For a given balloon inflated to a volume of 7 .00×10 2 ml at a temperature of 20 .0°C and its volume of gas should be determined when it is cooled at constant pressure to a temperature of 1 .00×10 2 K . Concept introduction: A French physicist Jacques Charles introduced a gaseous law with interpreting the relationship between the temperature and volume of a gas at constant pressure. That is the behavior of gas towards the heat. This law is known as Charles’s law . Charles’s law can be defined as, A gas kept in the particular container at constant pressure. If the container of gas is heated, the gaseous particle is expanded and the volume of container is increased. That is the volume of container is directly proportional to the temperature of gas. As increasing the temperature of a particular gas the volume of gas will expand. This direct relationship between the temperature and volume of gas is termed as Charles’s law. Mathematically this law can be written as, V ∝ T V=bT Where, T is temperature and b is proportionality constant. By comparing two systems at different conditions, V 1 T 1 = V 2 T 2 This direct proportionality of temperature and volume can be can be explained as when temperature of a gas container is increases, the kinetic energy of atomic gaseous molecules is increases and the particles started to move from the initial position and the volume of gas container going to expand.
For a given balloon inflated to a volume of 7 .00×10 2 ml at a temperature of 20 .0°C and its volume of gas should be determined when it is cooled at constant pressure to a temperature of 1 .00×10 2 K . Concept introduction: A French physicist Jacques Charles introduced a gaseous law with interpreting the relationship between the temperature and volume of a gas at constant pressure. That is the behavior of gas towards the heat. This law is known as Charles’s law . Charles’s law can be defined as, A gas kept in the particular container at constant pressure. If the container of gas is heated, the gaseous particle is expanded and the volume of container is increased. That is the volume of container is directly proportional to the temperature of gas. As increasing the temperature of a particular gas the volume of gas will expand. This direct relationship between the temperature and volume of gas is termed as Charles’s law. Mathematically this law can be written as, V ∝ T V=bT Where, T is temperature and b is proportionality constant. By comparing two systems at different conditions, V 1 T 1 = V 2 T 2 This direct proportionality of temperature and volume can be can be explained as when temperature of a gas container is increases, the kinetic energy of atomic gaseous molecules is increases and the particles started to move from the initial position and the volume of gas container going to expand.
Solution Summary: The author explains how Charles's law interprets the relationship between the temperature and volume of a gas at constant pressure.
For a given balloon inflated to a volume of
7.00×102ml at a temperature of
20.0°C and its volume of gas should be determined when it is cooled at constant pressure to a temperature of
1.00×102K.
Concept introduction:
A French physicist Jacques Charles introduced a gaseous law with interpreting the relationship between the temperature and volume of a gas at constant pressure. That is the behavior of gas towards the heat. This law is known as Charles’s law.
Charles’s law can be defined as,
A gas kept in the particular container at constant pressure. If the container of gas is heated, the gaseous particle is expanded and the volume of container is increased. That is the volume of container is directly proportional to the temperature of gas. As increasing the temperature of a particular gas the volume of gas will expand. This direct relationship between the temperature and volume of gas is termed as Charles’s law.
Mathematically this law can be written as,
V∝T
V=bT
Where, T is temperature and b is proportionality constant.
By comparing two systems at different conditions,
V1T1=V2T2
This direct proportionality of temperature and volume can be can be explained as when temperature of a gas container is increases, the kinetic energy of atomic gaseous molecules is increases and the particles started to move from the initial position and the volume of gas container going to expand.
Blocking Group are use to put 2 large sterically repulsive group ortho. Show the correct sequence toconnect the reagent to product with the highest yield possible. * see image **NOTE: The compound on the left is the starting point, and the compound on the right is the final product. Please show the steps in between to get from start to final, please. These are not two different compounds that need to be worked.
I dont understand this.
Can you please explain this prooblem to me, show me how the conjugation is added, did I add them in the correct places and if so please show me. Thanks!
Author:Steven D. Gammon, Ebbing, Darrell Ebbing, Steven D., Darrell; Gammon, Darrell Ebbing; Steven D. Gammon, Darrell D.; Gammon, Ebbing; Steven D. Gammon; Darrell
Author:Steven D. Gammon, Ebbing, Darrell Ebbing, Steven D., Darrell; Gammon, Darrell Ebbing; Steven D. Gammon, Darrell D.; Gammon, Ebbing; Steven D. Gammon; Darrell