Which method of heat transfer does NOT require a medium?

Radiation. Radiation transfers heat through electromagnetic waves and does not require a medium — it can travel through a vacuum. This is how the Sun's heat reaches Earth. Conduction requires direct contact (solid medium), and convection requires a fluid (liquid or gas) medium.

Why must a blood pressure cuff be positioned at heart level for accurate readings?

Fluid pressure is affected by height — above heart level reads low, below reads high. Fluid pressure increases with depth (P = rho x g x h). If the cuff is below heart level, the weight of the blood column adds pressure, giving a falsely high reading. If above heart level, the blood column subtracts pressure, giving a falsely low reading. Positioning at heart level eliminates this hydrostatic effect.

Water has a high specific heat capacity. This means water:

Absorbs and releases large amounts of heat with minimal temperature change. Water's high specific heat (4.184 J/g°C) means it can absorb or release large amounts of thermal energy with only a small change in temperature. This property is why water is excellent for regulating body temperature and why coastal climates are more moderate than inland areas.

Nuclear fission involves:

Splitting a heavy nucleus into lighter nuclei. Nuclear fission is the splitting of a heavy, unstable nucleus into two or more lighter nuclei, releasing a large amount of energy. This process powers nuclear power plants and was used in early atomic weapons. Nuclear fusion is the opposite — combining light nuclei (like hydrogen) into heavier ones, which powers the Sun.

According to the First Law of Thermodynamics:

Energy cannot be created or destroyed, only transformed. The First Law of Thermodynamics (Law of Conservation of Energy) states that energy cannot be created or destroyed — it can only be changed from one form to another. In biological systems, chemical energy in food is converted to kinetic energy, heat, and ATP. The total energy remains constant.

8.3 Fluid Dynamics, Thermodynamics & Nuclear Physics | HESI A2 Admission Assessment | Free Exam Prep

Fluid Dynamics, Thermodynamics & Nuclear Physics

These advanced physics topics have direct clinical applications. Fluid dynamics relates to blood pressure and IV management, thermodynamics to temperature regulation, and nuclear physics to radiation medicine.

Pressure

Pressure is the force applied per unit area:

P = F / A (Pressure = Force / Area)

Unit	Definition	Context
Pascal (Pa)	1 N/m^2	SI unit of pressure
mmHg	Millimeters of mercury	Blood pressure measurement
atm	Atmosphere	Standard atmospheric pressure = 1 atm = 760 mmHg = 101.3 kPa
psi	Pounds per square inch	Tire pressure, industrial

Key concept: The same force spread over a larger area produces less pressure. This is why:

Wide-based walkers are more stable than narrow canes
Snowshoes spread weight over a larger area to prevent sinking
Bed-bound patients develop pressure injuries where body weight concentrates on small areas (heels, sacrum)

Fluid Pressure

Fluid pressure increases with depth:

P = rho x g x h (density x gravity x height)

Clinical Application:

Blood pressure is higher in the feet than in the brain when standing (due to the weight of the blood column)
IV bags are hung above the patient — gravity creates the pressure needed to flow fluid into the vein
Blood pressure cuffs must be at heart level for accurate readings — positioning above heart level gives falsely low readings; below gives falsely high readings

Pascal's Principle

"Pressure applied to a confined fluid is transmitted equally in all directions."

Applications:

Hydraulic lifts (patient hoists)
Blood pressure transmission through the vascular system
Syringes — pushing the plunger applies pressure equally to the fluid

Buoyancy

Archimedes' Principle: An object submerged in fluid experiences an upward buoyant force equal to the weight of the fluid it displaces.

If buoyant force > weight → object floats
If buoyant force < weight → object sinks
Nursing application: Hydrotherapy — patients weigh less in water, making exercises easier on joints

Thermodynamics

Thermodynamics is the study of heat, energy, and work.

Heat Transfer Methods

Method	Description	Medium Required	Example
Conduction	Direct contact between objects	Yes (solid)	Holding an ice pack on skin
Convection	Heat transfer through moving fluid/gas	Yes (fluid/gas)	Warm air rising from a heater; blood circulating body heat
Radiation	Transfer via electromagnetic waves	No	Feeling warmth from the sun; radiant warmers for newborns

Clinical Applications:

Conduction: Ice packs, heating pads, warm blankets (direct contact)
Convection: Forced-air warming blankets (Bair Hugger), blood circulation distributing body heat
Radiation: Radiant warmers for premature infants, infrared heat lamps

Laws of Thermodynamics

Law	Statement	Clinical Relevance
0th Law	If A is in thermal equilibrium with B, and B with C, then A is with C	Thermometers work because they reach equilibrium with the body
1st Law	Energy cannot be created or destroyed, only transformed	Total energy in metabolic processes is conserved
2nd Law	Entropy (disorder) of an isolated system always increases	Living organisms maintain order by consuming energy; death → decomposition
3rd Law	Entropy approaches zero as temperature approaches absolute zero (0 K)	Theoretical limit; not directly applicable in nursing

Temperature Scales

Scale	Freezing Point of Water	Boiling Point of Water	Absolute Zero
Fahrenheit (°F)	32°F	212°F	-459.67°F
Celsius (°C)	0°C	100°C	-273.15°C
Kelvin (K)	273.15 K	373.15 K	0 K

Conversions:

°C to K: K = °C + 273.15
°F to °C: °C = (°F - 32) x 5/9
°C to °F: °F = (°C x 9/5) + 32

Specific Heat Capacity

Specific heat is the amount of energy needed to raise 1 gram of a substance by 1°C:

Q = m x c x deltaT (heat = mass x specific heat x temperature change)

Water has a very high specific heat (4.184 J/g°C) — it absorbs and releases large amounts of heat with minimal temperature change
This property makes water excellent for:
- Regulating body temperature (the body is ~60% water)
- Hot/cold packs (water-based packs retain temperature longer)
- Industrial cooling systems

Nuclear Physics

Nuclear physics deals with the structure and behavior of atomic nuclei.

Nuclear Fission vs. Fusion

Process	Description	Energy	Example
Fission	Splitting a heavy nucleus into lighter nuclei	Releases energy	Nuclear power plants, atomic bombs
Fusion	Combining light nuclei into a heavier nucleus	Releases enormous energy	Stars (including the Sun), hydrogen bombs

Radioactive Decay (Review)

Unstable atomic nuclei emit radiation to become more stable. The three types of radiation have different properties:

Property	Alpha	Beta	Gamma
Composition	2p + 2n (He nucleus)	Electron	EM wave (photon)
Charge	+2	-1	0
Mass	Large	Small	None
Penetration	Low (paper stops)	Moderate (aluminum stops)	High (lead/concrete stops)
Ionizing ability	Highest	Moderate	Lowest
Medical use	Rare	Some therapy	Imaging, cancer therapy

Half-Life Calculations

The half-life equation: N = N0 x (1/2)^n

Where N = remaining amount, N0 = initial amount, n = number of half-lives elapsed

Half-Lives	Fraction Remaining	Percent Remaining
0	1	100%
1	1/2	50%
2	1/4	25%
3	1/8	12.5%
4	1/16	6.25%
5	1/32	3.125%

HESI A2 Admission Assessment

1Introduction: HESI A2 Exam Overview

2Chapter 1: Mathematics

3Chapter 2: Reading Comprehension

4Chapter 3: Vocabulary & General Knowledge

5Chapter 4: Grammar

6Chapter 5: Biology

7Chapter 6: Chemistry

8Chapter 7: Anatomy & Physiology

9Chapter 8: Physics

Key Takeaways