class of amine hormones that when synthesised form the amino acid tyrosine.

0neutral

Tyrosine A nonessential amino acid used to manufacture adrenal and thyroid hormones, and converted into the skin pigment melanin.

Catecholamines are a class of amine hormones that when synthesised form the amino acid tyrosine.

0neutral

Tyrosine Crystals Tyrosine, an amino acid, may be the problem.

Catecholamines are a class of amine hormones that when synthesised form the amino acid tyrosine.

0neutral

synthesizing carnitine, tyrosine, adrenal hormones, and vasoactive amines;

Catecholamines are a class of amine hormones that when synthesised form the amino acid tyrosine.

0neutral

At the time of cell division a structure known as the phragmoplast appears across the center of the cell.

Cells in green algae divide along cell plates called phragmoplasts.

1entails

Be able to define cytokinesis, and describe the process as it occurs in plant cells, including the role of the phragmoplast and cell plate.

Cells in green algae divide along cell plates called phragmoplasts.

0neutral

Unlike other charophytes, cell division in the Klebsormidiales occurs through formation of a cleavage furrow, but apparently neither a phragmoplast nor a cell plate is formed.

Cells in green algae divide along cell plates called phragmoplasts.

0neutral

At the micro level, however, inertia is much more feeble at performing these tasks because the mass of micromachines and microcomponents is very small relative to the forces acting on it;

Centrifuges use inertia to perform their task.

0neutral

Both results are achieved through precise use of leverage, inertia, gravity, and the action of centrifugal and centripetal forces.

Centrifuges use inertia to perform their task.

0neutral

By using eggs, boomerangs, bubbles, a bucket of water, beach balls, leaf blowers, whips, and a stack of glassware, they'll demonstrate flight, aerodynamics, friction, the sound barrier, inertia, centrifugal force, and more.

Centrifuges use inertia to perform their task.

0neutral

CONCLUSIONS We observe consistently improved pointing performance with an isometric joystick using a negative inertia transfer function.

Centrifuges use inertia to perform their task.

0neutral

Centrifuges don't increase gravity, the centrifugal force caused by inertia is what causes the effect of 9 g's.

Centrifuges use inertia to perform their task.

1entails

Conventional computers may remain common because of technological inertia and because they can continue to perform simpler tasks.

Centrifuges use inertia to perform their task.

0neutral

Each section also includes links to suggested classroom activities, most performed using a Slinky, that demonstrate concepts such as inertia, gravity, potential energy, kinetic energy, longitudinal waves, and centrifugal force.

Centrifuges use inertia to perform their task.

0neutral

Electrical inertia simulation, or a combination of electrical and mechanical simulation may be used in lieu of mechanical flywheels, provided that the performance of the electrically simulated inertia complies with the following specifications.

Centrifuges use inertia to perform their task.

0neutral

Look at the mechanics of movement with a little help from author David Macaulay and use both our minds and bodies to learn about incline planes, levers, fulcrum, inertia, centrifugal force, pulleys and friction.

Centrifuges use inertia to perform their task.

0neutral

Performance can compare with conventional actuator systems using expensive low-inertia motors at much lower system cost.

Centrifuges use inertia to perform their task.

0neutral

Performance will be satisfactory if the student can use integral calculus to derive moments of inertia for simple macroscopic objects.

Centrifuges use inertia to perform their task.

0neutral

Stories about shuttle launches, space station dockings and space probe expeditions are filled with data that can be used to illustrate concepts such as inertia, speed, acceleration and centrifugal force.

Centrifuges use inertia to perform their task.

0neutral

The moment of inertia tests were performed in all three primary axes using torsional spring method.

Centrifuges use inertia to perform their task.

0neutral

They do this because they can't overcome the inertia to change their organization to use it, or the tool doesn't adequately perform the required functions.

Centrifuges use inertia to perform their task.

0neutral

Using Moment of Inertia

Centrifuges use inertia to perform their task.

0neutral

inertia balance by using a stroboscope.

Centrifuges use inertia to perform their task.

0neutral

A small protozoan named Trichonympha companula lives in the termite s digestive system and does the job of breaking down the cellulose the termite eats.

Certain anaerobic parabasalid species exist in the digestive tracts of termites and wood-eating cockroaches, where they contribute an essential step in the digestion of cellulose.

1entails

An example of a symbiotic member of this Division is the protozoans which live in the gut of termites and digest cellulose in the wood the termites eat.

Certain anaerobic parabasalid species exist in the digestive tracts of termites and wood-eating cockroaches, where they contribute an essential step in the digestion of cellulose.

1entails

Another example is the relation- ship between termites and certain protists that inhabit their digestive tracts and are responsible for the break- down of cellulose into compounds that can be assimilated by their insect hosts.

Certain anaerobic parabasalid species exist in the digestive tracts of termites and wood-eating cockroaches, where they contribute an essential step in the digestion of cellulose.

1entails

Termites are able to digest wood cellulose because of flagellate protozoans in their gut which in turn contain cellulase-producing bacteria.

Certain anaerobic parabasalid species exist in the digestive tracts of termites and wood-eating cockroaches, where they contribute an essential step in the digestion of cellulose.

1entails

Though termites consume wood, they are unable to digest it but instead possess one-celled protozoa in their gut that breaks down the wood cellulose into a form that the termite can then consume.

Certain anaerobic parabasalid species exist in the digestive tracts of termites and wood-eating cockroaches, where they contribute an essential step in the digestion of cellulose.

1entails

A linkage is a relationship between genes that tends to cause the characteristics of these genes to be inherited together.

Certain characteristics are frequently inherited together because of linkage.

1entails

But there is no causal linkage between these physical and behavioral traits, and therefore it is not justifiable to attribute cultural characteristics to genetic inheritance.

Certain characteristics are frequently inherited together because of linkage.

0neutral

In fact, one of the most enduring characteristics of online discussions is the frequent use of citations that the linkage of the Web makes possible.

Certain characteristics are frequently inherited together because of linkage.

0neutral

Linkage The tendency for certain genes to be inherited together due to their physical proximity on the chromosome.

Certain characteristics are frequently inherited together because of linkage.

1entails

Linkage explains why certain characteristics are frequently inherited together.

Certain characteristics are frequently inherited together because of linkage.

1entails

Managed care organizations inherently possess certain characteristics that facilitate linkages with schools.

Certain characteristics are frequently inherited together because of linkage.

0neutral

Specifically genetic markers termed microsatellites are to be analyzed for their linkage to characteristics such as growth and food metabolism for certain fish species.

Certain characteristics are frequently inherited together because of linkage.

0neutral

These pragmas are used for defining special linkage characteristics and to associate these linkage characteristics with functions.

Certain characteristics are frequently inherited together because of linkage.

0neutral

These projects are used again when studying crossing over, gene linkage, segregation and independent assortment of alleles in the gametes and studying certain human inheritance patterns.

Certain characteristics are frequently inherited together because of linkage.

0neutral

linkage analysis of inherited arthropathies;

Certain characteristics are frequently inherited together because of linkage.

0neutral

Impulse Momentum

Change in momentum in an object is equivalent to impulse .

0neutral

Impulse is also described as the change in momentum.

Change in momentum in an object is equivalent to impulse .

1entails

Impulse is change in momentum due to collision.

Change in momentum in an object is equivalent to impulse .

1entails

Impulse is equal to momentum change.

Change in momentum in an object is equivalent to impulse .

1entails

Impulse is the change in momentum.

Change in momentum in an object is equivalent to impulse .

1entails

Since impulse equals a change in momentum and since the two objects have equal and opposite impulses, they must also have equal and opposite changes in momentum.

Change in momentum in an object is equivalent to impulse .

1entails

The change in the momentum is given by the impulse .

Change in momentum in an object is equivalent to impulse .

1entails

The equation is known as the impulse-momentum change equation .

Change in momentum in an object is equivalent to impulse .

0neutral

The impulse experienced by an object is always equal to the change in its momentum.

Change in momentum in an object is equivalent to impulse .

1entails

The impulse is equal to the amount of momentum change.

Change in momentum in an object is equivalent to impulse .

1entails

The momentum of an object is changed by giving it an impulse .

Change in momentum in an object is equivalent to impulse .

1entails

Types of wave-energy-momentum impulses and other quantities-to measure 1.

Change in momentum in an object is equivalent to impulse .

0neutral

that is, the impulse is always equal to the momentum change.

Change in momentum in an object is equivalent to impulse .

1entails

the impulse causes (and is equal to) the change in momentum.

Change in momentum in an object is equivalent to impulse .

1entails

Calculate elastic potential elastic potential energy.