Explain what is meant by an adiabatic change - AQA - A-Level Physics - Question 3 - 2022 - Paper 6

The relationship for adiabatic processes can be described by the equation: P_{1} V_{1}^{eta} = P_{2} V_{2}^{eta} where β is the adiabatic index. Therefore, we can rearrange for V₁/V₂: V_{1}/V_{2} = (P_{2}/P_{1})^{rac{1}{eta}} Substituting the given values:

Diesel engines require a higher compression ratio compared to petrol engines to achieve a sufficient rise in temperature for ignition. In a diesel engine, air is compressed to a point where its temperature becomes high enough for fuel to auto-ignite, which occurs at higher pressure and temperature. In contrast, petrol engines rely on a spark to ignite the air-fuel mixture, allowing for a lower compression ratio. Therefore, higher compression ratios in diesel engines facilitate self-ignition at optimal pressures and temperatures.

The indicator diagram for a real four-stroke diesel engine generally demonstrates lower efficiency and different characteristics compared to the ideal cycle. The diagram would resemble a loop that includes the compression stroke, power stroke, exhaust, and intake phases, along with significant areas representing work done. It is important to note the shapes are rounded rather than sharp due to real engine inefficiencies.

The fuel injection point can be marked with an 'X' on the diagram at the beginning of the power stroke, where the pressure starts to rise significantly after the compression phase. This indicates the moment when the fuel is injected into the cylinder to initiate combustion.

1. Shape of the Curve: The ideal cycle typically shows sharp, distinct corners in the pressure-volume diagram, indicative of instantaneous processes. In contrast, real engine diagrams exhibit rounded curves due to the finite time taken for various processes like combustion and exhaust.

2. Work Output: The ideal cycle assumes constant efficiency and no heat losses, meaning all work done in the cycle is fully converted to useful work. Real engines, however, experience heat losses and inefficiencies (friction, heat rejection, etc.), resulting in lower effective work being produced.