Ballistic Coefficient Chart by Caliber

The main difference between calibers in terms of aerodynamics is easily visible when comparing their G1 and G7 values. While heavy, long, and sleek bullets offer exceptional wind resistance, shorter bullets often struggle to maintain energy at extended distances. Compared to traditional flat-base designs, modern boat-tail projectiles boast vastly superior drag profiles. The better choice depends on your specific rifle twist rate and terminal performance needs. If your goal is maximizing downrange precision, evaluating a ballistic coefficient chart by caliber is the most effective way to select the right projectile. Our comprehensive comparison allows readers to compare BC values across different calibers for hunting, target shooting, and long-range shooting.

Ballistic Coefficient Chart by Caliber

CaliberManufacturerBulletBullet Weight (gr)Bullet TypeG1 Ballistic CoefficientG7 Ballistic CoefficientRecommended Twist RateTypical Application
.17 HMRHornadyV-MAX17Polymer Tip.125N/A1:9″Varmint
.22 LRCCIStandard LRN40Lead Round Nose.120N/A1:16″Target
.22 Cal (.224)SierraBlitzKing55Polymer Tip.271.1361:12″Varmint
.22 Cal (.224)BarnesTTSX62Solid Copper Tip.274N/A1:9″Hunting
.22 Cal (.224)HornadyELD Match73Boat Tail Polymer.398.2001:8″Match
.22 Cal (.224)BergerFULLBORE Target80.5Boat Tail Target.441.2261:8″Target
6mm (.243)HornadyELD-X103Polymer Tip BT.512.2581:8″Hunting
6mm (.243)BergerHybrid Target105Hybrid Target.536.2741:8″Target
6mm (.243)SierraMatchKing107HPBT.527.2601:8″Match
6.5mm (.264)BarnesLRX127Solid Copper BT.468.2361:8″Hunting
6.5mm (.264)LapuaScenar139HPBT.578.2901:8″Match
6.5mm (.264)BergerHybrid Target140Hybrid Target.607.3111:8″Target
6.5mm (.264)NoslerAccuBond LR142Bonded Polymer BT.625.3171:8″Hunting
6.5mm (.264)HornadyELD-X143Polymer Tip BT.625.3151:8″Hunting
6.5mm (.264)HornadyELD Match147Polymer Tip BT.697.3511:8″Match
.270 Cal (.277)HornadyELD-X145Polymer Tip BT.536.2701:10″Hunting
.270 Cal (.277)BergerEOL Elite Hunter170Hybrid Hunting.662.3391:8″Hunting
7mm (.284)NoslerAccuBond150Bonded Polymer Tip.493.2481:9″Hunting
7mm (.284)HornadyELD-X162Polymer Tip BT.630.3171:9″Hunting
7mm (.284)BergerHybrid Target180Hybrid Target.680.3491:9″Target
7mm (.284)SierraMatchKing183HPBT.707.3451:8″Match
.30 Cal (.308)LapuaScenar155HPBT.460.2301:12″Match
.30 Cal (.308)SierraMatchKing175HPBT.505.2501:11″Match
.30 Cal (.308)BarnesLRX175Solid Copper BT.508.2561:10″Hunting
.30 Cal (.308)HornadyELD-X178Polymer Tip BT.552.2781:10″Hunting
.30 Cal (.308)BergerJuggernaut Target185Boat Tail Target.555.2841:11″Target
.30 Cal (.308)NoslerAccuBond LR190Bonded Polymer BT.640.3221:10″Hunting
.30 Cal (.308)HornadyELD Match208Polymer Tip BT.690.3481:10″Match
.30 Cal (.308)BergerHybrid Target215Hybrid Target.691.3541:10″Target
.338 Cal (.338)LapuaScenar250HPBT.648.3221:10″Match
.338 Cal (.338)HornadyBTHP Match250HPBT.670.3351:10″Match
.338 Cal (.338)BergerOTM Tactical300Hybrid Target.818.4191:10″Tactical
.338 Cal (.338)LapuaScenar300HPBT.736.3681:10″Match
.375 Cal (.375)BarnesTTSX250Solid Copper Tip.424N/A1:12″Hunting
.375 Cal (.375)BergerLRHT377Hybrid Target.923.4731:8″Target
.375 Cal (.375)HornadyA-TIP Match390Aluminum Tip BT1.040.5231:8″Match
.416 Cal (.416)BarnesTSX400Solid Copper BT.436N/A1:14″Hunting
.416 Cal (.416)HornadyBTHP Match450HPBT.731.3681:14″Match

Ballistic Coefficient Chart by Caliber Image

Ballistic Coefficient Comparison by Caliber

When examining bullet aerodynamics, caliber heavily dictates the potential ballistic coefficient (BC). Smaller rimfire calibers like .17 HMR and .22 LR have very low BCs, generally falling between .100 and .130. Because they lack the mass and length to cut through the wind efficiently, they shed velocity rapidly.

See also  17 HMR Ballistics Chart Hornady

As you move up to centerfire calibers like 6mm, 6.5mm, and 7mm, the BC values climb drastically. These calibers are widely known for featuring high BC bullets that often exceed a .500 G1 ballistic coefficient. Heavy-for-caliber bullets in .30 caliber, .338 caliber, and .375 caliber push the boundaries even further, with specialized target bullets crossing the remarkable 1.000 G1 threshold.

G1 vs G7 Ballistic Coefficients

In the firearms industry, manufacturers typically publish two drag models to quantify how well a bullet flies: the G1 ballistic coefficient and the G7 ballistic coefficient.

  • G1 measures: A standard projectile with a flat base and a short, blunt nose. It represents older, traditional bullet designs.
  • G7 measures: A standard projectile featuring a long boat tail and a sharp, secant or tangent ogive. It accurately represents modern long-range bullets.

Long-range shooters strongly prefer the G7 model because modern boat tail bullets closely mirror the G7 standard shape. This makes the G7 drag prediction much more consistent across varying velocities.

FeatureG1G7
Best ForFlat-base bullets, older designsBoat tail bullets, modern long-range designs
Velocity SensitivityHigh (changes significantly with speed)Low (remains consistent across speeds)
Standard ShapeShort nose, flat baseLong pointed nose, 7.5° boat tail

Which Calibers Have the Highest Ballistic Coefficients?

The highest ballistic coefficients belong to large magnum calibers shooting exceptionally heavy bullets. The .338 Lapua Magnum, .375 CheyTac, and .416 Barrett utilize projectiles weighing between 300 and 450 grains. For example, the Hornady .375 caliber 390-grain A-TIP boasts a G1 BC of 1.040.

In standard short-action rifles, the 6.5mm and 7mm calibers routinely showcase the highest BCs relative to their recoil. Bullets like the 7mm 183-grain Sierra MatchKing (G1 .707) resist wind drift and retain velocity much better than lighter bullets, resulting in flatter trajectories.

See also  6.5 Creedmoor Ballistics Chart

Hunting Bullets vs Match Bullets

A ballistic coefficient chart reveals a clear divide between hunting bullets and match bullets. Match bullets are designed with one primary goal: maximizing aerodynamic efficiency. They feature extremely tight meplats (tips), elongated boat tails, and thin jackets.

Hunting bullets must compromise slightly on aerodynamics to ensure reliable terminal performance. To achieve controlled expansion and weight retention, they require thicker jackets and specific nose geometries (like exposed lead or large polymer tips). However, modern options like the Hornady ELD-X and Nosler AccuBond LR bridge this gap, offering near-match BCs with devastating hunting performance.

Why Ballistic Coefficient Changes

You may notice some manufacturers publish multiple BC values for the same bullet. This happens because bullet drag is not entirely static; a bullet’s ballistic coefficient changes during its flight based on several factors:

  • Velocity: As a bullet slows down, its drag profile shifts. G1 BCs are especially sensitive to these velocity bands.
  • Mach Number: Transonic flight (approaching the speed of sound) heavily disrupts drag.
  • Bullet Shape: Meplat deformation from aerodynamic heating can lower BC (which is why manufacturers now use heat-resistant polymer tips).
  • Atmospheric Conditions: While the bullet’s inherent shape doesn’t change, the effective drag changes based on air density, altitude, and temperature, which your ballistic calculator must account for.

Does Higher Ballistic Coefficient Mean Better Performance?

A higher ballistic coefficient generally translates to superior exterior ballistics. By cutting through the air with less resistance, a high-BC bullet yields distinct advantages:

  • Less Wind Drift: The bullet reaches the target faster, giving the wind less time to push it off course.
  • Higher Retained Velocity: The bullet stays supersonic much longer.
  • Greater Retained Energy: Essential for ethical hunting, high-BC bullets carry more foot-pounds of energy to the target.
  • Flatter Trajectory: Less bullet drop requires less scope dial adjustment.
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The limitation? High BC bullets are incredibly long and often require custom barrel twist rates (e.g., 1:8″ or faster) to stabilize properly.

Which Ballistic Coefficient Is Best for Long-Range Shooting?

For precision shooting past 800 yards, a G7 ballistic coefficient above .300 (roughly a .600 G1) is the benchmark. Calibers like 6.5 Creedmoor, 6.5 PRC, and 7mm PRC excel here. The heavier .338 caliber bullets with G7 values over .400 represent the gold standard for Extreme Long Range (ELR) shooting, as they cheat the wind and maintain supersonic speeds past one mile.

Which Ballistic Coefficient Is Best for Hunting?

For practical hunting situations (typically under 500 yards), an astronomical BC is helpful but not strictly necessary.

A G1 ballistic coefficient between .400 and .550 is perfect for medium-to-large game. This range allows hunters to utilize standard weight-for-caliber bullets (like a .308 caliber 165-grain or 178-grain) that stabilize in factory rifles while still providing excellent retained energy and minimal wind deflection in the field.

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