Examples of gas syringe in the following topics:
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- The volume of oxygen produced can be measured using the gas syringe method.
- The gas collects in the syringe, pushing out against the plunger.
- The volume of gas that has been produced can be read from the markings on the syringe.
- The rate of a reaction that produces a gas can also be measured by calculating the mass loss as the gas forms and escapes from the reaction flask.
- In a reaction that produces a gas, the volume of the gas produced can be measured using the gas syringe method.
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- Pneumothorax, or collapsed lung, is an abnormal collection of air or gas in the pleural space of the lung that interferes with breathing.
- A pneumothorax is an abnormal collection of air or gas in the pleural space that separates the lungs from the chest wall, which may interfere with normal breathing .
- In larger pneumothoraces, or when there are marked signs and/or symptoms, the air may be extracted with a syringe or a chest tube connected to a one-way valve system.
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- A syringe filter with a pore size of 0.22 micrometers, small enough to capture and retain bacterial and fungal cells.
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- The ideal gas law is the equation of state of a hypothetical ideal gas (in which there is no molecule to molecule interaction).
- The ideal gas law is the equation of state of a hypothetical ideal gas (an illustration is offered in ).
- while Charles' law states that volume of a gas is proportional to the absolute temperature T of the gas at constant pressure
- The proportionality factor is the universal gas constant, R, i.e.
- Therefore, we derive a microscopic version of the ideal gas law
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- There is a simple relationship between the diameter of the gas vesicle and pressure at which it will collapse - the wider the gas vesicle the weaker it becomes.
- However, wider gas vesicles are more efficient.
- They provide more buoyancy per unit of protein than narrow gas vesicles.
- This will select for species with narrower, stronger gas vesicles.
- Discuss the role of a gas vesicle in regards to survival
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- The Ideal Gas Equation in the form $PV=nRT$ is an excellent tool for understanding the relationship between the pressure, volume, amount, and temperature of an ideal gas in a defined environment that can be controlled for constant volume.
- We know the Ideal Gas Equation in the form $PV=nRT$.
- The term $\frac{m}{V}$ appears on the right-hand side of the above rearranged Ideal Gas Law.
- This derivation of the Ideal Gas Equation allows us to characterize the relationship between the pressure, density, and temperature of the gas sample independent of the volume the gas occupies; it also allows us to determine the density of a gas sample given its pressure and temperature, or determine the molar mass of a gas sample given its density.
- Atmospheric science offers one plausible real-life application of the density form of the ideal gas equation.
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- We can derive a form of the Ideal Gas Equation, PV=nRT, that incorporates the molar mass of the gas (M, $g*mol^{-1}$ ).
- The molar mass of an ideal gas can be determined using yet another derivation of the Ideal Gas Law: $PV=nRT$.
- We can plug this into the Ideal Gas Equation:
- This derivation of the Ideal Gas Equation is useful in determining the molar mass of an unknown gas.
- What is the molar mass of the gas?
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- For an ideal gas, this means the volume of a gas is proportional to its temperature (historically, this is called Charles' law).
- Therefore, the work done by the gas (W) is:
- Using the ideal gas law PV=NkT (P=const),
- Here n is the amount of particles in a gas represented in moles.
- $c_P = \frac{5}{2} kN_A = \frac{5}{2} R$ for a monatomic gas.
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- Real gases deviate from the ideal gas law due to the finite volume occupied by individual gas particles.
- The ideal gas law is commonly used to model the behavior of gas-phase reactions.
- At high pressures where the volume occupied by gas molecules does not approach zero
- The particles of a real gas do, in fact, occupy a finite, measurable volume.
- The available volume is now represented as $V - nb$, where b is a constant that is specific to each gas.
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- Take the general gas-phase reaction:
- Recall that the ideal gas law is given by:
- In this expression, $\Delta n$ is a measure of the change in number of moles of gas in the reaction.
- For instance, if a reaction produces three moles of gas, and consumes two moles of gas, then $\Delta n=(3-2)=1$.
- Write the equilibrium expression, KP, in terms of the partial pressures of a gas-phase reaction