市場調查報告書
商品編碼
1370754
先進陶瓷市場 - 2018-2028 年全球產業規模、佔有率、趨勢、機會和預測(按材料、類別、最終用戶、地區和競爭細分)Advanced Ceramics Market - Global Industry Size, Share, Trends, Opportunity, and Forecast 2018-2028 Segmented By Material, By Class, By End User, By Region and Competition |
預計 2024-2028 年全球先進陶瓷市場將強勁成長。在預測期內,預計先進陶瓷在各種應用中的使用將不斷增加,以及醫療和電信行業的擴張,將推動市場成長。
市場概況 | |
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預測期 | 2024-2028 |
2022 年市場規模 | 624億美元 |
2028 年市場規模 | 921.8億美元 |
2023-2028 年年複合成長率 | 6.68% |
成長最快的細分市場 | 醫療的 |
最大的市場 | 亞太 |
生物陶瓷是指用於修復或取代受損骨組織的一類陶瓷材料。它們具有許多優點,例如生物相容性、無毒性和尺寸穩定性牙髓應用。生物陶瓷主要用作鬆散形式的醫療植入物或用作塗層和填充物。使用生物陶瓷植入物進行的骨科手術包括硬組織置換,例如髖部、膝蓋、關節、頭骨、下顎和脊椎。隨著世界人口老化,生物陶瓷的使用變得流行。
先進陶瓷材料以牙科陶瓷為代表,包括矯正器(如牙套)、修復體(如牙冠、牙橋)、植體(如全瓷牙根植體)等。目前常見牙科陶瓷系統中使用的材料有二氧化矽、白榴石、二矽酸鋰、氧化鋁和氧化鋯基材料。它具有優異的韌性、強度、抗疲勞性,以及優異的耐磨性和生物相容性。此外,陶瓷材料在美觀上與牙齒的自然顏色相匹配,並且比傳統金屬產品的性能更好。此外,這些先進陶瓷比大多數金屬更輕,使其適合醫療應用,並且能夠長時間承受極端條件的組合。這推動了先進陶瓷材料市場的市場需求。
當用作工程材料時,先進陶瓷具有優於金屬基系統的一些性能。這些特性包括高耐磨性、優異的高溫強度、化學惰性、高加工速度和尺寸穩定性。其硬度、物理穩定性、極高的耐熱性、化學惰性、優異的電氣性能以及適合大規模生產使其成為最通用的材料之一。先進陶瓷用於航空航太領域,其中渦輪葉片用於承受極端溫度和壓力的條件。這些有利的特性使高性能陶瓷成為金屬和塑膠的最佳替代品。此外,這些先進陶瓷比大多數金屬更輕,使其適合醫療應用,並且能夠長時間承受極端條件的組合,從而推動了先進陶瓷材料的市場需求。
電池技術的最新進步對熱管理系統提出了新的要求。下一代混合動力汽車可以使用陶瓷材料作為電池、馬達、充電器熱管理以及高低壓電路載體中的各種基板。此外,精密加工的陶瓷軸和軸承將用於下一代混合動力汽車水冷卻泵,以冷卻關鍵的引擎電子設備和鋰離子電池。陶瓷產品不僅對乙二醇基冷卻劑具有出色的耐化學性和較長的使用壽命,而且由於重量輕,有助於提高燃油效率和安靜性。例如,碳化硼陶瓷用於汽車煞車片,碳化矽陶瓷因其能夠承受極端溫度而用於高性能煞車碟盤。
基材是一種薄的、平坦的燒製材料。陶瓷具有優異的熱性能和介電性能,使其成為適合基板的材料。廣泛使用的陶瓷基板材料有氧化鋁(Al2O3)、氮化鋁(AlN)和氧化鈹(BeO)三種。陶瓷基板具有低介電常數和介電損耗、高導熱率和高化學穩定性等優點。陶瓷電子感測器通常用於滿足高要求的機器和系統,因為陶瓷材料結合了高強度、熱穩定性和耐腐蝕性。它主要監測溫度、壓力、流量、距離、加速度、水分含量和氣體濃度等非電變量,並將這些變量轉換為電訊號供下游電子設備處理。石英玻璃是半導體產業中應用最廣泛的陶瓷。半導體產業的應用包括矽錠拉製坩堝、矽外延沉積反應器、晶圓載體、單晶圓加工設備、濕式蝕刻槽和複雜的機械加工零件。氧化鋁具有電絕緣性和熱絕緣性。廣泛應用於半導體晶圓加工設備。氮化矽陶瓷球軸承是半導體產業的傳統應用之一。
全球先進陶瓷市場根據材料、類別、最終用戶和地區進行細分。根據材料,市場分為氧化鋁、氧化鋯、矽、鈦酸鹽等。根據類別,市場分為整體陶瓷、陶瓷塗層和陶瓷基複合材料。根據最終用戶,市場分為電氣和電子、交通、醫療等。根據地區,市場進一步分為北美、亞太地區、歐洲、南美、中東和非洲。
全球先進陶瓷市場的主要市場參與者包括 Ceramtec GmbH、Kyocera Corporation、Rauschert Steinbach GmbH、Blasch Precision Ceramics Inc.、Saint-Gobain Ceramic Materials、Morgan Advanced Materials PLC、Coorstek Inc.、Ceradyne Inc.、Rauschertbach GmbH、布料 Stein拉施精密陶瓷公司
在本報告中,除了以下詳細介紹的產業趨勢外,全球先進陶瓷市場也分為以下幾類。
(註:公司名單可依客戶要求客製化。)
Global Advanced Ceramics Market is expected to grow at a robust pace in the forecast period 2024-2028. Over the forecast period, it is anticipated that growing use of advanced ceramics in a variety of applications, along with expansion in the medical and telecom industries, shall boost the market growth.
Ceramic materials are a diverse group of materials known for their unique properties and applications. They are usually made from inorganic compounds such as oxides, nitrides and carbides and are known for their high strength, hardness and resistance to heat and corrosion. Ceramic materials have been used for thousands of years, but their uses have expanded significantly in modern times, making them an integral part of many modern technologies. Ceramic materials are known for their unique properties that make them ideal for a wide variety of applications. They are very hard and strong, with high wear and corrosion resistance. It is an excellent insulator, both electrically and thermally, and can withstand high temperatures without decomposing. Additionally, ceramics are biocompatible, making them ideal for use in medical devices and implants. These properties make ceramics an integral part of many modern technologies, from aerospace to electronics to healthcare.
Market Overview | |
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Forecast Period | 2024-2028 |
Market Size 2022 | USD 62.4 Billion |
Market Size 2028 | USD 92.18 Billion |
CAGR 2023-2028 | 6.68% |
Fastest Growing Segment | Medical |
Largest Market | Asia-Pacific |
Bio ceramics refers to a class of ceramic materials used to repair or replace damaged bone tissue. They offer many advantages such as biocompatibility, non-toxicity, and dimensional stability endodontic applications. Bio ceramics are mainly used as medical implants, in loose form or as coatings and fillers. Orthopedic surgeries using bio ceramic implants surgically include hard tissue replacements such as hips, knees, joints, skulls, jaws, and spines. With the aging of the world population, the use of bio ceramics has become popular.
Advanced ceramic materials are represented by dental ceramics, including orthodontic appliances (such as braces), prosthetics (such as crowns and bridges), and implants (such as all-ceramic root implants). Materials currently used in common dental ceramic systems are silica, leucite, lithium disilicate, alumina, and zirconia-based materials. It has excellent toughness, strength, fatigue resistance, as well as excellent wear resistance and biocompatibility. In addition, ceramic materials aesthetically match the natural color of teeth and perform better than traditional metal products. Additionally, these advanced ceramics are lighter than most metals, making them suitable for medical applications and capable of withstanding a combination of extreme conditions for extended periods of time. This drives market demand for the Advanced Ceramics Material Market.
Advanced ceramics have some properties superior to metal-based systems when used as engineering materials. These properties include high wear resistance, excellent high temperature strength, chemical inertness, high processing speed, and dimensional stability. Its hardness, physical stability, extreme heat resistance, chemical inertness, excellent electrical properties, and suitability for mass production make it one of the most versatile materials. Advanced ceramics are used in aerospace, where turbine blades are used to withstand conditions of extreme temperatures and pressures. These favorable properties make high-performance ceramics the best alternatives to metals and plastics. Additionally, these advanced ceramics are lighter than most metals, making them suitable for medical applications and capable of withstanding a combination of extreme conditions for extended periods of time, thus driving market demand for the Advanced Ceramic Material.
Recent advancements in battery technology place new demands on thermal management systems. Next-generation hybrid vehicles can use ceramic materials for various substrates in batteries, electric motors, charger thermal management, and high and low voltage circuit carriers. Additionally, precision-machined ceramic shafts and bearings would be used in next-generation hybrid vehicle water cooling pumps to cool critical engine electronics and lithium-ion batteries. Ceramic products not only have excellent chemical resistance to glycol-based coolants and a long service life, but contribute to improved fuel efficiency and quietness due to their light weight. For example, boron carbide ceramics are used in automotive brake pads, and silicon carbide ceramics are used in high performance brake discs due to their ability to withstand extreme temperatures.
A substrate is a thin, flat fired material. Ceramics have excellent thermal and dielectric properties, making them suitable materials for substrates. There are three types of ceramic substrate materials which are widely used namely are aluminum oxide (Al2O3), aluminum nitride (AlN), and beryllium oxide (BeO). Ceramic substrates have the advantages of low dielectric constant and dielectric loss, high thermal conductivity and high chemical stability. Ceramic electronic sensors are often used in machines and systems that meet high requirements as ceramic materials combine high strength, thermal stability, and corrosion resistance. It mainly monitors non-electrical variables such as temperature, pressure, flow, distance, acceleration, moisture content and gas concentration, and converts these variables to electrical signals for processing in downstream electronics. Quartz glass is the most widely used ceramic in the semiconductor industry. Applications in the semiconductor industry include silicon ingot pulling crucibles, silicon epitaxial deposition reactors, wafer carriers, single wafer processing equipment, wet etch tanks, and complex machined parts. Aluminum oxide is electrically and thermally insulating. Widely used in semiconductor wafer processing equipment. Silicon nitride ceramic ball bearings are one of the traditional applications in the semiconductor industry.
The Global Advanced Ceramics Market is segmented based on material, class, end user, and region. Based on material, the market is bifurcated into alumina, zirconia, silicon, titanate, and others. Based on class, the market is bifurcated into monolithic ceramics, ceramic coatings, and ceramic matrix composites. Based on end user, the market is bifurcated into electrical & electronics, transportation, medical, and others. Based on region, the market is further bifurcated into North America, Asia-Pacific, Europe, South America, Middle East & Africa.
The main market players in the Global Advanced Ceramics Market are Ceramtec GmbH, Kyocera Corporation, Rauschert Steinbach GmbH, Blasch Precision Ceramics Inc., Saint-Gobain Ceramic Materials, Morgan Advanced Materials PLC, Coorstek Inc., Ceradyne Inc., Rauschert Steinbach GmbH, Blasch Precision Ceramics Inc.
In this report, Global Advanced Ceramics Market has been segmented into the following categories, in addition to the industry trends which have also been detailed below.
(Note: The companies list can be customized based on the client requirements.)