Ambient Energy Harvester Market, By Technology (Light Energy Harvesting, Vibration Energy Harvesting, Thermal or Pyroelectric Energy Harvesting, and Radio Frequency (RF) Energy Harvesting), By Component (Transducers, Accumulators, Power Management Integrated Circuits (PMICs), and Secondary Batteries), By Application (Construction, Home Automation, Consumer Electronics, Industrial, Transportation, and Defence), and By Region (North America, Europe, Asia Pacific, Latin America, and Middle East & Africa) - Trends, Analysis and Forecast till 2034

Ambient Energy Harvester Market was valued at US$ 628.8 million in 2024 and is projected to grow at a CAGR of 10.1% to reach US$ 1507.9 million by 2034.

Ambient energy is a type of native energy produced by a variety of processes using both natural and artificial sources. The method of extracting useful energy from the ambiently available resident energy is known as energy harvesting. Low quantities of ambient energy from surroundings can be captured and transformed into useful electrical power by an apparatus known as an ambient energy harvester. When using conventional power sources which could be limited or unrealistic, these harvesters are usually used in that case. Sophisticated technologies such as thermoelectric generators, piezoelectric materials, photovoltaic cells, or electromagnetic coils can be used to harvest ambient energy sources including heat, vibration, light, or radiofrequency signals. Low-power electronic gadgets and sensors are subsequently powered by the captured energy or stored for later use. Because they provide a reliable and frequently maintenance-free power source for a variety of technologies in places where traditional power sources might not be available, ambient energy harvesters are essential to functions like wireless sensor networks, Internet of Things (IoT) devices, and remote sensing networks.

The energy captured is enough to run wireless sensors, which is driving the market for ambient energy harvesters to expand. Since the need for micropower production to charge thin-film batteries is growing, the ambient energy harvester market is anticipated to have considerable growth throughout the forecast duration. Sustainable and generating clean energy is the purpose of the ambient energy harvester. This item is preferred over batteries in low-power electronic systems due to the increasing need for materials that are free of pollutants. Ambient energy harvesters also have the benefit of not requiring batteries to be purchased, installed, or changed.

Energy-harvesting systems use light, thermal, radiofrequency, kinetic, chemical/biological, and vibrational energy forms of energy the most out of all the ambient sources of energy. Furthermore, the requirement for these technologies has grown as a result of favorable government regulations, heightened environmental consciousness, and a decrease in greenhouse gas emissions. However the poor energy production of these harvesters and the expensive cost of these items in comparison to traditional sources are the main issues impeding the target market's growth throughout the forecast.

Disclaimer: This data is only a representation. Actual data may vary and will be available in the report.

Ambient Energy Harvester Market Key Drivers:

The rising adoption of the Internet of Things (IoT)

• An important factor driving the demand for ambient energy harvesting systems is the growing acceptance of the Internet of Things (IoT). Battery usage in microelectronics can be eliminated with ambient energy. This effectively solves a broad variety of challenging issues that battery-powered IoT poses. From an economic perspective, they make perfect sense—longer lifespans, reduced maintenance expenses, and no replacement prices.
• This suggests that low-power and ultra-low-power devices will increasingly turn to ambient energy harvesting in the future. These days, it's easy to see how the Internet of Things may stimulate creativity and cause upheaval. Without uncertainty, over the next few decades, the IoT market will expand at an exponential rate. The necessity of being battery-less will become apparent once the quantity of linked devices approaches several hundred million or perhaps billions.
• For instance, in July 2023, according to data generated by Statista, it is projected that by 2030, there will be over 29 billion Internet of Things (IoT) devices globally, nearly doubling from 15.1 billion in 2020. With around 8 billion consumer devices, China will have the greatest number of IoT devices worldwide in 2030. Consumer markets and all industry verticals employ IoT devices; by 2020, almost 60% of all IoT-connected devices will be in the consumer segment. This percentage is expected to remain at this level for the ensuing ten years.

Growing emphasis on sustainable development  

• The environmental impact of IoT devices is significantly decreased when they run on ambient energy rather than batteries. With the battery business embroiled in some grave social and ecological issues that are difficult to ignore, there are environmental benefits to adopting such harvesters. Devices connected to the Internet of Things can run entirely on ambient energy. Scale adjustments are crucial here. If hundreds of billions of IoT devices adopt self-powered, ambient energy solutions instead of using batteries, this will have a significant impact on the annual production of batteries and, more significantly, reduce the number of batteries that wind up in waste disposal facilities and the waterways.

Ambient Energy Harvester Market Restrains:

The high cost of these harvesters along with the poor output of energy they generate

• However, the primary factors preventing the target market's expansion throughout the prediction are the harvesters' low energy output and the high cost of these goods in contrast to more conventional sources. Comparing ambient energy harvesting technology to typical batteries, the development and production expenses can be higher. This may prevent further adoption, especially in areas where costs are an issue. The ambient energy harvesters of the current generation are usually low-power devices since they produce very little electricity. Therefore, to power more demanding applications, advancements in energy production are required.

Ambient Energy Harvester Market Opportunities:

• Stricter energy safety regulations imposed by governments worldwide are anticipated to fuel consumer interest in these technologies, as renewable energy sources become more widely accepted as a means of reducing carbon emissions. During the following years, these technologies are expected to present enormous potential for long-term energy preservation and powering portable electric appliances.
• It is anticipated that advancements in nanotechnology will lead to smaller and more portable energy-gathering systems. Ambient energy harvesters are also expected to grow in the future due to recent breakthroughs like the ability to capture energy from the sound of heartbeats through the chest and convert it into power for implanted devices like pacemakers. It helps to eliminate the need for regular battery replacement. Additionally, studies are being conducted to find ways to power various implantable devices by capturing body vibration, heat, and motion.

Ambient Energy Harvester Market is segmented based on technology, component, application, and region.

Technology Insights

·         Light Energy Harvesting: An energy-harvesting source found in ambient light can extend the battery life of Internet of Things devices, such as wearables and cell phones, and recharge them with minimal human intervention. Though it can complement batteries to power some low-energy-consuming vital tasks of the wearable device, particularly in low-power wearables, available light energy is insufficient for directly charging mobile phones and wearable devices.

·         Vibration Energy Harvesting: The harvester may use vibrations from the surroundings to power sensors because piezoelectric materials have the unique capacity to transform mechanical stress into electric energy. The new piezoelectric vibration energy harvester (PVEH) is a robust and lightweight device that is ideal for Internet of Things applications. Tests and simulations demonstrate that PVEH continues to function even after 100,000 bendings. The PVEH's potential to power sensors using ambient energy was demonstrated by preliminary results that indicated it could power over 15 LEDs after gathering energy with an output capacitor.

Thermal or Pyroelectric Energy Harvesting: This category uses a type of material known as pyroelectric which changes in polarization with temperature, converting thermal fluctuations into electric charge. Pyroelectrics have the ability to generate energy from thermal fluctuations and serve as a source of charge or voltage for electrochemical applications. They can also be used to recover low-grade waste thermal energy from industrial operations and the surrounding environment.

Radio Frequency (RF) Energy Harvesting: This category involves the use of electromagnetic energy that can be harvested by a radio frequency power harvesting device and transformed into a direct current (DC) voltage that can be used. The antenna and rectifier circuit, which enable the conversion of alternating current (AC) into direct current (DC) energy, are the essential components of an RF power harvesting system.

Component Insights

• Transducers: Transducers are parts that create a useful electrical signal out of environmental energy such as light, vibration, and thermal forms.
• Accumulator: An accumulator is an element, and is usually a capacitor that holds the captured energy in reserve until it is needed.
• Power Management Integrated Circuits (PMICs): Power management integrated circuits (PMICs) control the captured energy, making sure the connected item is powered at the correct current and voltage levels.
• Secondary Batteries: This category includes capacitors and rechargeable batteries which can occasionally be used in tandem to store excess gathered energy for later use.

Application Insights

• Construction: This category involves wireless sensor networks for checking the stability of structures or building states which can then be powered by ambient energy harvesters.
• Home Automation: In this category, it may be possible for low-power gadgets, such as smart lighting controls or thermostats, to run on ambient energy instead of batteries.
• Consumer Electronics: Consumer electronics is a dominating segment of this sector for the target market. Wireless appliances, wearables, cellphones, remote controls, body implants, and other consumer gadgets are utilizing energy-harvesting devices in increasing numbers. Energy harvesting technologies also enable the operation of consumer electronics in situations where traditional power sources are not accessible. Devices no longer need to be physically close to a power source to be used because of these capabilities, which also increase their flexibility. In the consumer electronics industry, these characteristics are what are pushing the development of energy harvesting systems.
• Industrial: In this application type ambient energy can be used to power sensors that monitor equipment in factories or remote atmospheric conditions.
• Transportation: In this application type it may be possible to use ambient energy for data collection and transmission using wireless sensors installed in public transportation systems or on cars.
• Defense: In military settings, ambient energy harvesting may be used to power sensors or low-power systems communication tools during distant missions.

Regional Insights:

Ambient Energy Harvester Market Regional Insights

• North America market is estimated to witness a significantly high revenue share over the forecast period because of the continuous and quickening pace of technological development in the area, this region has become the most important market for developments in home automation and construction automation, which use renewable energy sources and drive the market for energy harvesting systems. The creation of integrated energy production and storage systems for use in electronics, vehicles, and portable weapons is the focus of an advanced research project for the US military.
• Asia Pacific market is estimated to witness the fastest revenue share due to the need for different energy-efficient technologies and solutions which is being driven by the region's huge and expanding population. Several important application areas for energy harvesting systems, including consumer electronics, transportation, and industrial automation, have a sizable market in this region. Due to growing concerns about energy saving, the Asia Pacific market is anticipated to rise quickly.
• Europe market is expanding steadily wherein to advance energy security in the area, the European Commission has been making more investments in R&D. The utilization of energy harvesting systems to fuel different IoT devices and sensors can be advantageous for Europe, a market that is significant for consumer electronics and smart home technologies. Additionally, the Energy Harvesting System market in Germany accounted for the highest part of the European market, while the UK market grew at the fastest rate.
• Latin America market is an emerging region and is expanding quickly, which increases the demand for infrastructure in smart cities. Efficient and intelligent urban development can be facilitated by the use of ambient energy harvesters to power low-power sensors for environmental monitoring and traffic control.
• Middle East & Africa market is in its developmental stages and is witnessing a growth in the use of wearables and smartphones, which presents a market opportunity for the integration of ambient energy harvesting features aimed at prolonging battery life and decreasing the need for disposable batteries.

Ambient Energy Harvester Market Report Scope:

Attribute	Details
Market Size 2024	US$ 628.8 million
Projected Market Size 2034	US$ 1507.9 million
CAGR Growth Rate	10.1%
Base year for estimation	2023
Forecast period	2024 – 2034
Market representation	Revenue in USD Million & CAGR from 2024 to 2034
Market Segmentation	By Technology - Light Energy Harvesting, Vibration Energy Harvesting, Thermal or Pyroelectric Energy Harvesting, and Radio Frequency (RF) Energy Harvesting By Component - Transducers, Accumulator, Power Management Integrated Circuits (PMICs), and Secondary Batteries By Application - Construction, Home Automation, Consumer Electronics, Industrial, Transportation, and Defence
Regional scope	North America - U.S., Canada Europe - UK, Germany, Spain, France, Italy, Russia, Rest of Europe Asia Pacific - Japan, India, China, South Korea, Australia, Rest of Asia-Pacific Latin America - Brazil, Mexico, Argentina, Rest of Latin America Middle East & Africa - South Africa, Saudi Arabia, UAE, Rest of Middle East & Africa
Report coverage	Revenue forecast, company share, competitive landscape, growth factors, and trends

Segments Covered in the Report:

This report forecasts revenue growth at global, regional, and country levels and provides an analysis of the latest industry trends and opportunities in each of the sub-segments from 2024 to 2034. For the purpose of this study, has segmented the Ambient Energy Harvester Market report based on technology, component, application, and region:

Ambient Energy Harvester Market, By Technology:

• Light Energy Harvesting
• Vibration Energy Harvesting
• Thermal or Pyroelectric Energy Harvesting
• Radio Frequency (RF) Energy Harvesting

Ambient Energy Harvester Market, By Component:

• Transducers
• Accumulator
• Power Management Integrated Circuits (PMICs)
• Secondary Batteries

Ambient Energy Harvester Market, By Application:

• Construction
• Home Automation
• Consumer Electronics
• Industrial
• Transportation
• Defence

Ambient Energy Harvester Market, By Region:

• North America
  • U.S.
  • Canada
• Europe
  • Germany
  • UK
  • France
  • Russia
  • Italy
  • Rest of Europe
• Asia Pacific
  • China
  • India
  • Japan
  • South Korea
  • Rest of Asia Pacific
• Latin America
  • Brazil
  • Mexico
  • Rest of Latin America
• Middle East & Africa
  • GCC
  • Israel
  • South Africa
  • Rest of Middle East & Africa

The key players operating the Ambient Energy Harvester Market includes Murata Manufacturing Co. Ltd., MicroStrain Inc., Infinite Power Solution Inc., Texas Instruments Limited, STMicroelectronics Inc., Mide Technology Corporation, Cymbet Corporation, Linear Technologies, Enocean GmbH, and Cypress Semiconductor Corp.

Disclaimer: This data is only a representation. Actual data may vary and will be available in the report.

• In January 2024, Dracula Technologies presents the first-ever integration of electrical storage with low-light OPV energy harvesting in a single flexible film, designed for the electronics sector. The French energy harvesting business Dracula Technologies has unveiled a cutting-edge solar module with integrated energy storage. Designed to power IoT LoRa wireless sensors in low light, this module, named LAYERVault, was introduced at CES 2024 in Las Vegas.
• In April 2024, Dracula Technologies, a French indoor organic photovoltaic specialist, and STMicroelectronics, a Swiss semiconductor maker, showcased a battery-free illuminometer at the Embedded World trade show in Germany last week. On display was a prototype of an illuminometer that runs on an organic photovoltaic (OPV) module instead of a conventional coin battery. The two businesses released a statement stating that the STM32U0 low-power microcontroller unit pairs well with the OPV module's energy harvesting capabilities, which are optimized for low light levels of less than 500 lux.
• In June 2023, E-peas and InPlay collaborated to create a BLE sensor beacon platform that combines energy harvesting and sensing/communications for the IoT of the future. An InPlay BLE beacon and an e-peas power management integrated circuit (IC) that is compatible with a photovoltaic (PV) cell and energy storage element are the two main components of the solution. By giving designers a battery-free sensor, the approach hopes to make dense IoT deployments easier without sacrificing functionality. The compact design of the AEM10330 power management IC helps since, like many IoT sensors, size is an important consideration. Furthermore, BLE transmissions won't put an excessive strain on the PV cell due to the IN100 NanoBeacon's extremely low power consumption.
• In March 2022, Powercast Corporation claimed to have shipped 10 million wireless RF Powerharvester PCC110 chips about two years ago. This accomplishment, according to the business, is the result of increased consumer demand for wireless power-over-distance solutions that free devices from wires, batteries, and placement restrictions like the Qi wireless charging standard's requirement for direct contact with a charging surface. Untethered devices can be powered remotely (up to 80 feet away) with Powercast's technology, which boosts usefulness and efficiency, increases flexibility in device placement, and reduces or eradicates the need for batteries and connections.
• In September 2022, E-Peas SA and Energous Corporation declared the release of a new Wireless Energy Harvesting Evaluation Kit designed for energy harvesting purposes in industrial IoT medical, sales, and warehouse asset trackers, as well as smart homes and buildings. The set contains two assessment boards from e-peas, the EP112 Energy Harvesting Optimized Antenna Evaluation Board and the AEM30940 RF Evaluation Board. It also includes the company's 1W WattUp PowerBridge transmitter, which provides an over-the-air solution that enables device producers to deploy wireless power and energy harvesting across a variety of connected devices.

• Murata Manufacturing Co. Ltd.*
  • Company Overview
  • Product Portfolio
  • Key Highlights
  • Financial Performance
  • Business Strategies
• MicroStrain Inc.
• Infinite Power Solution Inc.
• Texas Instruments Limited
• STMicroelectronics Inc.
• Mide Technology Corporation
• Cymbet Corporation
• Linear Technologies
• Enocean GmbH
• Cypress Semiconductor Corp.

“*” marked represents similar segmentation in other categories in the respective section.

1. Research Objective and Assumption
   • Research Objectives
   • Assumptions
   • Abbreviations
2. Market Preview
   • Report Description
     • Market Definition and Scope
   • Executive Summary
     • Market Snippet, By Technology
     • Market Snippet, By Component
     • Market Snippet, By Application
     • Market Snippet, By Region
   • Opportunity Map Analysis
3. Market Dynamics, Regulations, and Trends Analysis
   • Market Dynamics
     • Drivers
     • Restraints
     • Market Opportunities
   • Market Trends
   • Product Launch
   • Impact Analysis
   • PEST Analysis
   • Porter’s Analysis
4. Market Segmentation, By Technology, 2024 – 2034, (US$ Mn)
   • Overview
     • Market Value and Forecast (US$ Mn), and Share Analysis (%), 2024 – 2034
     • Y-o-Y Growth Analysis (%), 2024 – 2034
     • Segment Trends
   • Light Energy Harvesting
     • Overview
     • Market Size and Forecast (US$ Mn), and Y-o-Y Growth (%), 2024 – 2034
   • Vibration Energy Harvesting
     • Overview
     • Market Size and Forecast (US$ Mn), and Y-o-Y Growth (%), 2024 – 2034
   • Thermal or Pyroelectric Energy Harvesting
     • Overview
     • Market Size and Forecast (US$ Mn), and Y-o-Y Growth (%), 2024 – 2034
   • Radio Frequency (RF) Energy Harvesting
     • Overview
     • Market Size and Forecast (US$ Mn), and Y-o-Y Growth (%), 2024 – 2034
5. Market Segmentation, By Component, 2024 – 2034, (US$ Mn)
   • Overview
     • Market Value and Forecast (US$ Mn), and Share Analysis (%), 2024 – 2034
     • Y-o-Y Growth Analysis (%), 2024 – 2034
     • Segment Trends
   • Transducers
     • Overview
     • Market Size and Forecast (US$ Mn), and Y-o-Y Growth (%), 2024 – 2034
   • Accumulator
     • Overview
     • Market Size and Forecast (US$ Mn), and Y-o-Y Growth (%), 2024 – 2034
   • Financial Institutes
     • Overview
     • Market Size and Forecast (US$ Mn), and Y-o-Y Growth (%), 2024 – 2034
   • Power Management Integrated Circuits (PMICs)
     • Overview
     • Market Size and Forecast (US$ Mn), and Y-o-Y Growth (%), 2024 – 2034
   • Secondary Batteries
     • Overview
     • Market Size and Forecast (US$ Mn), and Y-o-Y Growth (%), 2024 – 2034
6. Market Segmentation, By Application, 2024 – 2034, (US$ Mn)
   •    Overview
     • Market Value and Forecast (US$ Mn), and Share Analysis (%), 2024 – 2034
     • Y-o-Y Growth Analysis (%), 2024 – 2034
     • Segment Trends
   • Construction
     • Overview
     • Market Size and Forecast (US$ Mn), and Y-o-Y Growth (%), 2024 – 2034
   • Home Automation
     • Overview
     • Market Size and Forecast (US$ Mn), and Y-o-Y Growth (%), 2024 – 2034
   • Consumer Electronics
     • Overview
     • Market Size and Forecast (US$ Mn), and Y-o-Y Growth (%), 2024 – 2034
   • Industrial Transportation
     • Overview
     • Market Size and Forecast (US$ Mn), and Y-o-Y Growth (%), 2024 – 2034
   • Defence
     • Overview
     • Market Size and Forecast (US$ Mn), and Y-o-Y Growth (%), 2024 – 2034
7. Global Market, By Region, 2024 – 2034, (US$ Mn)
   • Overview
     • Market Value and Forecast (US$ Mn), and Share Analysis (%), 2024 – 2034
     • Y-o-Y Growth Analysis (%), 2024 – 2034
     • Regional Trends
   • North America
     • Market Size and Forecast (US$ Mn), By Technology, 2024 – 2034
     • Market Size and Forecast (US$ Mn), By Component, 2024 – 2034
     • Market Size and Forecast (US$ Mn), By Application, 2024 – 2034
     • Market Size and Forecast (US$ Mn), By Country, 2024 – 2034
       • U.S.
       • Canada
   • Europe
     • Market Size and Forecast (US$ Mn), By Technology, 2024 – 2034
     • Market Size and Forecast (US$ Mn), By Component, 2024 – 2034
     • Market Size and Forecast (US$ Mn), By Application, 2024 – 2034
     • Market Size and Forecast (US$ Mn), By Country, 2024 – 2034
       • Germany
       • UK
       • France
       • Russia
       • Italy
       • Rest of Europe
   • Asia Pacific
     • Market Size and Forecast (US$ Mn), By Technology, 2024 – 2034
     • Market Size and Forecast (US$ Mn), By Component, 2024 – 2034
     • Market Size and Forecast (US$ Mn), By Application, 2024 – 2034
     • Market Size and Forecast (US$ Mn), By Country, 2024 – 2034
       • China
       • India
       • Japan
       • South Korea
       • Rest of Asia Pacific
   • Latin America
     • Market Size and Forecast (US$ Mn), By Technology, 2024 – 2034
     • Market Size and Forecast (US$ Mn), By Component, 2024 – 2034
     • Market Size and Forecast (US$ Mn), By Application, 2024 – 2034
     • Market Size and Forecast (US$ Mn), By Country, 2024 – 2034
       • Brazil
       • Mexico
       • Rest of Latin America
   • Middle East & Africa
     • Market Size and Forecast (US$ Mn), By Technology, 2024 – 2034
     • Market Size and Forecast (US$ Mn), By Component, 2024 – 2034
     • Market Size and Forecast (US$ Mn), By Application, 2024 – 2034
     • Market Size and Forecast (US$ Mn), By Country, 2024 – 2034
       • GCC
       • Israel
       • South Africa
       • Rest of Middle East & Africa
8. Competitive Landscape
   • Heat Map Analysis
   • Company Profiles
     • Murata Manufacturing Co. Ltd
       • Company Overview
       • Product Portfolio
       • Key Highlights
       • Financial Overview
     • MicroStrain Inc.
       • Company Overview
       • Product Portfolio
       • Key Highlights
       • Financial Overview
     • Infinite Power Solution Inc.
       • Company Overview
       • Product Portfolio
       • Key Highlights
       • Financial Overview
     • Texas Instruments Limited
       • Company Overview
       • Product Portfolio
       • Key Highlights
       • Financial Overview
     • STMicroelectronics Inc.
       • Company Overview
       • Product Portfolio
       • Key Highlights
       • Financial Overview
     • Mide Technology Corporation
       • Company Overview
       • Product Portfolio
       • Key Highlights
       • Financial Overview
     • Cymbet Corporation
       • Company Overview
       • Product Portfolio
       • Key Highlights
       • Financial Overview
     • Linear Technologies
       • Company Overview
       • Product Portfolio
       • Key Highlights
       • Financial Overview
     • Enocean GmbH
       • Company Overview
       • Product Portfolio
       • Key Highlights
       • Financial Overview
     • Cypress Semiconductor Corp
       • Company Overview
       • Product Portfolio
       • Key Highlights
       • Financial Overview
   • Analyst Views
9. Section
   • Research Methodology
   • About Us
   • Contact