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United States Energy Inflation

Price

1 %
Change +/-
-2.7 %
Percentage Change
-114.89 %

The current value of the Energy Inflation in United States is 1 %. The Energy Inflation in United States decreased to 1 % on 6/1/2024, after it was 3.7 % on 5/1/2024. From 1/1/1958 to 10/1/2024, the average GDP in United States was 4.46 %. The all-time high was reached on 3/1/1980 with 47.13 %, while the lowest value was recorded on 7/1/2009 with -28.09 %.

Source: Bureau of Labor Statistics

Energy Inflation

  • 3 years

  • 5 years

  • 10 years

  • 25 Years

  • Max

Energy Inflation

Energy Inflation History

DateValue
6/1/20241 %
5/1/20243.7 %
4/1/20242.6 %
3/1/20242.121 %
2/1/20235.2 %
1/1/20238.7 %
12/1/20227.3 %
11/1/202213.1 %
10/1/202217.6 %
9/1/202219.8 %
1
2
3
4
5
...
58

Similar Macro Indicators to Energy Inflation

NameCurrentPreviousFrequency
🇺🇸
Consumer Price Index (CPI)
315.664 points315.3 pointsMonthly
🇺🇸
Consumer Price Index for Housing and Utilities
335.056 points334.087 pointsMonthly
🇺🇸
Core Consumer Prices
321.67 points320.77 pointsMonthly
🇺🇸
Core CPI
2.3 %2.4 %Monthly
🇺🇸
Core Inflation Rate
3.4 %3.6 %Monthly
🇺🇸
Core Inflation Rate MoM
0.3 %0.3 %Monthly
🇺🇸
Core PCE Price Index
122.045 points121.944 pointsMonthly
🇺🇸
Core PCE Price Index Annual Change
2.6 %2.8 %Monthly
🇺🇸
Core PCE Price Index MoM
0.3 %0.3 %Monthly
🇺🇸
Core PCE Prices QoQ
2.1 %2.8 %Quarter
🇺🇸
Core Producer Prices
142 points141.94 pointsMonthly
🇺🇸
Core Producer Prices MoM
0 %0.5 %Monthly
🇺🇸
Core Producer Prices YoY
3.1 %2.9 %Monthly
🇺🇸
CPI Transport
269.724 points269.604 pointsMonthly
🇺🇸
Export Prices
148.4 points147.2 pointsMonthly
🇺🇸
Export Prices MoM
-0.6 %0.6 %Monthly
🇺🇸
Export Prices YoY
0.6 %-1 %Monthly
🇺🇸
Food Inflation
2.1 %2.3 %Monthly
🇺🇸
GDP Deflator
125.51 points124.94 pointsQuarter
🇺🇸
Import Prices
141.2 points141.8 pointsMonthly
🇺🇸
Import Prices MoM
0.3 %-0.4 %Monthly
🇺🇸
Import Prices YoY
1.1 %1.1 %Monthly
🇺🇸
Inflation Expectations
2.9 %3 %Monthly
🇺🇸
Inflation Rate
3.3 %3.4 %Monthly
🇺🇸
Inflation Rate MoM
0.2 %-0.1 %Monthly
🇺🇸
Median-CPI
4.32 %4.48 %Monthly
🇺🇸
Michigan 5-Year Inflation Expectations
3 %3 %Monthly
🇺🇸
Michigan Inflation Expectations
3 %3.3 %Monthly
🇺🇸
PCE Price Index
123.096 points123.106 pointsMonthly
🇺🇸
PCE Price Index annual change
2.3 %2.1 %Monthly
🇺🇸
PCE Price Index Monthly Change
0 %0.3 %Monthly
🇺🇸
PCE Prices QoQ
1.5 %2.5 %Quarter
🇺🇸
PPI excluding Food, Energy, and Trade Services
131.634 points131.532 pointsMonthly
🇺🇸
PPI Excluding Food, Energy, and Trade Services MoM
0 %0.4 %Monthly
🇺🇸
PPI excluding Food, Energy, and Trade Services YoY
3.3 %3.2 %Monthly
🇺🇸
Producer Price Change
2.2 %2.3 %Monthly
🇺🇸
Producer Price Inflation MoM
-0.2 %0.5 %Monthly
🇺🇸
Producer prices
143.822 points144.063 pointsMonthly
🇺🇸
Rental inflation
4.9 %4.9 %Monthly
🇺🇸
Seasonally Adjusted Consumer Price Index
313.534 points313.049 pointsMonthly
🇺🇸
Service Inflation
4.9 %5 %Monthly
🇺🇸
Trimmed Mean of the Consumer Price Index
3.42 %3.52 %Monthly

Energy inflation in the United States constitutes over 9 percent of the consumer price index, according to Eulerpool.

What is Energy Inflation?

Energy Inflation: Understanding its Impacts and Consequences Energy inflation refers to the rising costs associated with energy production and consumption, impacting economies at both macro and micro levels. As a niche within the broader category of inflation, energy inflation plays a crucial role in shaping economic policies, influencing market dynamics, and affecting everyday consumer behavior. At Eulerpool, we provide comprehensive macroeconomic data to help individuals, businesses, and policymakers navigate the complexities of energy inflation. The primary driving factor behind energy inflation is the fluctuation in the prices of primary energy sources such as oil, natural gas, coal, and renewable energies. These price changes can result from a myriad of factors, including geopolitical tensions, changes in production levels, natural disasters, and shifts in supply and demand. The interconnectedness of global markets means that a disruption in one region can have far-reaching effects, contributing to price volatility and increased energy costs worldwide. Geopolitical tensions are among the most significant contributors to energy inflation. Conflicts in key oil-producing regions, for example, can lead to supply disruptions, causing a spike in global oil prices. The Organization of the Petroleum Exporting Countries (OPEC) wields considerable influence over oil prices through its production quotas, further contributing to price volatility. Similarly, natural gas markets can be impacted by political decisions, such as sanctions or trade embargoes, which can limit access to vital resources and drive up prices. Another critical factor in energy inflation is the level of energy production. When production decreases due to technical issues, aging infrastructure, or deliberate cuts to manage supply and demand, prices inevitably rise. For example, hurricanes and other natural disasters can damage oil rigs and refineries, leading to supply shortages and increased costs. On the flip side, significant technological advancements in energy extraction and production, such as hydraulic fracturing (fracking) and deepwater drilling, can increase supply and stabilize or reduce prices. Demand-side factors also heavily influence energy inflation. Increased energy consumption driven by economic growth, particularly in emerging markets, can strain supply chains and drive up costs. Industrialization and urbanization contribute to higher energy needs for manufacturing, transportation, and residential use. Additionally, seasonal variations, such as higher demand for heating during winter months or cooling in the summer, can cause temporary spikes in energy prices. The transition towards renewable energy sources further complicates the energy inflation landscape. While renewable energies like solar, wind, and hydroelectric power are essential for sustainable growth and environmental preservation, their integration into existing energy systems comes with significant costs. The initial capital expenditure for renewable energy infrastructure is high, and the technology is still developing, leading to inconsistencies in energy production and storage. As a result, during the transition phase, energy prices may rise, contributing to overall energy inflation. The economic consequences of energy inflation are broad and multifaceted. At the macroeconomic level, energy inflation can lead to higher production costs for goods and services, negatively impacting gross domestic product (GDP) and slowing economic growth. Inflationary pressures can erode purchasing power, as consumers face higher costs for gasoline, electricity, and heating. This erosion of purchasing power can lead to reduced consumer spending, further slowing economic growth and potentially leading to a recession. For businesses, particularly those heavily reliant on energy, rising costs can squeeze profit margins and reduce competitiveness. Increased energy expenses can force companies to raise prices for their goods and services, potentially leading to lower demand and sales. Companies may also delay or cancel expansion plans, resulting in fewer job opportunities and slower economic development. Energy-intensive industries, such as manufacturing, transportation, and agriculture, are particularly vulnerable to the adverse effects of energy inflation. Energy inflation also has significant implications for monetary policy. Central banks, such as the Federal Reserve in the United States or the European Central Bank, closely monitor inflation rates, including energy prices, to formulate appropriate monetary policies. Persistent energy inflation can prompt central banks to raise interest rates to control overall inflation, which can increase borrowing costs and slow economic growth. Conversely, central banks may implement measures to support the economy during periods of high energy inflation, such as quantitative easing or other stimulus programs, though these measures carry their own risks and consequences. Governments may also intervene to mitigate the impacts of energy inflation through various policies. Subsidies for energy costs, tax incentives for renewable energy adoption, and strategic petroleum reserves are some tools used to stabilize energy prices and protect consumers and businesses. However, these interventions must be carefully balanced to avoid distortions in the energy market or long-term fiscal imbalances. On a global scale, energy inflation can exacerbate economic inequalities and hinder sustainable development. Developing countries, which may already struggle with limited access to affordable energy, can be disproportionately affected by rising energy prices. This can impede progress in poverty reduction, healthcare, education, and other critical areas, perpetuating the cycle of underdevelopment. To address the challenges posed by energy inflation, it is imperative to adopt comprehensive energy strategies that promote sustainability, innovation, and resilience. Investment in renewable energy technologies, energy efficiency measures, and diversification of energy sources can help mitigate the impacts of energy inflation. Policymakers, businesses, and consumers must work collaboratively to create a sustainable energy future that balances economic growth, environmental preservation, and energy affordability. In conclusion, energy inflation is a complex and multifaceted issue with far-reaching economic implications. Understanding the underlying factors and consequences of energy inflation is crucial for informed decision-making by policymakers, businesses, and consumers. At Eulerpool, we are committed to providing accurate and comprehensive macroeconomic data to help our users navigate the challenges and opportunities presented by energy inflation, fostering a more informed and resilient economy.